--- **Ops** - Manages aircraft CASE X recoveries for carrier operations (X=I, II, III). -- -- The AIRBOSS class manages recoveries of human pilots and AI aircraft on aircraft carriers. -- -- **Main Features:** -- -- * CASE I, II and III recoveries. -- * Supports human pilots as well as AI flight groups. -- * Automatic LSO grading including (optional) live grading while in the groove. -- * Different skill levels from on-the-fly tips for flight students to *ziplip* for pros. Can be set for each player individually. -- * Define recovery time windows with individual recovery cases in the same mission. -- * Option to let the carrier steam into the wind automatically. -- * Automatic TACAN and ICLS channel setting of carrier. -- * Separate radio channels for LSO and Marshal transmissions. -- * Voice over support for LSO and Marshal radio transmissions. -- * Advanced F10 radio menu including carrier info, weather, radio frequencies, TACAN/ICLS channels, player LSO grades, marking of zones etc. -- * Recovery tanker and refueling option via integration of @{Ops.RecoveryTanker} class. -- * Rescue helicopter option via @{Ops.RescueHelo} class. -- * Combine multiple human players to sections. -- * Many parameters customizable by convenient user API functions. -- * Multiple carrier support due to object oriented approach. -- * Unlimited number of players. -- * Persistence of player results (optional). LSO grading data is saved to csv file. -- * Trap sheet (optional). -- * Finite State Machine (FSM) implementation. -- -- **Supported Carriers:** -- -- * [USS John C. Stennis](https://en.wikipedia.org/wiki/USS_John_C._Stennis) (CVN-74) -- * [USS Theodore Roosevelt](https://en.wikipedia.org/wiki/USS_Theodore_Roosevelt_\(CVN-71\)) (CVN-71) [Super Carrier Module] -- * [USS Abraham Lincoln](https://en.wikipedia.org/wiki/USS_Abraham_Lincoln_\(CVN-72\)) (CVN-72) [Super Carrier Module] -- * [USS George Washington](https://en.wikipedia.org/wiki/USS_George_Washington_\(CVN-73\)) (CVN-73) [Super Carrier Module] -- * [USS Harry S. Truman](https://en.wikipedia.org/wiki/USS_Harry_S._Truman) (CVN-75) [Super Carrier Module] -- * [USS Forrestal](https://en.wikipedia.org/wiki/USS_Forrestal_\(CV-59\)) (CV-59) [Heatblur Carrier Module] -- * [HMS Hermes](https://en.wikipedia.org/wiki/HMS_Hermes_\(R12\)) (R12) -- * [HMS Invincible](https://en.wikipedia.org/wiki/HMS_Invincible_\(R05\)) (R05) -- * [USS Tarawa](https://en.wikipedia.org/wiki/USS_Tarawa_\(LHA-1\)) (LHA-1) -- * [USS America](https://en.wikipedia.org/wiki/USS_America_\(LHA-6\)) (LHA-6) -- * [Juan Carlos I](https://en.wikipedia.org/wiki/Spanish_amphibious_assault_ship_Juan_Carlos_I) (L61) -- * [HMAS Canberra](https://en.wikipedia.org/wiki/HMAS_Canberra_\(L02\)) (L02) -- -- **Supported Aircraft:** -- -- * [F/A-18C Hornet Lot 20](https://forums.eagle.ru/forumdisplay.php?f=557) (Player & AI) -- * [F-14A/B Tomcat](https://forums.eagle.ru/forumdisplay.php?f=395) (Player & AI) -- * [A-4E Skyhawk Community Mod](https://forums.eagle.ru/showthread.php?t=224989) (Player & AI) -- * [AV-8B N/A Harrier](https://forums.eagle.ru/forumdisplay.php?f=555) (Player & AI) -- * [T-45C Goshawk](https://forum.dcs.world/topic/203816-vnao-t-45-goshawk/) (VNAO mod) (Player & AI) -- * [FE/A-18E/F/G Superhornet](https://forum.dcs.world/topic/316971-cjs-super-hornet-community-mod-v20-official-thread/) (CJS mod) (Player & AI) -- * F/A-18C Hornet (AI) -- * F-14A Tomcat (AI) -- * E-2D Hawkeye (AI) -- * S-3B Viking & tanker version (AI) -- * [C-2A Greyhound](https://forums.eagle.ru/showthread.php?t=255641) (AI) -- -- At the moment, optimized parameters are available for the F/A-18C Hornet (Lot 20) and A-4E community mod as aircraft and the USS John C. Stennis as carrier. -- -- The AV-8B Harrier, HMS Hermes, HMS Invincible, the USS Tarawa, USS America, HMAS Canberra, and Juan Carlos I are WIP. The AV-8B harrier and the LHA's and LHD can only be used together, i.e. these ships are the only carriers the harrier is supposed to land on and -- no other fixed wing aircraft (human or AI controlled) are supposed to land on these ships. Currently only Case I is supported. Case II/III take slightly different steps from the CVN carrier. -- However, if no offset is used for the holding radial this provides a very close representation of the V/STOL Case III, allowing for an approach to over the deck and a vertical landing. -- -- Heatblur's mighty F-14B Tomcat has been added (March 13th 2019) as well. Same goes for the A version. -- -- The [DCS Supercarriers](https://www.digitalcombatsimulator.com/de/shop/modules/supercarrier/) are also supported. -- -- ## Discussion -- -- If you have questions or suggestions, please visit the [MOOSE Discord](https://discord.gg/AeYAkHP) #ops-airboss channel. -- There you also find an example mission and the necessary voice over sound files. Check out the **pinned messages**. -- -- ## Example Missions -- -- Example missions can be found [here](https://github.com/FlightControl-Master/MOOSE_MISSIONS/tree/master/Ops/Airboss). -- They contain the latest development Moose.lua file. -- -- ## IMPORTANT -- -- Some important restrictions (of DCS) you should be aware of: -- -- * Each player slot (client) should be in a separate group as DCS does only allow for sending messages to groups and not individual units. -- * Players are identified by their player name. Hence, ensure that no two player have the same name, e.g. "New Callsign", as this will lead to unexpected results. -- * The modex (tail number) of an aircraft should **not** be changed dynamically in the mission by a player. Unfortunately, there is no way to get this information via scripting API functions. -- * The A-4E-C mod needs *easy comms* activated to interact with the F10 radio menu. -- -- ## Youtube Videos -- -- ### AIRBOSS videos: -- -- * [[MOOSE] Airboss - Groove Testing (WIP)](https://www.youtube.com/watch?v=94KHQxxX3UI) -- * [[MOOSE] Airboss - Groove Test A-4E Community Mod](https://www.youtube.com/watch?v=ZbjD7FHiaHo) -- * [[MOOSE] Airboss - Groove Test: On-the-fly LSO Grading](https://www.youtube.com/watch?v=Xgs1hwDcPyM) -- * [[MOOSE] Airboss - Carrier Auto Steam Into Wind](https://www.youtube.com/watch?v=IsU8dYgsp90) -- * [[MOOSE] Airboss - CASE I Walkthrough in the F/A-18C by TG](https://www.youtube.com/watch?v=o1UrP4Q6PMM) -- * [[MOOSE] Airboss - New LSO/Marshal Voice Overs by Raynor](https://www.youtube.com/watch?v=_Suo68bRu8k) -- * [[MOOSE] Airboss - CASE I, "Until We Go Down" featuring the F-14B by Pikes](https://www.youtube.com/watch?v=ojgHDSw3Doc) -- * [[MOOSE] Airboss - Skipper Menu](https://youtu.be/awnecCxRoNQ) -- -- ### Jabbers Case I and III Recovery Tutorials: -- -- * [DCS World - F/A-18 - Case I Carrier Recovery Tutorial](https://www.youtube.com/watch?v=lm-M3VUy-_I) -- * [DCS World - Case I Recovery Tutorial - Followup](https://www.youtube.com/watch?v=cW5R32Q6xC8) -- * [DCS World - CASE III Recovery Tutorial](https://www.youtube.com/watch?v=Lnfug5CVAvo) -- -- ### Wags DCS Hornet Videos: -- -- * [DCS: F/A-18C Hornet - Episode 9: CASE I Carrier Landing](https://www.youtube.com/watch?v=TuigBLhtAH8) -- * [DCS: F/A-18C Hornet – Episode 16: CASE III Introduction](https://www.youtube.com/watch?v=DvlMHnLjbDQ) -- * [DCS: F/A-18C Hornet Case I Carrier Landing Training Lesson Recording](https://www.youtube.com/watch?v=D33uM9q4xgA) -- -- ### AV-8B Harrier and V/STOL Operations: -- -- * [Harrier Ship Landing Mission with Auto LSO!](https://www.youtube.com/watch?v=lqmVvpunk2c) -- * [Updated Airboss V/STOL Features USS Tarawa](https://youtu.be/K7I4pU6j718) -- * [Harrier Practice pattern USS America](https://youtu.be/99NigITYmcI) -- * [Harrier CASE III TACAN Approach USS Tarawa](https://www.youtube.com/watch?v=bTgJXZ9Mhdc&t=1s) -- * [Harrier CASE III TACAN Approach USS Tarawa](https://www.youtube.com/watch?v=wWHag5WpNZ0) -- -- === -- -- ### Author: **funkyfranky** LHA and LHD V/STOL additions by **Pene** -- ### Special Thanks To **Bankler** -- For his great [Recovery Trainer](https://forums.eagle.ru/showthread.php?t=221412) mission and script! -- His work was the initial inspiration for this class. Also note that this implementation uses some routines for determining the player position in Case I recoveries he developed. -- Bankler was kind enough to allow me to add this to the class - thanks again! -- -- @module Ops.Airboss -- @image Ops_Airboss.png --- AIRBOSS class. -- @type AIRBOSS -- @field #string ClassName Name of the class. -- @field #boolean Debug Debug mode. Messages to all about status. -- @field #string lid Class id string for output to DCS log file. -- @field #string theatre The DCS map used in the mission. -- @field Wrapper.Unit#UNIT carrier Aircraft carrier unit on which we want to practice. -- @field #string carriertype Type name of aircraft carrier. -- @field #AIRBOSS.CarrierParameters carrierparam Carrier specific parameters. -- @field #string alias Alias of the carrier. -- @field Wrapper.Airbase#AIRBASE airbase Carrier airbase object. -- @field #table waypoints Waypoint coordinates of carrier. -- @field #number currentwp Current waypoint, i.e. the one that has been passed last. -- @field Core.Beacon#BEACON beacon Carrier beacon for TACAN and ICLS. -- @field #boolean TACANon Automatic TACAN is activated. -- @field #number TACANchannel TACAN channel. -- @field #string TACANmode TACAN mode, i.e. "X" or "Y". -- @field #string TACANmorse TACAN morse code, e.g. "STN". -- @field #boolean ICLSon Automatic ICLS is activated. -- @field #number ICLSchannel ICLS channel. -- @field #string ICLSmorse ICLS morse code, e.g. "STN". -- @field #AIRBOSS.Radio PilotRadio Radio for Pilot calls. -- @field #AIRBOSS.Radio LSORadio Radio for LSO calls. -- @field #number LSOFreq LSO radio frequency in MHz. -- @field #string LSOModu LSO radio modulation "AM" or "FM". -- @field #AIRBOSS.Radio MarshalRadio Radio for carrier calls. -- @field #number MarshalFreq Marshal radio frequency in MHz. -- @field #string MarshalModu Marshal radio modulation "AM" or "FM". -- @field #AIRBOSS.Radio AirbossRadio Radio for carrier calls. -- @field #number AirbossFreq Airboss radio frequency in MHz. -- @field #string AirbossModu Airboss radio modulation "AM" or "FM". -- @field #number TowerFreq Tower radio frequency in MHz. -- @field Core.Scheduler#SCHEDULER radiotimer Radio queue scheduler. -- @field Core.Zone#ZONE_UNIT zoneCCA Carrier controlled area (CCA), i.e. a zone of 50 NM radius around the carrier. -- @field Core.Zone#ZONE_UNIT zoneCCZ Carrier controlled zone (CCZ), i.e. a zone of 5 NM radius around the carrier. -- @field #table players Table of players. -- @field #table menuadded Table of units where the F10 radio menu was added. -- @field #AIRBOSS.Checkpoint BreakEntry Break entry checkpoint. -- @field #AIRBOSS.Checkpoint BreakEarly Early break checkpoint. -- @field #AIRBOSS.Checkpoint BreakLate Late break checkpoint. -- @field #AIRBOSS.Checkpoint Abeam Abeam checkpoint. -- @field #AIRBOSS.Checkpoint Ninety At the ninety checkpoint. -- @field #AIRBOSS.Checkpoint Wake Checkpoint right behind the carrier. -- @field #AIRBOSS.Checkpoint Final Checkpoint when turning to final. -- @field #AIRBOSS.Checkpoint Groove In the groove checkpoint. -- @field #AIRBOSS.Checkpoint Platform Case II/III descent at 2000 ft/min at 5000 ft platform. -- @field #AIRBOSS.Checkpoint DirtyUp Case II/III dirty up and on speed position at 1200 ft and 10-12 NM from the carrier. -- @field #AIRBOSS.Checkpoint Bullseye Case III intercept glideslope and follow ICLS aka "bullseye". -- @field #number defaultcase Default recovery case. This is the case used if not specified otherwise. -- @field #number case Recovery case I, II or III currently in progress. -- @field #table recoverytimes List of time windows when aircraft are recovered including the recovery case and holding offset. -- @field #number defaultoffset Default holding pattern update if not specified otherwise. -- @field #number holdingoffset Offset [degrees] of Case II/III holding pattern. -- @field #table flights List of all flights in the CCA. -- @field #table Qmarshal Queue of marshalling aircraft groups. -- @field #table Qpattern Queue of aircraft groups in the landing pattern. -- @field #table Qwaiting Queue of aircraft groups waiting outside 10 NM zone for the next free Marshal stack. -- @field #table Qspinning Queue of aircraft currently spinning. -- @field #table RQMarshal Radio queue of marshal. -- @field #number TQMarshal Abs mission time, the last transmission ended. -- @field #table RQLSO Radio queue of LSO. -- @field #number TQLSO Abs mission time, the last transmission ended. -- @field #number Nmaxpattern Max number of aircraft in landing pattern. -- @field #number Nmaxmarshal Number of max Case I Marshal stacks available. Default 3, i.e. angels 2, 3 and 4. -- @field #number NmaxSection Number of max section members (excluding the lead itself), i.e. NmaxSection=1 is a section of two. -- @field #number NmaxStack Number of max flights per stack. Default 2. -- @field #boolean handleai If true (default), handle AI aircraft. -- @field Ops.RecoveryTanker#RECOVERYTANKER tanker Recovery tanker flying overhead of carrier. -- @field DCS#Vec3 Corientation Carrier orientation in space. -- @field DCS#Vec3 Corientlast Last known carrier orientation. -- @field Core.Point#COORDINATE Cposition Carrier position. -- @field #string defaultskill Default player skill @{#AIRBOSS.Difficulty}. -- @field #boolean adinfinitum If true, carrier patrols ad infinitum, i.e. when reaching its last waypoint it starts at waypoint one again. -- @field #number magvar Magnetic declination in degrees. -- @field #number Tcollapse Last time timer.gettime() the stack collapsed. -- @field #AIRBOSS.Recovery recoverywindow Current or next recovery window opened. -- @field #boolean usersoundradio Use user sound output instead of radio transmissions. -- @field #number Tqueue Last time in seconds of timer.getTime() the queue was updated. -- @field #number dTqueue Time interval in seconds for updating the queues etc. -- @field #number dTstatus Time interval for call FSM status updates. -- @field #boolean menumarkzones If false, disables the option to mark zones via smoke or flares. -- @field #boolean menusmokezones If false, disables the option to mark zones via smoke. -- @field #table playerscores Table holding all player scores and grades. -- @field #boolean autosave If true, all player grades are automatically saved to a file on disk. -- @field #string autosavepath Path where the player grades file is saved on auto save. -- @field #string autosavefilename File name of the auto player grades save file. Default is auto generated from carrier name/alias. -- @field #number marshalradius Radius of the Marshal stack zone. -- @field #boolean airbossnice Airboss is a nice guy. -- @field #boolean staticweather Mission uses static rather than dynamic weather. -- @field #number windowcount Running number counting the recovery windows. -- @field #number LSOdT Time interval in seconds before the LSO will make its next call. -- @field #string senderac Name of the aircraft acting as sender for broadcasting radio messages from the carrier. DCS shortcoming workaround. -- @field #string radiorelayLSO Name of the aircraft acting as sender for broadcasting LSO radio messages from the carrier. DCS shortcoming workaround. -- @field #string radiorelayMSH Name of the aircraft acting as sender for broadcasting Marhsal radio messages from the carrier. DCS shortcoming workaround. -- @field #boolean turnintowind If true, carrier is currently turning into the wind. -- @field #boolean detour If true, carrier is currently making a detour from its path along the ME waypoints. -- @field Core.Point#COORDINATE Creturnto Position to return to after turn into the wind leg is over. -- @field Core.Set#SET_GROUP squadsetAI AI groups in this set will be handled by the airboss. -- @field Core.Set#SET_GROUP excludesetAI AI groups in this set will be explicitly excluded from handling by the airboss and not forced into the Marshal pattern. -- @field #boolean menusingle If true, menu is optimized for a single carrier. -- @field #number collisiondist Distance up to which collision checks are done. -- @field #number holdtimestamp Timestamp when the carrier first came to an unexpected hold. -- @field #number Tmessage Default duration in seconds messages are displayed to players. -- @field #string soundfolder Folder within the mission (miz) file where airboss sound files are located. -- @field #string soundfolderLSO Folder withing the mission (miz) file where LSO sound files are stored. -- @field #string soundfolderMSH Folder withing the mission (miz) file where Marshal sound files are stored. -- @field #boolean despawnshutdown Despawn group after engine shutdown. -- @field #number Tbeacon Last time the beacons were refeshed. -- @field #number dTbeacon Time interval to refresh the beacons. Default 5 minutes. -- @field #AIRBOSS.LSOCalls LSOCall Radio voice overs of the LSO. -- @field #AIRBOSS.MarshalCalls MarshalCall Radio voice over of the Marshal/Airboss. -- @field #AIRBOSS.PilotCalls PilotCall Radio voice over from AI pilots. -- @field #number lowfuelAI Low fuel threshold for AI groups in percent. -- @field #boolean emergency If true (default), allow emergency landings, i.e. bypass any pattern and go for final approach. -- @field #boolean respawnAI If true, respawn AI flights as they enter the CCA to detach and airfields from the mission plan. Default false. -- @field #boolean turning If true, carrier is currently turning. -- @field #AIRBOSS.GLE gle Glidesope error thresholds. -- @field #AIRBOSS.LUE lue Lineup error thresholds. -- @field #boolean trapsheet If true, players can save their trap sheets. -- @field #string trappath Path where to save the trap sheets. -- @field #string trapprefix File prefix for trap sheet files. -- @field #number initialmaxalt Max altitude in meters to register in the inital zone. -- @field #boolean welcome If true, display welcome message to player. -- @field #boolean skipperMenu If true, add skipper menu. -- @field #number skipperSpeed Speed in knots for manual recovery start. -- @field #number skipperCase Manual recovery case. -- @field #boolean skipperUturn U-turn on/off via menu. -- @field #number skipperOffset Holding offset angle in degrees for Case II/III manual recoveries. -- @field #number skipperTime Recovery time in min for manual recovery. -- @field #boolean intowindold If true, use old into wind calculation. -- @extends Core.Fsm#FSM --- Be the boss! -- -- === -- -- ![Banner Image](..\Presentations\AIRBOSS\Airboss_Main.png) -- -- # The AIRBOSS Concept -- -- On a carrier, the AIRBOSS is guy who is really in charge - don't mess with him! -- -- # Recovery Cases -- -- The AIRBOSS class supports all three commonly used recovery cases, i.e. -- -- * **CASE I** during daytime and good weather (ceiling > 3000 ft, visibility > 5 NM), -- * **CASE II** during daytime but poor visibility conditions (ceiling > 1000 ft, visibility > 5NM), -- * **CASE III** when below Case II conditions and during nighttime (ceiling < 1000 ft, visibility < 5 NM). -- -- That being said, this script allows you to use any of the three cases to be used at any time. Or, in other words, *you* need to specify when which case is safe and appropriate. -- -- This is a lot of responsibility. *You* are the boss, but *you* need to make the right decisions or things will go terribly wrong! -- -- Recovery windows can be set up via the @{#AIRBOSS.AddRecoveryWindow} function as explained below. With this it is possible to seamlessly (within reason!) switch recovery cases in the same mission. -- -- ## CASE I -- -- As mentioned before, Case I recovery is the standard procedure during daytime and good visibility conditions. -- -- ### Holding Pattern -- -- ![Banner Image](..\Presentations\AIRBOSS\Airboss_Case1_Holding.png) -- -- The graphic depicts a the standard holding pattern during a Case I recovery. Incoming aircraft enter the holding pattern, which is a counter clockwise turn with a -- diameter of 5 NM, at their assigned altitude. The holding altitude of the first stack is 2000 ft. The interval between stacks is 1000 ft. -- -- Once a recovery window opens, the aircraft of the lowest stack commence their landing approach and the rest of the Marshal stack collapses, i.e. aircraft switch from -- their current stack to the next lower stack. -- -- The flight that transitions form the holding pattern to the landing approach, it should leave the Marshal stack at the 3 position and make a left hand turn to the *Initial* -- position, which is 3 NM astern of the boat. Note that you need to be below 1300 feet to be registered in the initial zone. -- The altitude can be set via the function @{#AIRBOSS.SetInitialMaxAlt}(*altitude*) function. -- As described below, the initial zone can be smoked or flared via the AIRBOSS F10 Help radio menu. -- -- ### Landing Pattern -- -- ![Banner Image](..\Presentations\AIRBOSS\Airboss_Case1_Landing.png) -- -- Once the aircraft reaches the Initial, the landing pattern begins. The important steps of the pattern are shown in the image above. -- The AV-8B Harrier pattern is very similar, the only differences are as there is no angled deck there is no wake check. from the ninety you wil fly a straight approach offset 26 ft to port (left) of the tram line. -- The aim is to arrive abeam the landing spot in a stable hover at 120 ft with forward speed matched to the boat. From there the LSO will call "cleared to land". You then level cross to the tram line at the designated landing spot at land vertcally. When you stabalise over the landing spot LSO will call Stabalise to indicate you are centered at the correct spot. -- -- ## CASE III -- -- ![Banner Image](..\Presentations\AIRBOSS\Airboss_Case3.png) -- -- A Case III recovery is conducted during nighttime or when the visibility is below CASE II minima during the day. The holding position and the landing pattern are rather different from a Case I recovery as can be seen in the image above. -- -- The first holding zone starts 21 NM astern the carrier at angels 6. The separation between the stacks is 1000 ft just like in Case I. However, the distance to the boat -- increases by 1 NM with each stack. The general form can be written as D=15+6+(N-1), where D is the distance to the boat in NM and N the number of the stack starting at N=1. -- -- Once the aircraft of the lowest stack is allowed to commence to the landing pattern, it starts a descent at 4000 ft/min until it reaches the "*Platform*" at 5000 ft and -- ~19 NM DME. From there a shallower descent at 2000 ft/min should be performed. At an altitude of 1200 ft the aircraft should level out and "*Dirty Up*" (gear, flaps & hook down). -- -- At 3 NM distance to the carrier, the aircraft should intercept the 3.5 degrees glideslope at the "*Bullseye*". From there the pilot should "follow the needles" of the ICLS. -- -- ## CASE II -- -- ![Banner Image](..\Presentations\AIRBOSS\Airboss_Case2.png) -- -- Case II is the common recovery procedure at daytime if visibility conditions are poor. It can be viewed as hybrid between Case I and III. -- The holding pattern is very similar to that of the Case III recovery with the difference the the radial is the inverse of the BRC instead of the FB. -- From the holding zone aircraft are follow the Case III path until they reach the Initial position 3 NM astern the boat. From there a standard Case I recovery procedure is -- in place. -- -- Note that the image depicts the case, where the holding zone has an angle offset of 30 degrees with respect to the BRC. This is optional. Commonly used offset angels -- are 0 (no offset), +-15 or +-30 degrees. The AIRBOSS class supports all these scenarios which are used during Case II and III recoveries. -- -- === -- -- # The F10 Radio Menu -- -- The F10 radio menu can be used to post requests to Marshal but also provides information about the player and carrier status. Additionally, helper functions -- can be called. -- -- ![Banner Image](..\Presentations\AIRBOSS\Airboss_MenuMain.png) -- -- By default, the script creates a submenu "Airboss" in the "F10 Other ..." menu and each @{#AIRBOSS} carrier gets its own submenu. -- If you intend to have only one carrier, you can simplify the menu structure using the @{#AIRBOSS.SetMenuSingleCarrier} function, which will create all carrier specific menu entries directly -- in the "Airboss" submenu. (Needless to say, that if you enable this and define multiple carriers, the menu structure will get completely screwed up.) -- -- ## Root Menu -- -- ![Banner Image](..\Presentations\AIRBOSS\Airboss_MenuRoot.png) -- -- The general structure -- -- * **F1 Help...** (Help submenu, see below.) -- * **F2 Kneeboard...** (Kneeboard submenu, see below. Carrier information, weather report, player status.) -- * **F3 Request Marshal** -- * **F4 Request Commence** -- * **F5 Request Refueling** -- * **F6 Spinning** -- * **F7 Emergency Landing** -- * **F8 [Reset My Status]** -- -- ### Request Marshal -- -- This radio command can be used to request a stack in the holding pattern from Marshal. Necessary conditions are that the flight is inside the Carrier Controlled Area (CCA) -- (see @{#AIRBOSS.SetCarrierControlledArea}). -- -- Marshal will assign an individual stack for each player group depending on the current or next open recovery case window. -- If multiple players have registered as a section, the section lead will be assigned a stack and is responsible to guide his section to the assigned holding position. -- -- ### Request Commence -- -- This command can be used to request commencing from the marshal stack to the landing pattern. Necessary condition is that the player is in the lowest marshal stack -- and that the number of aircraft in the landing pattern is smaller than four (or the number set by the mission designer). -- -- ![Banner Image](..\Presentations\AIRBOSS\Airboss_Case1Pattern.png) -- -- The image displays the standard Case I Marshal pattern recovery. Pilots are supposed to fly a clockwise circle and descent between the **3** and **1** positions. -- -- Commence should be performed at around the **3** position. If the pilot is in the lowest Marshal stack, and flies through this area, he is automatically cleared for the -- landing pattern. In other words, there is no need for the "Request Commence" radio command. The zone can be marked via smoke or flared using the player's F10 radio menu. -- -- A player can also request commencing if he is not registered in a marshal stack yet. If the pattern is free, Marshal will allow him to directly enter the landing pattern. -- However, this is only possible when the Airboss has a nice day - see @{#AIRBOSS.SetAirbossNiceGuy}. -- -- ### Request Refueling -- -- If a recovery tanker has been set up via the @{#AIRBOSS.SetRecoveryTanker}, the player can request refueling at any time. If currently in the marshal stack, the stack above will collapse. -- The player will be informed if the tanker is currently busy or going RTB to refuel itself at its home base. Once the re-fueling is complete, the player has to re-register to the marshal stack. -- -- ### Spinning -- -- If the pattern is full, players can go into the spinning pattern. This step is only allowed, if the player is in the pattern and his next step -- is initial, break entry, early/late break. At this point, the player should climb to 1200 ft a fly on the port side of the boat to go back to the initial again. -- -- If a player is in the spin pattern, flights in the Marshal queue should hold their altitude and are not allowed into the pattern until the spinning aircraft -- proceeds. -- -- Once the player reaches a point 100 meters behind the boat and at least 1 NM port, his step is set to "Initial" and he can resume the normal pattern approach. -- -- If necessary, the player can call "Spinning" again when in the above mentioned steps. -- -- ### Emergency Landing -- -- Request an emergency landing, i.e. bypass all pattern steps and go directly to the final approach. -- -- All section members are supposed to follow. Player (or section lead) is removed from all other queues and automatically added to the landing pattern queue. -- -- If this command is called while the player is currently on the carrier, he will be put in the bolter pattern. So the next expected step after take of -- is the abeam position. This allows for quick landing training exercises without having to go through the whole pattern. -- -- The mission designer can forbid this option my setting @{#AIRBOSS.SetEmergencyLandings}(false) in the script. -- -- ### [Reset My Status] -- -- This will reset the current player status. If player is currently in a marshal stack, he will be removed from the marshal queue and the stack above will collapse. -- The player needs to re-register later if desired. If player is currently in the landing pattern, he will be removed from the pattern queue. -- -- ## Help Menu -- -- ![Banner Image](..\Presentations\AIRBOSS\Airboss_MenuHelp.png) -- -- This menu provides commands to help the player. -- -- ### Mark Zones Submenu -- -- ![Banner Image](..\Presentations\AIRBOSS\Airboss_MenuMarkZones.png) -- -- These commands can be used to mark marshal or landing pattern zones. -- -- * **Smoke Pattern Zones** Smoke is used to mark the landing pattern zone of the player depending on his recovery case. -- For Case I this is the initial zone. For Case II/III and three these are the Platform, Arc turn, Dirty Up, Bullseye/Initial zones as well as the approach corridor. -- * **Flare Pattern Zones** Similar to smoke but uses flares to mark the pattern zones. -- * **Smoke Marshal Zone** This smokes the surrounding area of the currently assigned Marshal zone of the player. Player has to be registered in Marshal queue. -- * **Flare Marshal Zone** Similar to smoke but uses flares to mark the Marshal zone. -- -- Note that the smoke lasts ~5 minutes but the zones are moving along with the carrier. So after some time, the smoke gives shows you a picture of the past. -- -- ![Banner Image](..\Presentations\AIRBOSS\Airboss_Case3_FlarePattern.png) -- -- ### Skill Level Submenu -- -- ![Banner Image](..\Presentations\AIRBOSS\Airboss_MenuSkill.png) -- -- The player can choose between three skill or difficulty levels. -- -- * **Flight Student**: The player receives tips at certain stages of the pattern, e.g. if he is at the right altitude, speed, etc. -- * **Naval Aviator**: Less tips are show. Player should be familiar with the procedures and its aircraft parameters. -- * **TOPGUN Graduate**: Only very few information is provided to the player. This is for the pros. -- * **Hints On/Off**: Toggle displaying hints. -- -- ### My Status -- -- ![Banner Image](..\Presentations\AIRBOSS\Airboss_MenuMyStatus.png) -- -- This command provides information about the current player status. For example, his current step in the pattern. -- -- ### Attitude Monitor -- -- ![Banner Image](..\Presentations\AIRBOSS\Airboss_MenuAttitudeMonitor.png) -- -- This command displays the current aircraft attitude of the player aircraft in short intervals as message on the screen. -- It provides information about current pitch, roll, yaw, orientation of the plane with respect to the carrier's orientation (*Gamma*) etc. -- -- If you are in the groove, current lineup and glideslope errors are displayed and you get an on-the-fly LSO grade. -- -- ### LSO Radio Check -- -- LSO will transmit a short message on his radio frequency. See @{#AIRBOSS.SetLSORadio}. Note that in the A-4E you will not hear the message unless you are in the pattern. -- -- ### Marshal Radio Check -- -- Marshal will transmit a short message on his radio frequency. See @{#AIRBOSS.SetMarshalRadio}. -- -- ### Subtitles On/Off -- -- This command toggles the display of radio message subtitles if no radio relay unit is used. By default subtitles are on. -- Note that subtitles for radio messages which do not have a complete voice over are always displayed. -- -- ### Trapsheet On/Off -- -- Each player can activated or deactivate the recording of his flight data (AoA, glideslope, lineup, etc.) during his landing approaches. -- Note that this feature also has to be enabled by the mission designer. -- -- ## Kneeboard Menu -- -- ![Banner Image](..\Presentations\AIRBOSS\Airboss_MenuKneeboard.png) -- -- The Kneeboard menu provides information about the carrier, weather and player results. -- -- ### Results Submenu -- -- ![Banner Image](..\Presentations\AIRBOSS\Airboss_MenuResults.png) -- -- Here you find your LSO grading results as well as scores of other players. -- -- * **Greenie Board** lists average scores of all players obtained during landing approaches. -- * **My LSO Grades** lists all grades the player has received for his approaches in this mission. -- * **Last Debrief** shows the detailed debriefing of the player's last approach. -- -- ### Carrier Info -- -- ![Banner Image](..\Presentations\AIRBOSS\Airboss_MenuCarrierInfo.png) -- -- Information about the current carrier status is displayed. This includes current BRC, FB, LSO and Marshal frequencies, list of next recovery windows. -- -- ### Weather Report -- -- ![Banner Image](..\Presentations\AIRBOSS\Airboss_MenuWeatherReport.png) -- -- Displays information about the current weather at the carrier such as QFE, wind and temperature. -- -- For missions using static weather, more information such as cloud base, thickness, precipitation, visibility distance, fog and dust are displayed. -- If your mission uses dynamic weather, you can disable this output via the @{#AIRBOSS.SetStaticWeather}(**false**) function. -- -- ### Set Section -- -- With this command, you can define a section of human flights. The player who issues the command becomes the section lead and all other human players -- within a radius of 100 meters become members of the section. -- -- The responsibilities of the section leader are: -- -- * To request Marshal. The section members are not allowed to do this and have to follow the lead to his assigned stack. -- * To lead the right way to the pattern if the flight is allowed to commence. -- * The lead is also the only one who can request commence if the flight wants to bypass the Marshal stack. -- -- Each time the command is issued by the lead, the complete section is set up from scratch. Members which are not inside the 100 m radius any more are -- removed and/or new members which are now in range are added. -- -- If a section member issues this command, it is removed from the section of his lead. All flights which are not yet in another section will become members. -- -- The default maximum size of a section is two human players. This can be adjusted by the @{#AIRBOSS.SetMaxSectionSize}(*size*) function. The maximum allowed size -- is four. -- -- ### Marshal Queue -- -- ![Banner Image](..\Presentations\AIRBOSS\Airboss_MenuMarshalQueue.png) -- -- Lists all flights currently in the Marshal queue including their assigned stack, recovery case and Charlie time estimate. -- By default, the number of available Case I stacks is three, i.e. at angels 2, 3 and 4. Usually, the recovery thanker orbits at angels 6. -- The number of available stacks can be set by the @{#AIRBOSS.SetMaxMarshalStack} function. -- -- The default number of human players per stack is two. This can be set via the @{#AIRBOSS.SetMaxFlightsPerStack} function but has to be between one and four. -- -- Due to technical reasons, each AI group always gets its own stack. DCS does not allow to control the AI in a manner that more than one group per stack would make sense unfortunately. -- -- ### Pattern Queue -- -- ![Banner Image](..\Presentations\AIRBOSS\Airboss_MenuPatternQueue.png) -- -- Lists all flights currently in the landing pattern queue showing the time since they entered the pattern. -- By default, a maximum of four flights is allowed to enter the pattern. This can be set via the @{#AIRBOSS.SetMaxLandingPattern} function. -- -- ### Waiting Queue -- -- Lists all flights currently waiting for a free Case I Marshal stack. Note, stacks are limited only for Case I recovery ops but not for Case II or III. -- If the carrier is switches recovery ops form Case I to Case II or III, all waiting flights will be assigned a stack. -- -- # Landing Signal Officer (LSO) -- -- The LSO will first contact you on his radio channel when you are at the the abeam position (Case I) with the phrase "Paddles, contact.". -- Once you are in the groove the LSO will ask you to "Call the ball." and then acknowledge your ball call by "Roger Ball." -- -- During the groove the LSO will give you advice if you deviate from the correct landing path. These advices will be given when you are -- -- * too low or too high with respect to the glideslope, -- * too fast or too slow with respect to the optimal AoA, -- * too far left or too far right with respect to the lineup of the (angled) runway. -- -- ## LSO Grading -- -- LSO grading starts when the player enters the groove. The flight path and aircraft attitude is evaluated at certain steps (distances measured from rundown): -- -- * **X** At the Start (0.75 NM = 1390 m). -- * **IM** In the Middle (0.5 NM = 926 m), middle one third of the glideslope. -- * **IC** In Close (0.25 NM = 463 m), last one third of the glideslope. -- * **AR** At the Ramp (0.027 NM = 50 m). -- * **IW** In the Wires (at the landing position). -- -- Grading at each step includes the above calls, i.e. -- -- * **L**ined **U**p **L**eft or **R**ight: LUL, LUR -- * Too **H**igh or too **LO**w: H, LO -- * Too **F**ast or too **SLO**w: F, SLO -- * **O**ver**S**hoot: OS, only referenced during **X** -- * **Fly through** glideslope **down** or **up**: \\ , /, advisory only -- * **D**rift **L**eft or **R**ight:DL, DR, advisory only -- * **A**ngled **A**pproach: Angled approach (wings level and LUL): AA, advisory only -- -- Each grading, x, is subdivided by -- -- * (x): parenthesis, indicating "a little" for a minor deviation and -- * \_x\_: underline, indicating "a lot" for major deviations. -- -- The position at the landing event is analyzed and the corresponding trapped wire calculated. If no wire was caught, the LSO will give the bolter call. -- -- If a player is significantly off from the ideal parameters from IC to AR, the LSO will wave the player off. Thresholds for wave off are -- -- * Line up error > 3.0 degrees left or right and/or -- * Glideslope error < -1.2 degrees or > 1.8 degrees and/or -- * AOA depending on aircraft type and only applied if skill level is "TOPGUN graduate". -- -- ![Banner Image](..\Presentations\AIRBOSS\Airboss_LSOPlatcam.png) -- -- Line up and glideslope error thresholds were tested extensively using [VFA-113 Stingers LSO Mod](https://forums.eagle.ru/showthread.php?t=211557), -- if the aircraft is outside the red box. In the picture above, **blue** numbers denote the line up thresholds while the **blacks** refer to the glideslope. -- -- A wave off is called, when the aircraft is outside the red rectangle. The measurement stops already ~50 m before the rundown, since the error in the calculation -- increases the closer the aircraft gets to the origin/reference point. -- -- The optimal glideslope is assumed to be 3.5 degrees leading to a touch down point between the second and third wire. -- The height of the carrier deck and the exact wire locations are taken into account in the calculations. -- -- ## Pattern Waveoff -- -- The player's aircraft position is evaluated at certain critical locations in the landing pattern. If the player is far off from the ideal approach, the LSO will -- issue a pattern wave off. Currently, this is only implemented for Case I recoveries and the Case I part in the Case II recovery, i.e. -- -- * Break Entry -- * Early Break -- * Late Break -- * Abeam -- * Ninety -- * Wake -- * Groove -- -- At these points it is also checked if a player comes too close to another aircraft ahead of him in the pattern. -- -- ## Grading Points -- -- Currently grades are given by as follows -- -- * 5.0 Points **\_OK\_**: "Okay underline", given only for a perfect pass, i.e. when no deviations at all were observed by the LSO. The unicorn! -- * 4.0 Points **OK**: "Okay pass" when only minor () deviations happened. -- * 3.0 Points **(OK)**: "Fair pass", when only "normal" deviations were detected. -- * 2.0 Points **--**: "No grade", for larger deviations. -- -- Furthermore, we have the cases: -- -- * 2.5 Points **B**: "Bolter", when the player landed but did not catch a wire. -- * 2.0 Points **WOP**: "Pattern Wave-Off", when pilot was far away from where he should be in the pattern. -- * 2.0 Points **OWO**: "Own Wave-Off**, when pilot flies past the deck without touching it. -- * 1.0 Points **WO**: "Technique Wave-Off": Player got waved off in the final parts of the groove. -- * 1.0 Points **LIG**: "Long In the Groove", when pilot extents the downwind leg too far and screws up the timing for the following aircraft. -- * 0.0 Points **CUT**: "Cut pass", when player was waved off but landed anyway. In addition if a V/STOL lands without having been Cleared to Land. -- -- ## Foul Deck Waveoff -- -- A foul deck waveoff is called by the LSO if an aircraft is detected within the landing area when an approaching aircraft is at position IM-IC during Case I/II operations, -- or with an aircraft approaching the 3/4 NM during Case III operations. -- -- The approaching aircraft will be notified via LSO radio comms and is supposed to overfly the landing area to enter the Bolter pattern. **This pass is not graded**. -- -- === -- -- # Scripting -- -- Writing a basic script is easy and can be done in two lines. -- -- local airbossStennis=AIRBOSS:New("USS Stennis", "Stennis") -- airbossStennis:Start() -- -- The **first line** creates and AIRBOSS object via the @{#AIRBOSS.New}(*carriername*, *alias*) constructor. The first parameter *carriername* is name of the carrier unit as -- defined in the mission editor. The second parameter *alias* is optional. This name will, e.g., be used for the F10 radio menu entry. If not given, the alias is identical -- to the *carriername* of the first parameter. -- -- This simple script initializes a lot of parameters with default values: -- -- * TACAN channel is set to 74X, see @{#AIRBOSS.SetTACAN}, -- * ICSL channel is set to 1, see @{#AIRBOSS.SetICLS}, -- * LSO radio is set to 264 MHz FM, see @{#AIRBOSS.SetLSORadio}, -- * Marshal radio is set to 305 MHz FM, see @{#AIRBOSS.SetMarshalRadio}, -- * Default recovery case is set to 1, see @{#AIRBOSS.SetRecoveryCase}, -- * Carrier Controlled Area (CCA) is set to 50 NM, see @{#AIRBOSS.SetCarrierControlledArea}, -- * Default player skill "Flight Student" (easy), see @{#AIRBOSS.SetDefaultPlayerSkill}, -- * Once the carrier reaches its final waypoint, it will restart its route, see @{#AIRBOSS.SetPatrolAdInfinitum}. -- -- The **second line** starts the AIRBOSS class. If you set options this should happen after the @{#AIRBOSS.New} and before @{#AIRBOSS.Start} command. -- -- However, good mission planning involves also planning when aircraft are supposed to be launched or recovered. The definition of *case specific* recovery ops within the same mission is described in -- the next section. -- -- ## Recovery Windows -- -- Recovery of aircraft is only allowed during defined time slots. You can define these slots via the @{#AIRBOSS.AddRecoveryWindow}(*start*, *stop*, *case*, *holdingoffset*) function. -- The parameters are: -- -- * *start*: The start time as a string. For example "8:00" for a window opening at 8 am. Or "13:30+1" for half past one on the next day. Default (nil) is ASAP. -- * *stop*: Time when the window closes as a string. Same format as *start*. Default is 90 minutes after start time. -- * *case*: The recovery case during that window (1, 2 or 3). Default 1. -- * *holdingoffset*: Holding offset angle in degrees. Only for Case II or III recoveries. Default 0 deg. Common +-15 deg or +-30 deg. -- -- If recovery is closed, AI flights will be send to marshal stacks and orbit there until the next window opens. -- Players can request marshal via the F10 menu and will also be given a marshal stack. Currently, human players can request commence via the F10 radio regardless of -- whether a window is open or not and will be allowed to enter the pattern (if not already full). This will probably change in the future. -- -- At the moment there is no automatic recovery case set depending on weather or daytime. So it is the AIRBOSS (i.e. you as mission designer) who needs to make that decision. -- It is probably a good idea to synchronize the timing with the waypoints of the carrier. For example, setting up the waypoints such that the carrier -- already has turning into the wind, when a recovery window opens. -- -- The code for setting up multiple recovery windows could look like this -- local airbossStennis=AIRBOSS:New("USS Stennis", "Stennis") -- airbossStennis:AddRecoveryWindow("8:30", "9:30", 1) -- airbossStennis:AddRecoveryWindow("12:00", "13:15", 2, 15) -- airbossStennis:AddRecoveryWindow("23:30", "00:30+1", 3, -30) -- airbossStennis:Start() -- -- This will open a Case I recovery window from 8:30 to 9:30. Then a Case II recovery from 12:00 to 13:15, where the holing offset is +15 degrees wrt BRC. -- Finally, a Case III window opens 23:30 on the day the mission starts and closes 0:30 on the following day. The holding offset is -30 degrees wrt FB. -- -- Note that incoming flights will be assigned a holding pattern for the next opening window case if no window is open at the moment. So in the above example, -- all flights incoming after 13:15 will be assigned to a Case III marshal stack. Therefore, you should make sure that no flights are incoming long before the -- next window opens or adjust the recovery planning accordingly. -- -- The following example shows how you set up a recovery window for the next week: -- -- for i=0,7 do -- airbossStennis:AddRecoveryWindow(string.format("08:05:00+%d", i), string.format("08:50:00+%d", i)) -- end -- -- ### Turning into the Wind -- -- For each recovery window, you can define if the carrier should automatically turn into the wind. This is done by passing one or two additional arguments to the @{#AIRBOSS.AddRecoveryWindow} function: -- -- airbossStennis:AddRecoveryWindow("8:30", "9:30", 1, nil, true, 20) -- -- Setting the fifth parameter to *true* enables the automatic turning into the wind. The sixth parameter (here 20) specifies the speed in knots the carrier will go so that to total wind above the deck -- corresponds to this wind speed. For example, if the is blowing with 5 knots, the carrier will go 15 knots so that the total velocity adds up to the specified 20 knots for the pilot. -- -- The carrier will steam into the wind for as long as the recovery window is open. The distance up to which possible collisions are detected can be set by the @{#AIRBOSS.SetCollisionDistance} function. -- -- However, the AIRBOSS scans the type of the surface up to 5 NM in the direction of movement of the carrier. If he detects anything but deep water, he will stop the current course and head back to -- the point where he initially turned into the wind. -- -- The same holds true after the recovery window closes. The carrier will head back to the place where he left its assigned route and resume the path to the next waypoint defined in the mission editor. -- -- Note that the carrier will only head into the wind, if the wind direction is different by more than 5° from the current heading of the carrier (the angled runway, if any, fis taken into account here). -- -- === -- -- # Persistence of Player Results -- -- LSO grades of players can be saved to disk and later reloaded when a new mission is started. -- -- ## Prerequisites -- -- **Important** By default, DCS does not allow for writing data to files. Therefore, one first has to comment out the line "sanitizeModule('io')" and "sanitizeModule('lfs')", i.e. -- -- do -- sanitizeModule('os') -- --sanitizeModule('io') -- required for saving files -- --sanitizeModule('lfs') -- optional for setting the default path to your "Saved Games\DCS" folder -- require = nil -- loadlib = nil -- end -- -- in the file "MissionScripting.lua", which is located in the subdirectory "Scripts" of your DCS installation root directory. -- -- **WARNING** Desanitizing the "io" and "lfs" modules makes your machine or server vulnerable to attacks from the outside! Use this at your own risk. -- -- ## Save Results -- -- Saving asset data to file is achieved by the @{#AIRBOSS.Save}(*path*, *filename*) function. -- -- The parameter *path* specifies the path on the file system where the -- player grades are saved. If you do not specify a path, the file is saved your the DCS installation root directory if the **lfs** module is *not* desanizied or -- your "Saved Games\\DCS" folder in case you did desanitize the **lfs** module. -- -- The parameter *filename* is optional and defines the name of the saved file. By default this is automatically created from the AIRBOSS carrier name/alias, i.e. -- "Airboss-USS Stennis_LSOgrades.csv", if the alias is "USS Stennis". -- -- In the easiest case, you desanitize the **io** and **lfs** modules and just add the line -- -- airbossStennis:Save() -- -- If you want to specify an explicit path you can do this by -- -- airbossStennis:Save("D:\\My Airboss Data\\") -- -- This will save all player grades to in "D:\\My Airboss Data\\Airboss-USS Stennis_LSOgrades.csv". -- -- ### Automatic Saving -- -- The player grades can be saved automatically after each graded player pass via the @{#AIRBOSS.SetAutoSave}(*path*, *filename*) function. Again the parameters *path* and *filename* are optional. -- In the simplest case, you desanitize the **lfs** module and just add -- -- airbossStennis:SetAutoSave() -- -- Note that the the stats are saved after the *final* grade has been given, i.e. the player has landed on the carrier. After intermediate results such as bolters or waveoffs the stats are not automatically saved. -- -- In case you want to specify an explicit path, you can write -- -- airbossStennis:SetAutoSave("D:\\My Airboss Data\\") -- -- ## Results Output -- -- ![Banner Image](..\Presentations\AIRBOSS\Airboss_PersistenceResultsTable.png) -- -- The results file is stored as comma separated file. The columns are -- -- * *Name*: The player name. -- * *Pass*: A running number counting the passes of the player -- * *Points Final*: The final points (i.e. when the player has landed). This is the average over all previous bolters or waveoffs, if any. -- * *Points Pass*: The points of each pass including bolters and waveoffs. -- * *Grade*: LSO grade. -- * *Details*: Detailed analysis of deviations within the groove. -- * *Wire*: Trapped wire, if any. -- * *Tgroove*: Time in the groove in seconds (not applicable during Case III). -- * *Case*: The recovery case operations in progress during the pass. -- * *Wind*: Wind on deck in knots during approach. -- * *Modex*: Tail number of the player. -- * *Airframe*: Aircraft type used in the recovery. -- * *Carrier Type*: Type name of the carrier. -- * *Carrier Name*: Name/alias of the carrier. -- * *Theatre*: DCS map. -- * *Mission Time*: Mission time at the end of the approach. -- * *Mission Date*: Mission date in yyyy/mm/dd format. -- * *OS Date*: Real life date from os.date(). Needs **os** to be desanitized. -- -- ## Load Results -- -- Loading player grades from file is achieved by the @{#AIRBOSS.Load}(*path*, *filename*) function. The parameter *path* specifies the path on the file system where the -- data is loaded from. If you do not specify a path, the file is loaded from your the DCS installation root directory or, if **lfs** was desanitized from you "Saved Games\DCS" directory. -- The parameter *filename* is optional and defines the name of the file to load. By default this is automatically generated from the AIBOSS carrier name/alias, for example -- "Airboss-USS Stennis_LSOgrades.csv". -- -- Note that the AIRBOSS FSM **must not be started** in order to load the data. In other words, loading should happen **after** the -- @{#AIRBOSS.New} command is specified in the code but **before** the @{#AIRBOSS.Start} command is given. -- -- The easiest was to load player results is -- -- airbossStennis:New("USS Stennis") -- airbossStennis:Load() -- airbossStennis:SetAutoSave() -- -- Additional specification of parameters such as recovery windows etc, if required. -- airbossStennis:Start() -- -- This sequence loads all available player grades from the default file and automatically saved them when a player received a (final) grade. Again, if **lfs** was desanitized, the files are save to and loaded -- from the "Saved Games\DCS" directory. If **lfs** was *not* desanitized, the DCS root installation folder is the default path. -- -- # Trap Sheet -- -- Important aircraft attitude parameters during the Groove can be saved to file for later analysis. This also requires the **io** and optionally **lfs** modules to be desanitized. -- -- In the script you have to add the @{#AIRBOSS.SetTrapSheet}(*path*) function to activate this feature. -- -- ![Banner Image](..\Presentations\AIRBOSS\Airboss_TrapSheetTable.png) -- -- Data the is written to a file in csv format and contains the following information: -- -- * *Time*: time in seconds since start. -- * *Rho*: distance from rundown to player aircraft in NM. -- * *X*: distance parallel to the carrier in meters. -- * *Z*: distance perpendicular to the carrier in meters. -- * *Alt*: altitude of player aircraft in feet. -- * *AoA*: angle of attack in degrees. -- * *GSE*: glideslope error in degrees. -- * *LUE*: lineup error in degrees. -- * *Vtot*: total velocity of player aircraft in knots. -- * *Vy*: vertical (descent) velocity in ft/min. -- * *Gamma*: angle between vector of aircraft nose and vector point in the direction of the carrier runway in degrees. -- * *Pitch*: pitch angle of player aircraft in degrees. -- * *Roll*: roll angle of player aircraft in degrees. -- * *Yaw*: yaw angle of player aircraft in degrees. -- * *Step*: Step in the groove. -- * *Grade*: Current LSO grade. -- * *Points*: Current points for the pass. -- * *Details*: Detailed grading analysis. -- -- ## Lineup Error -- -- ![Banner Image](..\Presentations\AIRBOSS\Airboss_TrapSheetLUE.png) -- -- The graph displays the lineup error (LUE) as a function of the distance to the carrier. -- -- The pilot approaches the carrier from the port side, LUE>0°, at a distance of ~1 NM. -- At the beginning of the groove (X), he significantly overshoots to the starboard side (LUE<5°). -- In the middle (IM), he performs good corrections and smoothly reduces the lineup error. -- Finally, at a distance of ~0.3 NM (IC) he has corrected his lineup with the runway to a reasonable level, |LUE|<0.5°. -- -- ## Glideslope Error -- -- ![Banner Image](..\Presentations\AIRBOSS\Airboss_TrapSheetGLE.png) -- -- The graph displays the glideslope error (GSE) as a function of the distance to the carrier. -- -- In this case the pilot already enters the groove (X) below the optimal glideslope. He is not able to correct his height in the IM part and -- stays significantly too low. In close, he performs a harsh correction to gain altitude and ends up even slightly too high (GSE>0.5°). -- At his point further corrections are necessary. -- -- ## Angle of Attack -- -- ![Banner Image](..\Presentations\AIRBOSS\Airboss_TrapSheetAoA.png) -- -- The graph displays the angle of attack (AoA) as a function of the distance to the carrier. -- -- The pilot starts off being on speed after the ball call. Then he get way to fast troughout the most part of the groove. He manages to correct -- this somewhat short before touchdown. -- -- === -- -- # Sound Files -- -- An important aspect of the AIRBOSS is that it uses voice overs for greater immersion. The necessary sound files can be obtained from the -- MOOSE Discord in the [#ops-airboss](https://discordapp.com/channels/378590350614462464/527363141185830915) channel. Check out the **pinned messages**. -- -- However, including sound files into a new mission is tedious as these usually need to be included into the mission **miz** file via (unused) triggers. -- -- The default location inside the miz file is "l10n/DEFAULT/". But simply opening the *miz* file with e.g. [7-zip](https://www.7-zip.org/) and copying the files into that folder does not work. -- The next time the mission is saved, files not included via trigger are automatically removed by DCS. -- -- However, if you create a new folder inside the miz file, which contains the sounds, it will not be deleted and can be used. The location of the sound files can be specified -- via the @{#AIRBOSS.SetSoundfilesFolder}(*folderpath*) function. The parameter *folderpath* defines the location of the sound files folder within the mission *miz* file. -- -- ![Banner Image](..\Presentations\AIRBOSS\Airboss_SoundfilesFolder.png) -- -- For example as -- -- airbossStennis:SetSoundfilesFolder("Airboss Soundfiles/") -- -- ## Carrier Specific Voice Overs -- -- It is possible to use different sound files for different carriers. If you have set up two (or more) AIRBOSS objects at different carriers - say Stennis and Tarawa - each -- carrier would use the files in the specified directory, e.g. -- -- airbossStennis:SetSoundfilesFolder("Airboss Soundfiles Stennis/") -- airbossTarawa:SetSoundfilesFolder("Airboss Soundfiles Tarawa/") -- -- ## Sound Packs -- -- The AIRBOSS currently has two different "sound packs" for LSO and three different "sound Packs" for Marshal radios. These contain voice overs by different actors. -- These can be set by @{#AIRBOSS.SetVoiceOversLSOByRaynor}() and @{#AIRBOSS.SetVoiceOversMarshalByRaynor}(). These are the default settings. -- The other sound files can be set by @{#AIRBOSS.SetVoiceOversLSOByFF}(), @{#AIRBOSS.SetVoiceOversMarshalByGabriella}() and @{#AIRBOSS.SetVoiceOversMarshalByFF}(). -- Also combinations can be used, e.g. -- -- airbossStennis:SetVoiceOversLSOByFF() -- airbossStennis:SetVoiceOversMarshalByRaynor() -- -- In this example LSO voice overs by FF and Marshal voice overs by Raynor are used. -- -- **Note** that this only initializes the correct parameters parameters of sound files, i.e. the duration. The correct files have to be in the directory set by the -- @{#AIRBOSS.SetSoundfilesFolder}(*folder*) function. -- -- ## How To Use Your Own Voice Overs -- -- If you have a set of AIRBOSS sound files recorded or got it from elsewhere it is possible to use those instead of the default ones. -- I recommend to use exactly the same file names as the original sound files have. -- -- However, the **timing is critical**! As sometimes sounds are played directly after one another, e.g. by saying the modex but also on other occations, the airboss -- script has a radio queue implemented (actually two - one for the LSO and one for the Marshal/Airboss radio). -- By this it is automatically taken care that played messages are not overlapping and played over each other. The disadvantage is, that the script needs to know -- the exact duration of *each* voice over. For the default sounds this is hard coded in the source code. For your own files, you need to give that bit of information -- to the script via the @{#AIRBOSS.SetVoiceOver}(**radiocall**, **duration**, **subtitle**, **subduration**, **filename**, **suffix**) function. Only the first two -- parameters **radiocall** and **duration** are usually important to adjust here. -- -- For example, if you want to change the LSO "Call the Ball" and "Roger Ball" calls: -- -- airbossStennis:SetVoiceOver(airbossStennis.LSOCall.CALLTHEBALL, 0.6) -- airbossStennis:SetVoiceOver(airbossStennis.LSOCall.ROGERBALL, 0.7) -- -- Again, changing the file name, subtitle, subtitle duration is not required if you name the file exactly like the original one, which is this case would be "LSO-RogerBall.ogg". -- -- ## The Radio Dilemma -- -- DCS offers two (actually three) ways to send radio messages. Each one has its advantages and disadvantages and it is important to understand the differences. -- -- ### Transmission via Command -- -- *In principle*, the best way to transmit messages is via the [TransmitMessage](https://wiki.hoggitworld.com/view/DCS_command_transmitMessage) command. -- This method has the advantage that subtitles can be used and these subtitles are only displayed to the players who dialed in the same radio frequency as -- used for the transmission. -- However, this method unfortunately only works if the sending unit is an **aircraft**. Therefore, it is not usable by the AIRBOSS per se as the transmission comes from -- a naval unit (i.e. the carrier). -- -- As a workaround, you can put an aircraft, e.g. a Helicopter on the deck of the carrier or another ship of the strike group. The aircraft should be set to -- uncontrolled and maybe even to immortal. With the @{#AIRBOSS.SetRadioUnitName}(*unitname*) function you can use this unit as "radio repeater" for both Marshal and LSO -- radio channels. However, this might lead to interruptions in the transmission if both channels transmit simultaniously. Therefore, it is better to assign a unit for -- each radio via the @{#AIRBOSS.SetRadioRelayLSO}(unitname) and @{#AIRBOSS.SetRadioRelayMarshal}(unitname) functions. -- -- Of course you can also use any other aircraft in the vicinity of the carrier, e.g. a rescue helo or a recovery tanker. It is just important that this -- unit is and stays close the the boat as the distance from the sender to the receiver is modeled in DCS. So messages from too far away might not reach the players. -- -- **Note** that not all radio messages the airboss sends have voice overs. Therefore, if you use a radio relay unit, users should *not* disable the -- subtitles in the DCS game menu. -- -- ### Transmission via Trigger -- -- Another way to broadcast messages is via the [radio transmission trigger](https://wiki.hoggitworld.com/view/DCS_func_radioTransmission). This method can be used for all -- units (land, air, naval). However, messages cannot be subtitled. Therefore, subtitles are displayed to the players via normal textout messages. -- The disadvantage is that is is impossible to know which players have the right radio frequencies dialed in. Therefore, subtitles of the Marshal radio calls are displayed to all players -- inside the CCA. Subtitles on the LSO radio frequency are displayed to all players in the pattern. -- -- ### Sound to User -- -- The third way to play sounds to the user via the [outsound trigger](https://wiki.hoggitworld.com/view/DCS_func_outSound). -- These sounds are not coming from a radio station and therefore can be heard by players independent of their actual radio frequency setting. -- The AIRBOSS class uses this method to play sounds to players which are of a more "private" nature - for example when a player has left his assigned altitude -- in the Marshal stack. Often this is the modex of the player in combination with a textout messaged displayed on screen. -- -- If you want to use this method for all radio messages you can enable it via the @{#AIRBOSS.SetUserSoundRadio}() function. This is the analogue of activating easy comms in DCS. -- -- Note that this method is used for all players who are in the A-4E community mod as this mod does not have the ability to use radios due to current DCS restrictions. -- Therefore, A-4E drivers will hear all radio transmissions from the Marshal/Airboss and all LSO messages as soon as their commence the pattern. -- -- === -- -- # AI Handling -- -- The @{#AIRBOSS} class allows to handle incoming AI units and integrate them into the marshal and landing pattern. -- -- By default, incoming carrier capable aircraft which are detecting inside the Carrier Controlled Area (CCA) and approach the carrier by more than 5 NM are automatically guided to the holding zone. -- Each AI group gets its own marshal stack in the holding pattern. Once a recovery window opens, the AI group of the lowest stack is transitioning to the landing pattern -- and the Marshal stack collapses. -- -- If no AI handling is desired, this can be turned off via the @{#AIRBOSS.SetHandleAIOFF} function. -- -- In case only specifc AI groups shall be excluded, it can be done by adding the groups to a set, e.g. -- -- -- AI groups explicitly excluded from handling by the Airboss -- local CarrierExcludeSet=SET_GROUP:New():FilterPrefixes("E-2D Wizard Group"):FilterStart() -- AirbossStennis:SetExcludeAI(CarrierExcludeSet) -- -- Similarly, to the @{#AIRBOSS.SetExcludeAI} function, AI groups can be explicitly *included* via the @{#AIRBOSS.SetSquadronAI} function. If this is used, only the *included* groups are handled -- by the AIRBOSS. -- -- ## Keep the Deck Clean -- -- Once the AI groups have landed on the carrier, they can be despawned automatically after they shut down their engines. This is achieved by the @{#AIRBOSS.SetDespawnOnEngineShutdown}() function. -- -- ## Refueling -- -- AI groups in the marshal pattern can be send to refuel at the recovery tanker or if none is defined to the nearest divert airfield. This can be enabled by the @{#AIRBOSS.SetRefuelAI}(*lowfuelthreshold*). -- The parameter *lowfuelthreshold* is the threshold of fuel in percent. If the fuel drops below this value, the group will go for refueling. If refueling is performed at the recovery tanker, -- the group will return to the marshal stack when done. The aircraft will not return from the divert airfield however. -- -- Note that this feature is not enabled by default as there might be bugs in DCS that prevent a smooth refueling of the AI. Enable at your own risk. -- -- ## Respawning - DCS Landing Bug -- -- AI groups that enter the CCA are usually guided to Marshal stack. However, due to DCS limitations they might not obey the landing task if they have another airfield as departure and/or destination in -- their mission task. Therefore, AI groups can be respawned when detected in the CCA. This should clear all other airfields and allow the aircraft to land on the carrier. -- This is achieved by the @{#AIRBOSS.SetRespawnAI}() function. -- -- ## Known Issues -- -- Dealing with the DCS AI is a big challenge and there is only so much one can do. Please bear this in mind! -- -- ### Pattern Updates -- -- The holding position of the AI is updated regularly when the carrier has changed its position by more then 2.5 NM or changed its course significantly. -- The patterns are realized by orbit or racetrack patterns of the DCS scripting API. -- However, when the position is updated or the marshal stack collapses, it comes to disruptions of the regular orbit because a new waypoint with a new -- orbit task needs to be created. -- -- ### Recovery Cases -- -- The AI performs a very realistic Case I recovery. Therefore, we already have a good Case I and II recovery simulation since the final part of Case II is a -- Case I recovery. However, I don't think the AI can do a proper Case III recovery. If you give the AI the landing command, it is out of our hands and will -- always go for a Case I in the final pattern part. Maybe this will improve in future DCS version but right now, there is not much we can do about it. -- -- === -- -- # Finite State Machine (FSM) -- -- The AIRBOSS class has a Finite State Machine (FSM) implementation for the carrier. This allows mission designers to hook into certain events and helps -- simulate complex behaviour easier. -- -- FSM events are: -- -- * @{#AIRBOSS.Start}: Starts the AIRBOSS FSM. -- * @{#AIRBOSS.Stop}: Stops the AIRBOSS FSM. -- * @{#AIRBOSS.Idle}: Carrier is set to idle and not recovering. -- * @{#AIRBOSS.RecoveryStart}: Starts the recovery ops. -- * @{#AIRBOSS.RecoveryStop}: Stops the recovery ops. -- * @{#AIRBOSS.RecoveryPause}: Pauses the recovery ops. -- * @{#AIRBOSS.RecoveryUnpause}: Unpauses the recovery ops. -- * @{#AIRBOSS.RecoveryCase}: Sets/switches the recovery case. -- * @{#AIRBOSS.PassingWaypoint}: Carrier passes a waypoint defined in the mission editor. -- -- These events can be used in the user script. When the event is triggered, it is automatically a function OnAfter*Eventname* called. For example -- -- --- Carrier just passed waypoint *n*. -- function AirbossStennis:OnAfterPassingWaypoint(From, Event, To, n) -- -- Launch green flare. -- self.carrier:FlareGreen() -- end -- -- In this example, we only launch a green flare every time the carrier passes a waypoint defined in the mission editor. But, of course, you can also use it to add new -- recovery windows each time a carrier passes a waypoint. Therefore, you can create an "infinite" number of windows easily. -- -- === -- -- # Examples -- -- In this section a few simple examples are given to illustrate the scripting part. -- -- ## Simple Case -- -- -- Create AIRBOSS object. -- local AirbossStennis=AIRBOSS:New("USS Stennis") -- -- -- Add recovery windows: -- -- Case I from 9 to 10 am. Carrier will turn into the wind 5 min before window opens and go at a speed so that wind over the deck is 25 knots. -- local window1=AirbossStennis:AddRecoveryWindow("9:00", "10:00", 1, nil, true, 25) -- -- Case II with +15 degrees holding offset from 15:00 for 60 min. -- local window2=AirbossStennis:AddRecoveryWindow("15:00", "16:00", 2, 15) -- -- Case III with +30 degrees holding offset from 21:00 to 23:30. -- local window3=AirbossStennis:AddRecoveryWindow("21:00", "23:30", 3, 30) -- -- -- Load all saved player grades from your "Saved Games\DCS" folder (if lfs was desanitized). -- AirbossStennis:Load() -- -- -- Automatically save player results to your "Saved Games\DCS" folder each time a player get a final grade from the LSO. -- AirbossStennis:SetAutoSave() -- -- -- Start airboss class. -- AirbossStennis:Start() -- -- === -- -- # Debugging -- -- In case you have problems, it is always a good idea to have a look at your DCS log file. You find it in your "Saved Games" folder, so for example in -- C:\Users\\Saved Games\DCS\Logs\dcs.log -- All output concerning the @{#AIRBOSS} class should have the string "AIRBOSS" in the corresponding line. -- Searching for lines that contain the string "error" or "nil" can also give you a hint what's wrong. -- -- The verbosity of the output can be increased by adding the following lines to your script: -- -- BASE:TraceOnOff(true) -- BASE:TraceLevel(1) -- BASE:TraceClass("AIRBOSS") -- -- To get even more output you can increase the trace level to 2 or even 3, c.f. @{Core.Base#BASE} for more details. -- -- ### Debug Mode -- -- You have the option to enable the debug mode for this class via the @{#AIRBOSS.SetDebugModeON} function. -- If enabled, status and debug text messages will be displayed on the screen. Also informative marks on the F10 map are created. -- -- @field #AIRBOSS AIRBOSS = { ClassName = "AIRBOSS", Debug = false, lid = nil, theatre = nil, carrier = nil, carriertype = nil, carrierparam = {}, alias = nil, airbase = nil, waypoints = {}, currentwp = nil, beacon = nil, TACANon = nil, TACANchannel = nil, TACANmode = nil, TACANmorse = nil, ICLSon = nil, ICLSchannel = nil, ICLSmorse = nil, LSORadio = nil, LSOFreq = nil, LSOModu = nil, MarshalRadio = nil, MarshalFreq = nil, MarshalModu = nil, TowerFreq = nil, radiotimer = nil, zoneCCA = nil, zoneCCZ = nil, players = {}, menuadded = {}, BreakEntry = {}, BreakEarly = {}, BreakLate = {}, Abeam = {}, Ninety = {}, Wake = {}, Final = {}, Groove = {}, Platform = {}, DirtyUp = {}, Bullseye = {}, defaultcase = nil, case = nil, defaultoffset = nil, holdingoffset = nil, recoverytimes = {}, flights = {}, Qpattern = {}, Qmarshal = {}, Qwaiting = {}, Qspinning = {}, RQMarshal = {}, RQLSO = {}, TQMarshal = 0, TQLSO = 0, Nmaxpattern = nil, Nmaxmarshal = nil, NmaxSection = nil, NmaxStack = nil, handleai = nil, xtVoiceOvers = nil, xtVoiceOversAI = nil, tanker = nil, Corientation = nil, Corientlast = nil, Cposition = nil, defaultskill = nil, adinfinitum = nil, magvar = nil, Tcollapse = nil, recoverywindow = nil, usersoundradio = nil, Tqueue = nil, dTqueue = nil, dTstatus = nil, menumarkzones = nil, menusmokezones = nil, playerscores = nil, autosave = nil, autosavefile = nil, autosavepath = nil, marshalradius = nil, airbossnice = nil, staticweather = nil, windowcount = 0, LSOdT = nil, senderac = nil, radiorelayLSO = nil, radiorelayMSH = nil, turnintowind = nil, detour = nil, squadsetAI = nil, excludesetAI = nil, menusingle = nil, collisiondist = nil, holdtimestamp = nil, Tmessage = nil, soundfolder = nil, soundfolderLSO = nil, soundfolderMSH = nil, despawnshutdown= nil, dTbeacon = nil, Tbeacon = nil, LSOCall = nil, MarshalCall = nil, lowfuelAI = nil, emergency = nil, respawnAI = nil, gle = {}, lue = {}, trapsheet = nil, trappath = nil, trapprefix = nil, initialmaxalt = nil, welcome = nil, skipperMenu = nil, skipperSpeed = nil, skipperTime = nil, skipperOffset = nil, skipperUturn = nil, } --- Aircraft types capable of landing on carrier (human+AI). -- @type AIRBOSS.AircraftCarrier -- @field #string AV8B AV-8B Night Harrier. Works only with the HMS Hermes, HMS Invincible, USS Tarawa, USS America, and Juan Carlos I. -- @field #string A4EC A-4E Community mod. -- @field #string HORNET F/A-18C Lot 20 Hornet by Eagle Dynamics. -- @field #string F14A F-14A by Heatblur. -- @field #string F14B F-14B by Heatblur. -- @field #string F14A_AI F-14A Tomcat (AI). -- @field #string FA18C F/A-18C Hornet (AI). -- @field #string S3B Lockheed S-3B Viking. -- @field #string S3BTANKER Lockheed S-3B Viking tanker. -- @field #string E2D Grumman E-2D Hawkeye AWACS. -- @field #string C2A Grumman C-2A Greyhound from Military Aircraft Mod. -- @field #string T45C T-45C by VNAO. -- @field #string RHINOE F/A-18E Superhornet (mod). -- @field #string RHINOF F/A-18F Superhornet (mod). -- @field #string GROWLER FEA-18G Superhornet (mod). AIRBOSS.AircraftCarrier={ AV8B="AV8BNA", HORNET="FA-18C_hornet", A4EC="A-4E-C", F14A="F-14A-135-GR", F14B="F-14B", F14A_AI="F-14A", FA18C="F/A-18C", T45C="T-45", S3B="S-3B", S3BTANKER="S-3B Tanker", E2D="E-2C", C2A="C2A_Greyhound", RHINOE="FA-18E", RHINOF="FA-18F", GROWLER="EA-18G", } --- Carrier types. -- @type AIRBOSS.CarrierType -- @field #string ROOSEVELT USS Theodore Roosevelt (CVN-71) [Super Carrier Module] -- @field #string LINCOLN USS Abraham Lincoln (CVN-72) [Super Carrier Module] -- @field #string WASHINGTON USS George Washington (CVN-73) [Super Carrier Module] -- @field #string STENNIS USS John C. Stennis (CVN-74) -- @field #string TRUMAN USS Harry S. Truman (CVN-75) [Super Carrier Module] -- @field #string FORRESTAL USS Forrestal (CV-59) [Heatblur Carrier Module] -- @field #string VINSON USS Carl Vinson (CVN-70) [Deprecated!] -- @field #string HERMES HMS Hermes (R12) [V/STOL Carrier] -- @field #string INVINCIBLE HMS Invincible (R05) [V/STOL Carrier] -- @field #string TARAWA USS Tarawa (LHA-1) [V/STOL Carrier] -- @field #string AMERICA USS America (LHA-6) [V/STOL Carrier] -- @field #string JCARLOS Juan Carlos I (L61) [V/STOL Carrier] -- @field #string HMAS Canberra (L02) [V/STOL Carrier] -- @field #string KUZNETSOV Admiral Kuznetsov (CV 1143.5) AIRBOSS.CarrierType = { ROOSEVELT = "CVN_71", LINCOLN = "CVN_72", WASHINGTON = "CVN_73", TRUMAN = "CVN_75", STENNIS = "Stennis", FORRESTAL = "Forrestal", VINSON = "VINSON", HERMES = "HERMES81", INVINCIBLE = "hms_invincible", TARAWA = "LHA_Tarawa", AMERICA = "USS America LHA-6", JCARLOS = "L61", CANBERRA = "L02", KUZNETSOV = "KUZNECOW", } --- Carrier specific parameters. -- @type AIRBOSS.CarrierParameters -- @field #number rwyangle Runway angle in degrees. for carriers with angled deck. For USS Stennis -9 degrees. -- @field #number sterndist Distance in meters from carrier position to stern of carrier. For USS Stennis -150 meters. -- @field #number deckheight Height of deck in meters. For USS Stennis ~63 ft = 19 meters. -- @field #number wire1 Distance in meters from carrier position to first wire. -- @field #number wire2 Distance in meters from carrier position to second wire. -- @field #number wire3 Distance in meters from carrier position to third wire. -- @field #number wire4 Distance in meters from carrier position to fourth wire. -- @field #number landingdist Distance in meeters to the landing position. -- @field #number rwylength Length of the landing runway in meters. -- @field #number rwywidth Width of the landing runway in meters. -- @field #number totlength Total length of carrier. -- @field #number totwidthstarboard Total with of the carrier from stern position to starboard side (asymmetric carriers). -- @field #number totwidthport Total with of the carrier from stern position to port side (asymmetric carriers). --- Aircraft specific Angle of Attack (AoA) (or alpha) parameters. -- @type AIRBOSS.AircraftAoA -- @field #number OnSpeedMin Minimum on speed AoA. Values below are fast -- @field #number OnSpeedMax Maximum on speed AoA. Values above are slow. -- @field #number OnSpeed Optimal on-speed AoA. -- @field #number Fast Fast AoA threshold. Smaller means faster. -- @field #number Slow Slow AoA threshold. Larger means slower. -- @field #number FAST Really fast AoA threshold. -- @field #number SLOW Really slow AoA threshold. --- Glideslope error thresholds in degrees. -- @type AIRBOSS.GLE -- @field #number _max Max _OK_ value. Default 0.4 deg. -- @field #number _min Min _OK_ value. Default -0.3 deg. -- @field #number High (H) threshold. Default 0.8 deg. -- @field #number Low (L) threshold. Default -0.6 deg. -- @field #number HIGH H threshold. Default 1.5 deg. -- @field #number LOW L threshold. Default -0.9 deg. --- Lineup error thresholds in degrees. -- @type AIRBOSS.LUE -- @field #number _max Max _OK_ value. Default 0.5 deg. -- @field #number _min Min _OK_ value. Default -0.5 deg. -- @field #number Left (LUR) threshold. Default -1.0 deg. -- @field #number Right (LUL) threshold. Default 1.0 deg. -- @field #number LeftMed threshold for AA/OS measuring. Default -2.0 deg. -- @field #number RightMed threshold for AA/OS measuring. Default 2.0 deg. -- @field #number LEFT LUR threshold. Default -3.0 deg. -- @field #number RIGHT LUL threshold. Default 3.0 deg. --- Pattern steps. -- @type AIRBOSS.PatternStep -- @field #string UNDEFINED "Undefined". -- @field #string REFUELING "Refueling". -- @field #string SPINNING "Spinning". -- @field #string COMMENCING "Commencing". -- @field #string HOLDING "Holding". -- @field #string WAITING "Waiting for free Marshal stack". -- @field #string PLATFORM "Platform". -- @field #string ARCIN "Arc Turn In". -- @field #string ARCOUT "Arc Turn Out". -- @field #string DIRTYUP "Dirty Up". -- @field #string BULLSEYE "Bullseye". -- @field #string INITIAL "Initial". -- @field #string BREAKENTRY "Break Entry". -- @field #string EARLYBREAK "Early Break". -- @field #string LATEBREAK "Late Break". -- @field #string ABEAM "Abeam". -- @field #string NINETY "Ninety". -- @field #string WAKE "Wake". -- @field #string FINAL "Final". -- @field #string GROOVE_XX "Groove X". -- @field #string GROOVE_IM "Groove In the Middle". -- @field #string GROOVE_IC "Groove In Close". -- @field #string GROOVE_AR "Groove At the Ramp". -- @field #string GROOVE_AL "Groove Abeam Landing Spot". -- @field #string GROOVE_LC "Groove Level Cross". -- @field #string GROOVE_IW "Groove In the Wires". -- @field #string BOLTER "Bolter Pattern". -- @field #string EMERGENCY "Emergency Landing". -- @field #string DEBRIEF "Debrief". AIRBOSS.PatternStep = { UNDEFINED = "Undefined", REFUELING = "Refueling", SPINNING = "Spinning", COMMENCING = "Commencing", HOLDING = "Holding", WAITING = "Waiting for free Marshal stack", PLATFORM = "Platform", ARCIN = "Arc Turn In", ARCOUT = "Arc Turn Out", DIRTYUP = "Dirty Up", BULLSEYE = "Bullseye", INITIAL = "Initial", BREAKENTRY = "Break Entry", EARLYBREAK = "Early Break", LATEBREAK = "Late Break", ABEAM = "Abeam", NINETY = "Ninety", WAKE = "Wake", FINAL = "Turn Final", GROOVE_XX = "Groove X", GROOVE_IM = "Groove In the Middle", GROOVE_IC = "Groove In Close", GROOVE_AR = "Groove At the Ramp", GROOVE_IW = "Groove In the Wires", GROOVE_AL = "Groove Abeam Landing Spot", GROOVE_LC = "Groove Level Cross", BOLTER = "Bolter Pattern", EMERGENCY = "Emergency Landing", DEBRIEF = "Debrief", } --- Groove position. -- @type AIRBOSS.GroovePos -- @field #string X0 "X0": Entering the groove. -- @field #string XX "XX": At the start, i.e. 3/4 from the run down. -- @field #string IM "IM": In the middle. -- @field #string IC "IC": In close. -- @field #string AR "AR": At the ramp. -- @field #string AL "AL": Abeam landing position (V/STOL). -- @field #string LC "LC": Level crossing (V/STOL). -- @field #string IW "IW": In the wires. AIRBOSS.GroovePos = { X0 = "X0", XX = "XX", IM = "IM", IC = "IC", AR = "AR", AL = "AL", LC = "LC", IW = "IW", } --- Radio. -- @type AIRBOSS.Radio -- @field #number frequency Frequency in Hz. -- @field #number modulation Band modulation. -- @field #string alias Radio alias. --- Radio sound file and subtitle. -- @type AIRBOSS.RadioCall -- @field #string file Sound file name without suffix. -- @field #string suffix File suffix/extension, e.g. "ogg". -- @field #boolean loud Loud version of sound file available. -- @field #string subtitle Subtitle displayed during transmission. -- @field #number duration Duration of the sound in seconds. This is also the duration the subtitle is displayed. -- @field #number subduration Duration in seconds the subtitle is displayed. -- @field #string modexsender Onboard number of the sender (optional). -- @field #string modexreceiver Onboard number of the receiver (optional). -- @field #string sender Sender of the message (optional). Default radio alias. --- Pilot radio calls. -- type AIRBOSS.PilotCalls -- @field #AIRBOSS.RadioCall N0 "Zero" call. -- @field #AIRBOSS.RadioCall N1 "One" call. -- @field #AIRBOSS.RadioCall N2 "Two" call. -- @field #AIRBOSS.RadioCall N3 "Three" call. -- @field #AIRBOSS.RadioCall N4 "Four" call. -- @field #AIRBOSS.RadioCall N5 "Five" call. -- @field #AIRBOSS.RadioCall N6 "Six" call. -- @field #AIRBOSS.RadioCall N7 "Seven" call. -- @field #AIRBOSS.RadioCall N8 "Eight" call. -- @field #AIRBOSS.RadioCall N9 "Nine" call. -- @field #AIRBOSS.RadioCall POINT "Point" call. -- @field #AIRBOSS.RadioCall BALL "Ball" call. -- @field #AIRBOSS.RadioCall HARRIER "Harrier" call. -- @field #AIRBOSS.RadioCall HAWKEYE "Hawkeye" call. -- @field #AIRBOSS.RadioCall HORNET "Hornet" call. -- @field #AIRBOSS.RadioCall SKYHAWK "Skyhawk" call. -- @field #AIRBOSS.RadioCall TOMCAT "Tomcat" call. -- @field #AIRBOSS.RadioCall VIKING "Viking" call. -- @field #AIRBOSS.RadioCall BINGOFUEL "Bingo Fuel" call. -- @field #AIRBOSS.RadioCall GASATDIVERT "Going for gas at the divert field" call. -- @field #AIRBOSS.RadioCall GASATTANKER "Going for gas at the recovery tanker" call. --- LSO radio calls. -- @type AIRBOSS.LSOCalls -- @field #AIRBOSS.RadioCall BOLTER "Bolter, Bolter" call. -- @field #AIRBOSS.RadioCall CALLTHEBALL "Call the Ball" call. -- @field #AIRBOSS.RadioCall CHECK "CHECK" call. -- @field #AIRBOSS.RadioCall CLEAREDTOLAND "Cleared to land" call. -- @field #AIRBOSS.RadioCall COMELEFT "Come left" call. -- @field #AIRBOSS.RadioCall DEPARTANDREENTER "Depart and re-enter" call. -- @field #AIRBOSS.RadioCall EXPECTHEAVYWAVEOFF "Expect heavy wavoff" call. -- @field #AIRBOSS.RadioCall EXPECTSPOT75 "Expect spot 7.5" call. -- @field #AIRBOSS.RadioCall EXPECTSPOT5 "Expect spot 5" call. -- @field #AIRBOSS.RadioCall FAST "You're fast" call. -- @field #AIRBOSS.RadioCall FOULDECK "Foul Deck" call. -- @field #AIRBOSS.RadioCall HIGH "You're high" call. -- @field #AIRBOSS.RadioCall IDLE "Idle" call. -- @field #AIRBOSS.RadioCall LONGINGROOVE "You're long in the groove" call. -- @field #AIRBOSS.RadioCall LOW "You're low" call. -- @field #AIRBOSS.RadioCall N0 "Zero" call. -- @field #AIRBOSS.RadioCall N1 "One" call. -- @field #AIRBOSS.RadioCall N2 "Two" call. -- @field #AIRBOSS.RadioCall N3 "Three" call. -- @field #AIRBOSS.RadioCall N4 "Four" call. -- @field #AIRBOSS.RadioCall N5 "Five" call. -- @field #AIRBOSS.RadioCall N6 "Six" call. -- @field #AIRBOSS.RadioCall N7 "Seven" call. -- @field #AIRBOSS.RadioCall N8 "Eight" call. -- @field #AIRBOSS.RadioCall N9 "Nine" call. -- @field #AIRBOSS.RadioCall PADDLESCONTACT "Paddles, contact" call. -- @field #AIRBOSS.RadioCall POWER "Power" call. -- @field #AIRBOSS.RadioCall RADIOCHECK "Paddles, radio check" call. -- @field #AIRBOSS.RadioCall RIGHTFORLINEUP "Right for line up" call. -- @field #AIRBOSS.RadioCall ROGERBALL "Roger ball" call. -- @field #AIRBOSS.RadioCall SLOW "You're slow" call. -- @field #AIRBOSS.RadioCall STABILIZED "Stabilized" call. -- @field #AIRBOSS.RadioCall WAVEOFF "Wave off" call. -- @field #AIRBOSS.RadioCall WELCOMEABOARD "Welcome aboard" call. -- @field #AIRBOSS.RadioCall CLICK Radio end transmission click sound. -- @field #AIRBOSS.RadioCall NOISE Static noise sound. -- @field #AIRBOSS.RadioCall SPINIT "Spin it" call. --- Marshal radio calls. -- @type AIRBOSS.MarshalCalls -- @field #AIRBOSS.RadioCall AFFIRMATIVE "Affirmative" call. -- @field #AIRBOSS.RadioCall ALTIMETER "Altimeter" call. -- @field #AIRBOSS.RadioCall BRC "BRC" call. -- @field #AIRBOSS.RadioCall CARRIERTURNTOHEADING "Turn to heading" call. -- @field #AIRBOSS.RadioCall CASE "Case" call. -- @field #AIRBOSS.RadioCall CHARLIETIME "Charlie Time" call. -- @field #AIRBOSS.RadioCall CLEAREDFORRECOVERY "You're cleared for case" call. -- @field #AIRBOSS.RadioCall DECKCLOSED "Deck closed" sound. -- @field #AIRBOSS.RadioCall DEGREES "Degrees" call. -- @field #AIRBOSS.RadioCall EXPECTED "Expected" call. -- @field #AIRBOSS.RadioCall FLYNEEDLES "Fly your needles" call. -- @field #AIRBOSS.RadioCall HOLDATANGELS "Hold at angels" call. -- @field #AIRBOSS.RadioCall HOURS "Hours" sound. -- @field #AIRBOSS.RadioCall MARSHALRADIAL "Marshal radial" call. -- @field #AIRBOSS.RadioCall N0 "Zero" call. -- @field #AIRBOSS.RadioCall N1 "One" call. -- @field #AIRBOSS.RadioCall N2 "Two" call. -- @field #AIRBOSS.RadioCall N3 "Three" call. -- @field #AIRBOSS.RadioCall N4 "Four" call. -- @field #AIRBOSS.RadioCall N5 "Five" call. -- @field #AIRBOSS.RadioCall N6 "Six" call. -- @field #AIRBOSS.RadioCall N7 "Seven" call. -- @field #AIRBOSS.RadioCall N8 "Eight" call. -- @field #AIRBOSS.RadioCall N9 "Nine" call. -- @field #AIRBOSS.RadioCall NEGATIVE "Negative" sound. -- @field #AIRBOSS.RadioCall NEWFB "New final bearing" call. -- @field #AIRBOSS.RadioCall OBS "Obs" call. -- @field #AIRBOSS.RadioCall POINT "Point" call. -- @field #AIRBOSS.RadioCall RADIOCHECK "Radio check" call. -- @field #AIRBOSS.RadioCall RECOVERY "Recovery" call. -- @field #AIRBOSS.RadioCall RECOVERYOPSSTOPPED "Recovery ops stopped" sound. -- @field #AIRBOSS.RadioCall RECOVERYPAUSEDNOTICE "Recovery paused until further notice" call. -- @field #AIRBOSS.RadioCall RECOVERYPAUSEDRESUMED "Recovery paused and will be resumed at" call. -- @field #AIRBOSS.RadioCall RESUMERECOVERY "Resuming aircraft recovery" call. -- @field #AIRBOSS.RadioCall REPORTSEEME "Report see me" call. -- @field #AIRBOSS.RadioCall ROGER "Roger" call. -- @field #AIRBOSS.RadioCall SAYNEEDLES "Say needles" call. -- @field #AIRBOSS.RadioCall STACKFULL "Marshal stack is currently full. Hold outside 10 NM zone and wait for further instructions" call. -- @field #AIRBOSS.RadioCall STARTINGRECOVERY "Starting aircraft recovery" call. -- @field #AIRBOSS.RadioCall CLICK Radio end transmission click sound. -- @field #AIRBOSS.RadioCall NOISE Static noise sound. --- Difficulty level. -- @type AIRBOSS.Difficulty -- @field #string EASY Flight Student. Shows tips and hints in important phases of the approach. -- @field #string NORMAL Naval aviator. Moderate number of hints but not really zip lip. -- @field #string HARD TOPGUN graduate. For people who know what they are doing. Nearly *ziplip*. AIRBOSS.Difficulty = { EASY = "Flight Student", NORMAL = "Naval Aviator", HARD = "TOPGUN Graduate", } --- Recovery window parameters. -- @type AIRBOSS.Recovery -- @field #number START Start of recovery in seconds of abs mission time. -- @field #number STOP End of recovery in seconds of abs mission time. -- @field #number CASE Recovery case (1-3) of that time slot. -- @field #number OFFSET Angle offset of the holding pattern in degrees. Usually 0, +-15, or +-30 degrees. -- @field #boolean OPEN Recovery window is currently open. -- @field #boolean OVER Recovery window is over and closed. -- @field #boolean WIND Carrier will turn into the wind. -- @field #number SPEED The speed in knots the carrier has during the recovery. -- @field #boolean UTURN If true, carrier makes a U-turn to the point it came from before resuming its route to the next waypoint. -- @field #number ID Recovery window ID. --- Groove data. -- @type AIRBOSS.GrooveData -- @field #number Step Current step. -- @field #number Time Time in seconds. -- @field #number Rho Distance in meters. -- @field #number X Distance in meters. -- @field #number Z Distance in meters. -- @field #number AoA Angle of Attack. -- @field #number Alt Altitude in meters. -- @field #number GSE Glideslope error in degrees. -- @field #number LUE Lineup error in degrees. -- @field #number Pitch Pitch angle in degrees. -- @field #number Roll Roll angle in degrees. -- @field #number Yaw Yaw angle in degrees. -- @field #number Vel Total velocity in m/s. -- @field #number Vy Vertical velocity in m/s. -- @field #number Gamma Relative heading player to carrier's runway. 0=parallel, +-90=perpendicular. -- @field #string Grade LSO grade. -- @field #number GradePoints LSO grade points -- @field #string GradeDetail LSO grade details. -- @field #string FlyThrough Fly through up "/" or fly through down "\\". --- LSO grade data. -- @type AIRBOSS.LSOgrade -- @field #string grade LSO grade, i.e. _OK_, OK, (OK), --, CUT -- @field #number points Points received. -- @field #number finalscore Points received after player has finally landed. This is the average over all incomplete passes (bolter, waveoff) before. -- @field #string details Detailed flight analysis. -- @field #number wire Wire caught. -- @field #number Tgroove Time in the groove in seconds. -- @field #number case Recovery case. -- @field #string wind Wind speed on deck in knots. -- @field #string modex Onboard number. -- @field #string airframe Aircraft type name of player. -- @field #string carriertype Carrier type name. -- @field #string carriername Carrier name/alias. -- @field #string theatre DCS map. -- @field #string mitime Mission time in hh:mm:ss+d format -- @field #string midate Mission date in yyyy/mm/dd format. -- @field #string osdate Real live date. Needs **os** to be desanitized. --- Checkpoint parameters triggering the next step in the pattern. -- @type AIRBOSS.Checkpoint -- @field #string name Name of checkpoint. -- @field #number Xmin Minimum allowed longitual distance to carrier. -- @field #number Xmax Maximum allowed longitual distance to carrier. -- @field #number Zmin Minimum allowed latitudal distance to carrier. -- @field #number Zmax Maximum allowed latitudal distance to carrier. -- @field #number LimitXmin Latitudal threshold for triggering the next step if XXmax. -- @field #number LimitZmin Latitudal threshold for triggering the next step if ZZmax. --- Parameters of a flight group. -- @type AIRBOSS.FlightGroup -- @field Wrapper.Group#GROUP group Flight group. -- @field #string groupname Name of the group. -- @field #number nunits Number of units in group. -- @field #number dist0 Distance to carrier in meters when the group was first detected inside the CCA. -- @field #number time Timestamp in seconds of timer.getAbsTime() of the last important event, e.g. added to the queue. -- @field #number flag Flag value describing the current stack. -- @field #boolean ai If true, flight is purly AI. -- @field #string actype Aircraft type name. -- @field #table onboardnumbers Onboard numbers of aircraft in the group. -- @field #string onboard Onboard number of player or first unit in group. -- @field #number case Recovery case of flight. -- @field #string seclead Name of section lead. -- @field #table section Other human flight groups belonging to this flight. This flight is the lead. -- @field #boolean holding If true, flight is in holding zone. -- @field #boolean ballcall If true, flight called the ball in the groove. -- @field #table elements Flight group elements. -- @field #number Tcharlie Charlie (abs) time in seconds. -- @field #string name Player name or name of first AI unit. -- @field #boolean refueling Flight is refueling. --- Parameters of an element in a flight group. -- @type AIRBOSS.FlightElement -- @field Wrapper.Unit#UNIT unit Aircraft unit. -- @field #string unitname Name of the unit. -- @field #boolean ai If true, AI sits inside. If false, human player is flying. -- @field #string onboard Onboard number of the aircraft. -- @field #boolean ballcall If true, flight called the ball in the groove. -- @field #boolean recovered If true, element was successfully recovered. --- Player data table holding all important parameters of each player. -- @type AIRBOSS.PlayerData -- @field Wrapper.Unit#UNIT unit Aircraft of the player. -- @field #string unitname Name of the unit. -- @field Wrapper.Client#CLIENT client Client object of player. -- @field #string callsign Callsign of player. -- @field #string difficulty Difficulty level. -- @field #string step Current/next pattern step. -- @field #boolean warning Set true once the player got a warning. -- @field #number passes Number of passes. -- @field #boolean attitudemonitor If true, display aircraft attitude and other parameters constantly. -- @field #table debrief Debrief analysis of the current step of this pass. -- @field #table lastdebrief Debrief of player performance of last completed pass. -- @field #boolean landed If true, player landed or attempted to land. -- @field #boolean boltered If true, player boltered. -- @field #boolean waveoff If true, player was waved off during final approach. -- @field #boolean wop If true, player was waved off during the pattern. -- @field #boolean lig If true, player was long in the groove. -- @field #boolean owo If true, own waveoff by player. -- @field #boolean wofd If true, player was waved off because of a foul deck. -- @field #number Tlso Last time the LSO gave an advice. -- @field #number Tgroove Time in the groove in seconds. -- @field #number TIG0 Time in groove start timer.getTime(). -- @field #number wire Wire caught by player when trapped. -- @field #AIRBOSS.GroovePos groove Data table at each position in the groove. Elements are of type @{#AIRBOSS.GrooveData}. -- @field #table points Points of passes until finally landed. -- @field #number finalscore Final score if points are averaged over multiple passes. -- @field #boolean valid If true, player made a valid approach. Is set true on start of Groove X. -- @field #boolean subtitles If true, display subtitles of radio messages. -- @field #boolean showhints If true, show step hints. -- @field #table trapsheet Groove data table recorded every 0.5 seconds. -- @field #boolean trapon If true, save trap sheets. -- @field #string debriefschedulerID Debrief scheduler ID. -- -- @field Sound.SRS#MSRS SRS -- @field Sound.SRS#MSRSQUEUE SRSQ -- -- @extends #AIRBOSS.FlightGroup --- Main group level radio menu: F10 Other/Airboss. -- @field #table MenuF10 AIRBOSS.MenuF10 = {} --- Airboss mission level F10 root menu. -- @field #table MenuF10Root AIRBOSS.MenuF10Root = nil --- Airboss class version. -- @field #string version AIRBOSS.version = "1.3.3" ------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- -- TODO list ------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- -- DONE: Handle tanker and AWACS. Put them into pattern. -- TODO: Handle cases where AI crashes on carrier deck ==> Clean up deck. -- TODO: Player eject and crash debrief "gradings". -- TODO: PWO during case 2/3. -- TODO: PWO when player comes too close to other flight. -- DONE: Spin pattern. Add radio menu entry. Not sure what to add though?! -- DONE: Despawn AI after engine shutdown option. -- DONE: What happens when section lead or member dies? -- DONE: Do not remove recovered elements but only set switch. Remove only groups which are completely recovered. -- DONE: Option to filter AI groups for recovery. -- DONE: Rework radio messages. Better control over player board numbers. -- DONE: Case I & II/III zone so that player gets into pattern automatically. Case I 3 position on the circle. Case II/III when the player enters the approach corridor maybe? -- DONE: Add static weather information. -- DONE: Allow up to two flights per Case I marshal stack. -- DONE: Add max stack for Case I and define waiting queue outside CCZ. -- DONE: Maybe do an additional step at the initial (Case II) or bullseye (Case III) and register player in case he missed some steps. -- DONE: Subtitles off options on player level. -- DONE: Persistence of results. -- DONE: Foul deck waveoff. -- DONE: Get Charlie time estimate function. -- DONE: Average player grades until landing. -- DONE: Check player heading at zones, e.g. initial. -- DONE: Fix bug that player leaves the approach zone if he boltered or was waved off during Case II or III. NOTE: Partly due to increasing approach zone size. -- DONE: Fix bug that player gets an altitude warning if stack collapses. NOTE: Would not work if two stacks Case I and II/III are used. -- DONE: Improve radio messages. Maybe usersound for messages which are only meant for players? -- DONE: Add voice over fly needs and welcome aboard. -- DONE: Improve trapped wire calculation. -- DONE: Carrier zone with dimensions of carrier. to check if landing happened on deck. -- DONE: Carrier runway zone for fould deck check. -- DONE: More Hints for Case II/III. -- DONE: Set magnetic declination function. -- DONE: First send AI to marshal and then allow them into the landing pattern ==> task function when reaching the waypoint. -- DONE: Extract (static) weather from mission for cloud cover etc. -- DONE: Check distance to players during approach. -- DONE: Option to turn AI handling off. -- DONE: Add user functions. -- DONE: Update AI holding pattern wrt to moving carrier. -- DONE: Generalize parameters for other carriers. -- DONE: Generalize parameters for other aircraft. -- DONE: Add radio check (LSO, AIRBOSS) to F10 radio menu. -- DONE: Right pattern step after bolter/wo/patternWO? Guess so. -- DONE: Set case II and III times (via recovery time). -- DONE: Get correct wire when trapped. DONE but might need further tweaking. -- DONE: Add radio transmission queue for LSO and airboss. -- DONE: CASE II. -- DONE: CASE III. -- NOPE: Strike group with helo bringing cargo etc. Not yet. -- DONE: Handle crash event. Delete A/C from queue, send rescue helo. -- DONE: Get fuel state in pounds. (working for the hornet, did not check others) -- DONE: Add aircraft numbers in queue to carrier info F10 radio output. -- DONE: Monitor holding of players/AI in zoneHolding. -- DONE: Transmission via radio. -- DONE: Get board numbers. -- DONE: Get an _OK_ pass if long in groove. Possible other pattern wave offs as well?! -- DONE: Add scoring to radio menu. -- DONE: Optimized debrief. -- DONE: Add automatic grading. -- DONE: Fix radio menu. ------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- -- Constructor ------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- --- Create a new AIRBOSS class object for a specific aircraft carrier unit. -- @param #AIRBOSS self -- @param carriername Name of the aircraft carrier unit as defined in the mission editor. -- @param alias (Optional) Alias for the carrier. This will be used for radio messages and the F10 radius menu. Default is the carrier name as defined in the mission editor. -- @return #AIRBOSS self or nil if carrier unit does not exist. function AIRBOSS:New( carriername, alias ) -- Inherit everthing from FSM class. local self = BASE:Inherit( self, FSM:New() ) -- #AIRBOSS -- Debug. self:F2( { carriername = carriername, alias = alias } ) -- Set carrier unit. self.carrier = UNIT:FindByName( carriername ) -- Check if carrier unit exists. if self.carrier == nil then -- Error message. local text = string.format( "ERROR: Carrier unit %s could not be found! Make sure this UNIT is defined in the mission editor and check the spelling of the unit name carefully.", carriername ) MESSAGE:New( text, 120 ):ToAll() self:E( text ) return nil end -- Set some string id for output to DCS.log file. self.lid = string.format( "AIRBOSS %s | ", carriername ) -- Current map. self.theatre = env.mission.theatre self:T2( self.lid .. string.format( "Theatre = %s.", tostring( self.theatre ) ) ) -- Get carrier type. self.carriertype = self.carrier:GetTypeName() -- Set alias. self.alias = alias or carriername -- Set carrier airbase object. self.airbase = AIRBASE:FindByName( carriername ) -- Create carrier beacon. self.beacon = BEACON:New( self.carrier ) -- Set Tower Frequency of carrier. self:_GetTowerFrequency() -- Init player scores table. self.playerscores = {} -- Initialize ME waypoints. self:_InitWaypoints() -- Current waypoint. self.currentwp = 1 -- Patrol route. self:_PatrolRoute() ------------- --- Defaults: ------------- -- Set up Airboss radio. self:SetMarshalRadio() self:SetAirbossRadio() -- Set up LSO radio. self:SetLSORadio() -- Set LSO call interval. Default 4 sec. self:SetLSOCallInterval() -- Radio scheduler. self.radiotimer = SCHEDULER:New() -- Set magnetic declination. self:SetMagneticDeclination() -- Set ICSL to channel 1. self:SetICLS() -- Set TACAN to channel 74X. self:SetTACAN() -- Becons are reactivated very 5 min. self:SetBeaconRefresh() -- Set max aircraft in landing pattern. Default 4. self:SetMaxLandingPattern() -- Set max Case I Marshal stacks. Default 3. self:SetMaxMarshalStacks() -- Set max section members. Default 2. self:SetMaxSectionSize() -- Set max flights per stack. Default is 2. self:SetMaxFlightsPerStack() -- Set AI handling On. self:SetHandleAION() -- No extra voiceover/calls from player by default self:SetExtraVoiceOvers(false) -- No extra voiceover/calls from AI by default self:SetExtraVoiceOversAI(false) -- Airboss is a nice guy. self:SetAirbossNiceGuy() -- Allow emergency landings. self:SetEmergencyLandings() -- No despawn after engine shutdown by default. self:SetDespawnOnEngineShutdown( false ) -- No respawning of AI groups when entering the CCA. self:SetRespawnAI( false ) -- Mission uses static weather by default. self:SetStaticWeather() -- Default recovery case. This sets self.defaultcase and self.case. Default Case I. self:SetRecoveryCase() -- Set time the turn starts before the window opens. self:SetRecoveryTurnTime() -- Set holding offset to 0 degrees. This set self.defaultoffset and self.holdingoffset. self:SetHoldingOffsetAngle() -- Set Marshal stack radius. Default 2.75 NM, which gives a diameter of 5.5 NM. self:SetMarshalRadius() -- Set max alt at initial. Default 1300 ft. self:SetInitialMaxAlt() -- Default player skill EASY. self:SetDefaultPlayerSkill( AIRBOSS.Difficulty.EASY ) -- Default glideslope error thresholds. self:SetGlideslopeErrorThresholds() -- Default lineup error thresholds. self:SetLineupErrorThresholds() -- CCA 50 NM radius zone around the carrier. self:SetCarrierControlledArea() -- CCZ 5 NM radius zone around the carrier. self:SetCarrierControlledZone() -- Carrier patrols its waypoints until the end of time. self:SetPatrolAdInfinitum( true ) -- Collision check distance. Default 5 NM. self:SetCollisionDistance() -- Set update time intervals. self:SetQueueUpdateTime() self:SetStatusUpdateTime() self:SetDefaultMessageDuration() -- Menu options. self:SetMenuMarkZones() self:SetMenuSmokeZones() self:SetMenuSingleCarrier( false ) -- Welcome players. self:SetWelcomePlayers( true ) -- Coordinates self.landingcoord = COORDINATE:New( 0, 0, 0 ) -- Core.Point#COORDINATE self.sterncoord = COORDINATE:New( 0, 0, 0 ) -- Core.Point#COORDINATE self.landingspotcoord = COORDINATE:New( 0, 0, 0 ) -- Core.Point#COORDINATE -- Init carrier parameters. if self.carriertype == AIRBOSS.CarrierType.STENNIS then -- Stennis parameters were updated to match the other Super Carriers. self:_InitNimitz() elseif self.carriertype == AIRBOSS.CarrierType.ROOSEVELT then self:_InitNimitz() elseif self.carriertype == AIRBOSS.CarrierType.LINCOLN then self:_InitNimitz() elseif self.carriertype == AIRBOSS.CarrierType.WASHINGTON then self:_InitNimitz() elseif self.carriertype == AIRBOSS.CarrierType.TRUMAN then self:_InitNimitz() elseif self.carriertype == AIRBOSS.CarrierType.FORRESTAL then self:_InitForrestal() elseif self.carriertype == AIRBOSS.CarrierType.VINSON then -- Carl Vinson is legacy now. self:_InitStennis() elseif self.carriertype == AIRBOSS.CarrierType.HERMES then -- Hermes parameters. self:_InitHermes() elseif self.carriertype == AIRBOSS.CarrierType.INVINCIBLE then -- Invincible parameters. self:_InitInvincible() elseif self.carriertype == AIRBOSS.CarrierType.TARAWA then -- Tarawa parameters. self:_InitTarawa() elseif self.carriertype == AIRBOSS.CarrierType.AMERICA then -- Use America parameters. self:_InitAmerica() elseif self.carriertype == AIRBOSS.CarrierType.JCARLOS then -- Use Juan Carlos parameters. self:_InitJcarlos() elseif self.carriertype == AIRBOSS.CarrierType.CANBERRA then -- Use Juan Carlos parameters at this stage. self:_InitCanberra() elseif self.carriertype == AIRBOSS.CarrierType.KUZNETSOV then -- Kusnetsov parameters - maybe... self:_InitStennis() else self:E( self.lid .. string.format( "ERROR: Unknown carrier type %s!", tostring( self.carriertype ) ) ) return nil end -- Init voice over files. self:_InitVoiceOvers() ------------------- -- Debug Section -- ------------------- -- Debug trace. if false then self.Debug = true BASE:TraceOnOff( true ) BASE:TraceClass( self.ClassName ) BASE:TraceLevel( 3 ) -- self.dTstatus=0.1 end -- Smoke zones. if false then local case = 3 self.holdingoffset = 30 self:_GetZoneGroove():SmokeZone( SMOKECOLOR.Red, 5 ) self:_GetZoneLineup():SmokeZone( SMOKECOLOR.Green, 5 ) self:_GetZoneBullseye( case ):SmokeZone( SMOKECOLOR.White, 45 ) self:_GetZoneDirtyUp( case ):SmokeZone( SMOKECOLOR.Orange, 45 ) self:_GetZoneArcIn( case ):SmokeZone( SMOKECOLOR.Blue, 45 ) self:_GetZoneArcOut( case ):SmokeZone( SMOKECOLOR.Blue, 45 ) self:_GetZonePlatform( case ):SmokeZone( SMOKECOLOR.Blue, 45 ) self:_GetZoneCorridor( case ):SmokeZone( SMOKECOLOR.Green, 45 ) self:_GetZoneHolding( case, 1 ):SmokeZone( SMOKECOLOR.White, 45 ) self:_GetZoneHolding( case, 2 ):SmokeZone( SMOKECOLOR.White, 45 ) self:_GetZoneInitial( case ):SmokeZone( SMOKECOLOR.Orange, 45 ) self:_GetZoneCommence( case, 1 ):SmokeZone( SMOKECOLOR.Red, 45 ) self:_GetZoneCommence( case, 2 ):SmokeZone( SMOKECOLOR.Red, 45 ) self:_GetZoneAbeamLandingSpot():SmokeZone( SMOKECOLOR.Red, 5 ) self:_GetZoneLandingSpot():SmokeZone( SMOKECOLOR.Red, 5 ) end -- Carrier parameter debug tests. if false then -- Stern coordinate. local FB = self:GetFinalBearing( false ) local hdg = self:GetHeading( false ) -- Stern pos. local stern = self:_GetSternCoord() -- Bow pos. local bow = stern:Translate( self.carrierparam.totlength, hdg, true ) -- End of rwy. local rwy = stern:Translate( self.carrierparam.rwylength, FB, true ) --- Flare points and zones. local function flareme() -- Carrier pos. self:GetCoordinate():FlareYellow() -- Stern stern:FlareYellow() -- Bow bow:FlareYellow() -- Runway half width = 10 m. local r1 = stern:Translate( self.carrierparam.rwywidth * 0.5, FB + 90, true ) local r2 = stern:Translate( self.carrierparam.rwywidth * 0.5, FB - 90, true ) -- r1:FlareWhite() -- r2:FlareWhite() -- End of runway. rwy:FlareRed() -- Right 30 meters from stern. local cR = stern:Translate( self.carrierparam.totwidthstarboard, hdg + 90, true ) -- cR:FlareYellow() -- Left 40 meters from stern. local cL = stern:Translate( self.carrierparam.totwidthport, hdg - 90, true ) -- cL:FlareYellow() -- Carrier specific. if self.carrier:GetTypeName() ~= AIRBOSS.CarrierType.INVINCIBLE or self.carrier:GetTypeName() ~= AIRBOSS.CarrierType.HERMES or self.carrier:GetTypeName() ~= AIRBOSS.CarrierType.TARAWA or self.carrier:GetTypeName() ~= AIRBOSS.CarrierType.AMERICA or self.carrier:GetTypeName() ~= AIRBOSS.CarrierType.JCARLOS or self.carrier:GetTypeName() ~= AIRBOSS.CarrierType.CANBERRA then -- Flare wires. local w1 = stern:Translate( self.carrierparam.wire1, FB, true ) local w2 = stern:Translate( self.carrierparam.wire2, FB, true ) local w3 = stern:Translate( self.carrierparam.wire3, FB, true ) local w4 = stern:Translate( self.carrierparam.wire4, FB, true ) w1:FlareWhite() w2:FlareYellow() w3:FlareWhite() w4:FlareYellow() else -- Abeam landing spot zone. local ALSPT = self:_GetZoneAbeamLandingSpot() ALSPT:FlareZone( FLARECOLOR.Red, 5, nil, UTILS.FeetToMeters( 120 ) ) -- Primary landing spot zone. local LSPT = self:_GetZoneLandingSpot() LSPT:FlareZone( FLARECOLOR.Green, 5, nil, self.carrierparam.deckheight ) -- Landing spot coordinate. local PLSC = self:_GetLandingSpotCoordinate() PLSC:FlareWhite() end -- Flare carrier and landing runway. local cbox = self:_GetZoneCarrierBox() local rbox = self:_GetZoneRunwayBox() cbox:FlareZone( FLARECOLOR.Green, 5, nil, self.carrierparam.deckheight ) rbox:FlareZone( FLARECOLOR.White, 5, nil, self.carrierparam.deckheight ) end -- Flare points every 3 seconds for 3 minutes. SCHEDULER:New( nil, flareme, {}, 1, 3, nil, 180 ) end ----------------------- --- FSM Transitions --- ----------------------- -- Start State. self:SetStartState( "Stopped" ) -- Add FSM transitions. -- From State --> Event --> To State self:AddTransition("Stopped", "Load", "Stopped") -- Load player scores from file. self:AddTransition("Stopped", "Start", "Idle") -- Start AIRBOSS script. self:AddTransition("*", "Idle", "Idle") -- Carrier is idling. self:AddTransition("Idle", "RecoveryStart", "Recovering") -- Start recovering aircraft. self:AddTransition("Recovering", "RecoveryStop", "Idle") -- Stop recovering aircraft. self:AddTransition("Recovering", "RecoveryPause", "Paused") -- Pause recovering aircraft. self:AddTransition("Paused", "RecoveryUnpause", "Recovering") -- Unpause recovering aircraft. self:AddTransition("*", "Status", "*") -- Update status of players and queues. self:AddTransition("*", "RecoveryCase", "*") -- Switch to another case recovery. self:AddTransition("*", "PassingWaypoint", "*") -- Carrier is passing a waypoint. self:AddTransition("*", "LSOGrade", "*") -- LSO grade. self:AddTransition("*", "Marshal", "*") -- A flight was send into the marshal stack. self:AddTransition("*", "Save", "*") -- Save player scores to file. self:AddTransition("*", "Stop", "Stopped") -- Stop AIRBOSS FMS. --- Triggers the FSM event "Start" that starts the airboss. Initializes parameters and starts event handlers. -- @function [parent=#AIRBOSS] Start -- @param #AIRBOSS self --- Triggers the FSM event "Start" that starts the airboss after a delay. Initializes parameters and starts event handlers. -- @function [parent=#AIRBOSS] __Start -- @param #AIRBOSS self -- @param #number delay Delay in seconds. --- On after "Start" user function. Called when the AIRBOSS FSM is started. -- @function [parent=#AIRBOSS] OnAfterStart -- @param #AIRBOSS self -- @param #string From From state. -- @param #string Event Event. -- @param #string To To state. --- Triggers the FSM event "Idle" that puts the carrier into state "Idle" where no recoveries are carried out. -- @function [parent=#AIRBOSS] Idle -- @param #AIRBOSS self --- Triggers the FSM delayed event "Idle" that puts the carrier into state "Idle" where no recoveries are carried out. -- @function [parent=#AIRBOSS] __Idle -- @param #AIRBOSS self -- @param #number delay Delay in seconds. --- Triggers the FSM event "RecoveryStart" that starts the recovery of aircraft. Marshalling aircraft are send to the landing pattern. -- @function [parent=#AIRBOSS] RecoveryStart -- @param #AIRBOSS self -- @param #number Case Recovery case (1, 2 or 3) that is started. -- @param #number Offset Holding pattern offset angle in degrees for CASE II/III recoveries. --- Triggers the FSM delayed event "RecoveryStart" that starts the recovery of aircraft. Marshalling aircraft are send to the landing pattern. -- @function [parent=#AIRBOSS] __RecoveryStart -- @param #AIRBOSS self -- @param #number delay Delay in seconds. -- @param #number Case Recovery case (1, 2 or 3) that is started. -- @param #number Offset Holding pattern offset angle in degrees for CASE II/III recoveries. --- On after "RecoveryStart" user function. Called when recovery of aircraft is started and carrier switches to state "Recovering". -- @function [parent=#AIRBOSS] OnAfterRecoveryStart -- @param #AIRBOSS self -- @param #string From From state. -- @param #string Event Event. -- @param #string To To state. -- @param #number Case The recovery case (1, 2 or 3) to start. -- @param #number Offset Holding pattern offset angle in degrees for CASE II/III recoveries. --- Triggers the FSM event "RecoveryStop" that stops the recovery of aircraft. -- @function [parent=#AIRBOSS] RecoveryStop -- @param #AIRBOSS self --- Triggers the FSM delayed event "RecoveryStop" that stops the recovery of aircraft. -- @function [parent=#AIRBOSS] __RecoveryStop -- @param #AIRBOSS self -- @param #number delay Delay in seconds. --- On after "RecoveryStop" user function. Called when recovery of aircraft is stopped. -- @function [parent=#AIRBOSS] OnAfterRecoveryStop -- @param #AIRBOSS self -- @param #string From From state. -- @param #string Event Event. -- @param #string To To state. --- Triggers the FSM event "RecoveryPause" that pauses the recovery of aircraft. -- @function [parent=#AIRBOSS] RecoveryPause -- @param #AIRBOSS self -- @param #number duration Duration of pause in seconds. After that recovery is automatically resumed. --- Triggers the FSM delayed event "RecoveryPause" that pauses the recovery of aircraft. -- @function [parent=#AIRBOSS] __RecoveryPause -- @param #AIRBOSS self -- @param #number delay Delay in seconds. -- @param #number duration Duration of pause in seconds. After that recovery is automatically resumed. --- Triggers the FSM event "RecoveryUnpause" that resumes the recovery of aircraft if it was paused. -- @function [parent=#AIRBOSS] RecoveryUnpause -- @param #AIRBOSS self --- Triggers the FSM delayed event "RecoveryUnpause" that resumes the recovery of aircraft if it was paused. -- @function [parent=#AIRBOSS] __RecoveryUnpause -- @param #AIRBOSS self -- @param #number delay Delay in seconds. --- Triggers the FSM event "RecoveryCase" that switches the aircraft recovery case. -- @function [parent=#AIRBOSS] RecoveryCase -- @param #AIRBOSS self -- @param #number Case The new recovery case (1, 2 or 3). -- @param #number Offset Holding pattern offset angle in degrees for CASE II/III recoveries. --- Triggers the delayed FSM event "RecoveryCase" that sets the used aircraft recovery case. -- @function [parent=#AIRBOSS] __RecoveryCase -- @param #AIRBOSS self -- @param #number delay Delay in seconds. -- @param #number Case The new recovery case (1, 2 or 3). -- @param #number Offset Holding pattern offset angle in degrees for CASE II/III recoveries. --- Triggers the FSM event "PassingWaypoint". Called when the carrier passes a waypoint. -- @function [parent=#AIRBOSS] PassingWaypoint -- @param #AIRBOSS self -- @param #number waypoint Number of waypoint. --- Triggers the FSM delayed event "PassingWaypoint". Called when the carrier passes a waypoint. -- @function [parent=#AIRBOSS] __PassingWaypoint -- @param #AIRBOSS self -- @param #number delay Delay in seconds. -- @param #number Case Recovery case (1, 2 or 3) that is started. -- @param #number Offset Holding pattern offset angle in degrees for CASE II/III recoveries. --- On after "PassingWaypoint" user function. Called when the carrier passes a waypoint of its route. -- @function [parent=#AIRBOSS] OnAfterPassingWaypoint -- @param #AIRBOSS self -- @param #string From From state. -- @param #string Event Event. -- @param #string To To state. -- @param #number waypoint Number of waypoint. --- Triggers the FSM event "Save" that saved the player scores to a file. -- @function [parent=#AIRBOSS] Save -- @param #AIRBOSS self -- @param #string path Path where the file is saved. Default is the DCS installation root directory or your "Saved Games\DCS" folder if lfs was desanitized. -- @param #string filename (Optional) File name. Default is AIRBOSS-*ALIAS*_LSOgrades.csv. --- Triggers the FSM delayed event "Save" that saved the player scores to a file. -- @function [parent=#AIRBOSS] __Save -- @param #AIRBOSS self -- @param #number delay Delay in seconds. -- @param #string path Path where the file is saved. Default is the DCS installation root directory or your "Saved Games\DCS" folder if lfs was desanitized. -- @param #string filename (Optional) File name. Default is AIRBOSS-*ALIAS*_LSOgrades.csv. --- On after "Save" event user function. Called when the player scores are saved to disk. -- @function [parent=#AIRBOSS] OnAfterSave -- @param #AIRBOSS self -- @param #string From From state. -- @param #string Event Event. -- @param #string To To state. -- @param #string path Path where the file is saved. Default is the DCS installation root directory or your "Saved Games\DCS" folder if lfs was desanitized. -- @param #string filename (Optional) File name. Default is AIRBOSS-*ALIAS*_LSOgrades.csv. --- Triggers the FSM event "Load" that loads the player scores from a file. AIRBOSS FSM must **not** be started at this point. -- @function [parent=#AIRBOSS] Load -- @param #AIRBOSS self -- @param #string path Path where the file is located. Default is the DCS installation root directory. -- @param #string filename (Optional) File name. Default is AIRBOSS-_LSOgrades.csv. --- Triggers the FSM delayed event "Load" that loads the player scores from a file. AIRBOSS FSM must **not** be started at this point. -- @function [parent=#AIRBOSS] __Load -- @param #AIRBOSS self -- @param #number delay Delay in seconds. -- @param #string path Path where the file is located. Default is the DCS installation root directory or your "Saved Games\DCS" folder if lfs was desanitized. -- @param #string filename (Optional) File name. Default is AIRBOSS-*ALIAS*_LSOgrades.csv. --- On after "Load" event user function. Called when the player scores are loaded from disk. -- @function [parent=#AIRBOSS] OnAfterLoad -- @param #AIRBOSS self -- @param #string From From state. -- @param #string Event Event. -- @param #string To To state. -- @param #string path Path where the file is located. Default is the DCS installation root directory or your "Saved Games\DCS" folder if lfs was desanitized. -- @param #string filename (Optional) File name. Default is AIRBOSS-*ALIAS*_LSOgrades.csv. --- Triggers the FSM event "LSOGrade". Called when the LSO grades a player -- @function [parent=#AIRBOSS] LSOGrade -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player Data. -- @param #AIRBOSS.LSOgrade grade LSO grade. --- Triggers the FSM event "LSOGrade". Delayed called when the LSO grades a player. -- @function [parent=#AIRBOSS] __LSOGrade -- @param #AIRBOSS self -- @param #number delay Delay in seconds. -- @param #AIRBOSS.PlayerData playerData Player Data. -- @param #AIRBOSS.LSOgrade grade LSO grade. --- On after "LSOGrade" user function. Called when the carrier passes a waypoint of its route. -- @function [parent=#AIRBOSS] OnAfterLSOGrade -- @param #AIRBOSS self -- @param #string From From state. -- @param #string Event Event. -- @param #string To To state. -- @param #AIRBOSS.PlayerData playerData Player Data. -- @param #AIRBOSS.LSOgrade grade LSO grade. --- Triggers the FSM event "Marshal". Called when a flight is send to the Marshal stack. -- @function [parent=#AIRBOSS] Marshal -- @param #AIRBOSS self -- @param #AIRBOSS.FlightGroup flight The flight group data. --- Triggers the FSM event "Marshal". Delayed call when a flight is send to the Marshal stack. -- @function [parent=#AIRBOSS] __Marshal -- @param #AIRBOSS self -- @param #number delay Delay in seconds. -- @param #AIRBOSS.FlightGroup flight The flight group data. --- On after "Marshal" user function. Called when a flight is send to the Marshal stack. -- @function [parent=#AIRBOSS] OnAfterMarshal -- @param #AIRBOSS self -- @param #string From From state. -- @param #string Event Event. -- @param #string To To state. -- @param #AIRBOSS.FlightGroup flight The flight group data. --- Triggers the FSM event "Stop" that stops the airboss. Event handlers are stopped. -- @function [parent=#AIRBOSS] Stop -- @param #AIRBOSS self --- Triggers the FSM event "Stop" that stops the airboss after a delay. Event handlers are stopped. -- @function [parent=#AIRBOSS] __Stop -- @param #AIRBOSS self -- @param #number delay Delay in seconds. return self end ------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- -- USER API Functions ------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- --- Set welcome messages for players. -- @param #AIRBOSS self -- @param #boolean Switch If true, display welcome message to player. -- @return #AIRBOSS self function AIRBOSS:SetWelcomePlayers( Switch ) self.welcome = Switch return self end --- Set carrier controlled area (CCA). -- This is a large zone around the carrier, which is constantly updated wrt the carrier position. -- @param #AIRBOSS self -- @param #number Radius Radius of zone in nautical miles (NM). Default 50 NM. -- @return #AIRBOSS self function AIRBOSS:SetCarrierControlledArea( Radius ) Radius = UTILS.NMToMeters( Radius or 50 ) self.zoneCCA = ZONE_UNIT:New( "Carrier Controlled Area", self.carrier, Radius ) return self end --- Set carrier controlled zone (CCZ). -- This is a small zone (usually 5 NM radius) around the carrier, which is constantly updated wrt the carrier position. -- @param #AIRBOSS self -- @param #number Radius Radius of zone in nautical miles (NM). Default 5 NM. -- @return #AIRBOSS self function AIRBOSS:SetCarrierControlledZone( Radius ) Radius = UTILS.NMToMeters( Radius or 5 ) self.zoneCCZ = ZONE_UNIT:New( "Carrier Controlled Zone", self.carrier, Radius ) return self end --- Set distance up to which water ahead is scanned for collisions. -- @param #AIRBOSS self -- @param #number Distance Distance in NM. Default 5 NM. -- @return #AIRBOSS self function AIRBOSS:SetCollisionDistance( Distance ) self.collisiondist = UTILS.NMToMeters( Distance or 5 ) return self end --- Set the default recovery case. -- @param #AIRBOSS self -- @param #number Case Case of recovery. Either 1, 2 or 3. Default 1. -- @return #AIRBOSS self function AIRBOSS:SetRecoveryCase( Case ) -- Set default case or 1. self.defaultcase = Case or 1 -- Current case init. self.case = self.defaultcase return self end --- Set holding pattern offset from final bearing for Case II/III recoveries. -- Usually, this is +-15 or +-30 degrees. You should not use and offset angle >= 90 degrees, because this will cause a devision by zero in some of the equations used to calculate the approach corridor. -- So best stick to the defaults up to 30 degrees. -- @param #AIRBOSS self -- @param #number Offset Offset angle in degrees. Default 0. -- @return #AIRBOSS self function AIRBOSS:SetHoldingOffsetAngle( Offset ) -- Set default angle or 0. self.defaultoffset = Offset or 0 -- Current offset init. self.holdingoffset = self.defaultoffset return self end --- Enable F10 menu to manually start recoveries. -- @param #AIRBOSS self -- @param #number Duration Default duration of the recovery in minutes. Default 30 min. -- @param #number WindOnDeck Default wind on deck in knots. Default 25 knots. -- @param #boolean Uturn U-turn after recovery window closes on=true or off=false/nil. Default off. -- @param #number Offset Relative Marshal radial in degrees for Case II/III recoveries. Default 30°. -- @return #AIRBOSS self function AIRBOSS:SetMenuRecovery( Duration, WindOnDeck, Uturn, Offset ) self.skipperMenu = true self.skipperTime = Duration or 30 self.skipperSpeed = WindOnDeck or 25 self.skipperOffset = Offset or 30 if Uturn then self.skipperUturn = true else self.skipperUturn = false end return self end --- Add aircraft recovery time window and recovery case. -- @param #AIRBOSS self -- @param #string starttime Start time, e.g. "8:00" for eight o'clock. Default now. -- @param #string stoptime Stop time, e.g. "9:00" for nine o'clock. Default 90 minutes after start time. -- @param #number case Recovery case for that time slot. Number between one and three. -- @param #number holdingoffset Only for CASE II/III: Angle in degrees the holding pattern is offset. -- @param #boolean turnintowind If true, carrier will turn into the wind 5 minutes before the recovery window opens. -- @param #number speed Speed in knots during turn into wind leg. -- @param #boolean uturn If true (or nil), carrier wil perform a U-turn and go back to where it came from before resuming its route to the next waypoint. If false, it will go directly to the next waypoint. -- @return #AIRBOSS.Recovery Recovery window. function AIRBOSS:AddRecoveryWindow( starttime, stoptime, case, holdingoffset, turnintowind, speed, uturn ) -- Absolute mission time in seconds. local Tnow = timer.getAbsTime() if starttime and type( starttime ) == "number" then starttime = UTILS.SecondsToClock( Tnow + starttime ) end if stoptime and type( stoptime ) == "number" then stoptime = UTILS.SecondsToClock( Tnow + stoptime ) end -- Input or now. starttime = starttime or UTILS.SecondsToClock( Tnow ) -- Set start time. local Tstart = UTILS.ClockToSeconds( starttime ) -- Set stop time. local Tstop = stoptime and UTILS.ClockToSeconds( stoptime ) or Tstart + 90 * 60 -- Consistancy check for timing. if Tstart > Tstop then self:E( string.format( "ERROR: Recovery stop time %s lies before recovery start time %s! Recovery window rejected.", UTILS.SecondsToClock( Tstart ), UTILS.SecondsToClock( Tstop ) ) ) return self end if Tstop <= Tnow then string.format( "WARNING: Recovery stop time %s already over. Tnow=%s! Recovery window rejected.", UTILS.SecondsToClock( Tstop ), UTILS.SecondsToClock( Tnow ) ) return self end -- Case or default value. case = case or self.defaultcase -- Holding offset or default value. holdingoffset = holdingoffset or self.defaultoffset -- Offset zero for case I. if case == 1 then holdingoffset = 0 end -- Increase counter. self.windowcount = self.windowcount + 1 -- Recovery window. local recovery = {} -- #AIRBOSS.Recovery recovery.START = Tstart recovery.STOP = Tstop recovery.CASE = case recovery.OFFSET = holdingoffset recovery.OPEN = false recovery.OVER = false recovery.WIND = turnintowind recovery.SPEED = speed or 20 recovery.ID = self.windowcount if uturn == nil or uturn == true then recovery.UTURN = true else recovery.UTURN = false end -- Add to table table.insert( self.recoverytimes, recovery ) return recovery end --- Define a set of AI groups that are handled by the airboss. -- @param #AIRBOSS self -- @param Core.Set#SET_GROUP SetGroup The set of AI groups which are handled by the airboss. -- @return #AIRBOSS self function AIRBOSS:SetSquadronAI( SetGroup ) self.squadsetAI = SetGroup return self end --- Define a set of AI groups that excluded from AI handling. Members of this set will be left allone by the airboss and not forced into the Marshal pattern. -- @param #AIRBOSS self -- @param Core.Set#SET_GROUP SetGroup The set of AI groups which are excluded. -- @return #AIRBOSS self function AIRBOSS:SetExcludeAI( SetGroup ) self.excludesetAI = SetGroup return self end --- Add a group to the exclude set. If no set exists, it is created. -- @param #AIRBOSS self -- @param Wrapper.Group#GROUP Group The group to be excluded. -- @return #AIRBOSS self function AIRBOSS:AddExcludeAI( Group ) self.excludesetAI = self.excludesetAI or SET_GROUP:New() self.excludesetAI:AddGroup( Group ) return self end --- Close currently running recovery window and stop recovery ops. Recovery window is deleted. -- @param #AIRBOSS self -- @param #number Delay (Optional) Delay in seconds before the window is deleted. function AIRBOSS:CloseCurrentRecoveryWindow( Delay ) if Delay and Delay > 0 then -- SCHEDULER:New(nil, self.CloseCurrentRecoveryWindow, {self}, delay) self:ScheduleOnce( Delay, self.CloseCurrentRecoveryWindow, self ) else if self:IsRecovering() and self.recoverywindow and self.recoverywindow.OPEN then self:RecoveryStop() self.recoverywindow.OPEN = false self.recoverywindow.OVER = true self:DeleteRecoveryWindow( self.recoverywindow ) end end end --- Delete all recovery windows. -- @param #AIRBOSS self -- @param #number Delay (Optional) Delay in seconds before the windows are deleted. -- @return #AIRBOSS self function AIRBOSS:DeleteAllRecoveryWindows( Delay ) -- Loop over all recovery windows. for _, recovery in pairs( self.recoverytimes ) do self:I( self.lid .. string.format( "Deleting recovery window ID %s", tostring( recovery.ID ) ) ) self:DeleteRecoveryWindow( recovery, Delay ) end return self end --- Return the recovery window of the given ID. -- @param #AIRBOSS self -- @param #number id The ID of the recovery window. -- @return #AIRBOSS.Recovery Recovery window with the right ID or nil if no such window exists. function AIRBOSS:GetRecoveryWindowByID( id ) if id then for _, _window in pairs( self.recoverytimes ) do local window = _window -- #AIRBOSS.Recovery if window and window.ID == id then return window end end end return nil end --- Delete a recovery window. If the window is currently open, it is closed and the recovery stopped. -- @param #AIRBOSS self -- @param #AIRBOSS.Recovery Window Recovery window. -- @param #number Delay Delay in seconds, before the window is deleted. function AIRBOSS:DeleteRecoveryWindow( Window, Delay ) if Delay and Delay > 0 then -- Delayed call. -- SCHEDULER:New(nil, self.DeleteRecoveryWindow, {self, window}, delay) self:ScheduleOnce( Delay, self.DeleteRecoveryWindow, self, Window ) else for i, _recovery in pairs( self.recoverytimes ) do local recovery = _recovery -- #AIRBOSS.Recovery if Window and Window.ID == recovery.ID then if Window.OPEN then -- Window is currently open. self:RecoveryStop() else table.remove( self.recoverytimes, i ) end end end end end --- Set time before carrier turns and recovery window opens. -- @param #AIRBOSS self -- @param #number Interval Time interval in seconds. Default 300 sec. -- @return #AIRBOSS self function AIRBOSS:SetRecoveryTurnTime( Interval ) self.dTturn = Interval or 300 return self end --- Set multiplayer environment wire correction. -- @param #AIRBOSS self -- @param #number Dcorr Correction distance in meters. Default 12 m. -- @return #AIRBOSS self function AIRBOSS:SetMPWireCorrection( Dcorr ) self.mpWireCorrection = Dcorr or 12 return self end --- Set time interval for updating queues and other stuff. -- @param #AIRBOSS self -- @param #number TimeInterval Time interval in seconds. Default 30 sec. -- @return #AIRBOSS self function AIRBOSS:SetQueueUpdateTime( TimeInterval ) self.dTqueue = TimeInterval or 30 return self end --- Set time interval between LSO calls. Optimal time in the groove is ~16 seconds. So the default of 4 seconds gives around 3-4 correction calls in the groove. -- @param #AIRBOSS self -- @param #number TimeInterval Time interval in seconds between LSO calls. Default 4 sec. -- @return #AIRBOSS self function AIRBOSS:SetLSOCallInterval( TimeInterval ) self.LSOdT = TimeInterval or 4 return self end --- Set if old into wind calculation is used when carrier turns into the wind for a recovery. -- @param #AIRBOSS self -- @param #boolean SwitchOn If `true` or `nil`, use old into wind calculation. -- @return #AIRBOSS self function AIRBOSS:SetIntoWindLegacy( SwitchOn ) if SwitchOn==nil then SwitchOn=true end self.intowindold=SwitchOn return self end --- Airboss is a rather nice guy and not strictly following the rules. Fore example, he does allow you into the landing pattern if you are not coming from the Marshal stack. -- @param #AIRBOSS self -- @param #boolean Switch If true or nil, Airboss bends the rules a bit. -- @return #AIRBOSS self function AIRBOSS:SetAirbossNiceGuy( Switch ) if Switch == true or Switch == nil then self.airbossnice = true else self.airbossnice = false end return self end --- Allow emergency landings, i.e. bypassing any pattern and go directly to final approach. -- @param #AIRBOSS self -- @param #boolean Switch If true or nil, emergency landings are okay. -- @return #AIRBOSS self function AIRBOSS:SetEmergencyLandings( Switch ) if Switch == true or Switch == nil then self.emergency = true else self.emergency = false end return self end --- Despawn AI groups after they they shut down their engines. -- @param #AIRBOSS self -- @param #boolean Switch If true or nil, AI groups are despawned. -- @return #AIRBOSS self function AIRBOSS:SetDespawnOnEngineShutdown( Switch ) if Switch == true or Switch == nil then self.despawnshutdown = true else self.despawnshutdown = false end return self end --- Respawn AI groups once they reach the CCA. Clears any attached airbases and allows making them land on the carrier via script. -- @param #AIRBOSS self -- @param #boolean Switch If true or nil, AI groups are respawned. -- @return #AIRBOSS self function AIRBOSS:SetRespawnAI( Switch ) if Switch == true or Switch == nil then self.respawnAI = true else self.respawnAI = false end return self end --- Give AI aircraft the refueling task if a recovery tanker is present or send them to the nearest divert airfield. -- @param #AIRBOSS self -- @param #number LowFuelThreshold Low fuel threshold in percent. AI will go refueling if their fuel level drops below this value. Default 10 %. -- @return #AIRBOSS self function AIRBOSS:SetRefuelAI( LowFuelThreshold ) self.lowfuelAI = LowFuelThreshold or 10 return self end --- Set max altitude to register flights in the initial zone. Aircraft above this altitude will not be registerered. -- @param #AIRBOSS self -- @param #number MaxAltitude Max altitude in feet. Default 1300 ft. -- @return #AIRBOSS self function AIRBOSS:SetInitialMaxAlt( MaxAltitude ) self.initialmaxalt = UTILS.FeetToMeters( MaxAltitude or 1300 ) return self end --- Set folder path where the airboss sound files are located **within you mission (miz) file**. -- The default path is "l10n/DEFAULT/" but sound files simply copied there will be removed by DCS the next time you save the mission. -- However, if you create a new folder inside the miz file, which contains the sounds, it will not be deleted and can be used. -- @param #AIRBOSS self -- @param #string FolderPath The path to the sound files, e.g. "Airboss Soundfiles/". -- @return #AIRBOSS self function AIRBOSS:SetSoundfilesFolder( FolderPath ) -- Check that it ends with / if FolderPath then local lastchar = string.sub( FolderPath, -1 ) if lastchar ~= "/" then FolderPath = FolderPath .. "/" end end -- Folderpath. self.soundfolder = FolderPath -- Info message. self:I( self.lid .. string.format( "Setting sound files folder to: %s", self.soundfolder ) ) return self end --- Set time interval for updating player status and other things. -- @param #AIRBOSS self -- @param #number TimeInterval Time interval in seconds. Default 0.5 sec. -- @return #AIRBOSS self function AIRBOSS:SetStatusUpdateTime( TimeInterval ) self.dTstatus = TimeInterval or 0.5 return self end --- Set duration how long messages are displayed to players. -- @param #AIRBOSS self -- @param #number Duration Duration in seconds. Default 10 sec. -- @return #AIRBOSS self function AIRBOSS:SetDefaultMessageDuration( Duration ) self.Tmessage = Duration or 10 return self end --- Set glideslope error thresholds. -- @param #AIRBOSS self -- @param #number _max -- @param #number _min -- @param #number High -- @param #number HIGH -- @param #number Low -- @param #number LOW -- @return #AIRBOSS self function AIRBOSS:SetGlideslopeErrorThresholds(_max,_min, High, HIGH, Low, LOW) --Check if V/STOL Carrier if self.carriertype == AIRBOSS.CarrierType.INVINCIBLE or self.carriertype == AIRBOSS.CarrierType.HERMES or self.carriertype == AIRBOSS.CarrierType.TARAWA or self.carriertype == AIRBOSS.CarrierType.AMERICA or self.carriertype == AIRBOSS.CarrierType.JCARLOS or self.carriertype == AIRBOSS.CarrierType.CANBERRA then -- allow a larger GSE for V/STOL operations --Pene Testing self.gle._max=_max or 0.7 self.gle.High=High or 1.4 self.gle.HIGH=HIGH or 1.9 self.gle._min=_min or -0.5 self.gle.Low=Low or -1.2 self.gle.LOW=LOW or -1.5 -- CVN values else self.gle._max=_max or 0.4 self.gle.High=High or 0.8 self.gle.HIGH=HIGH or 1.5 self.gle._min=_min or -0.3 self.gle.Low=Low or -0.6 self.gle.LOW=LOW or -0.9 end return self end --- Set lineup error thresholds. -- @param #AIRBOSS self -- @param #number _max -- @param #number _min -- @param #number Left -- @param #number LeftMed -- @param #number LEFT -- @param #number Right -- @param #number RightMed -- @param #number RIGHT -- @return #AIRBOSS self function AIRBOSS:SetLineupErrorThresholds(_max,_min, Left, LeftMed, LEFT, Right, RightMed, RIGHT) --Check if V/STOL Carrier -- Pene testing if self.carriertype == AIRBOSS.CarrierType.INVINCIBLE or self.carriertype == AIRBOSS.CarrierType.HERMES or self.carriertype == AIRBOSS.CarrierType.TARAWA or self.carriertype == AIRBOSS.CarrierType.AMERICA or self.carriertype == AIRBOSS.CarrierType.JCARLOS or self.carriertype == AIRBOSS.CarrierType.CANBERRA then -- V/STOL Values -- allow a larger LUE for V/STOL operations self.lue._max=_max or 1.8 self.lue._min=_min or -1.8 self.lue.Left=Left or -2.8 self.lue.LeftMed=LeftMed or -3.8 self.lue.LEFT=LEFT or -4.5 self.lue.Right=Right or 2.8 self.lue.RightMed=RightMed or 3.8 self.lue.RIGHT=RIGHT or 4.5 -- CVN Values else self.lue._max=_max or 0.5 self.lue._min=_min or -0.5 self.lue.Left=Left or -1.0 self.lue.LeftMed=LeftMed or -2.0 self.lue.LEFT=LEFT or -3.0 self.lue.Right=Right or 1.0 self.lue.RightMed=RightMed or 2.0 self.lue.RIGHT=RIGHT or 3.0 end return self end --- Set Case I Marshal radius. This is the radius of the valid zone around "the post" aircraft are supposed to be holding in the Case I Marshal stack. -- The post is 2.5 NM port of the carrier. -- @param #AIRBOSS self -- @param #number Radius Radius in NM. Default 2.8 NM, which gives a diameter of 5.6 NM. -- @return #AIRBOSS self function AIRBOSS:SetMarshalRadius( Radius ) self.marshalradius = UTILS.NMToMeters( Radius or 2.8 ) return self end --- Optimized F10 radio menu for a single carrier. The menu entries will be stored directly under F10 Other/Airboss/ and not F10 Other/Airboss/"Carrier Alias"/. -- **WARNING**: If you use this with two airboss objects/carriers, the radio menu will be screwed up! -- @param #AIRBOSS self -- @param #boolean Switch If true or nil single menu is enabled. If false, menu is for multiple carriers in the mission. -- @return #AIRBOSS self function AIRBOSS:SetMenuSingleCarrier( Switch ) if Switch == true or Switch == nil then self.menusingle = true else self.menusingle = false end return self end --- Enable or disable F10 radio menu for marking zones via smoke or flares. -- @param #AIRBOSS self -- @param #boolean Switch If true or nil, menu is enabled. If false, menu is not available to players. -- @return #AIRBOSS self function AIRBOSS:SetMenuMarkZones( Switch ) if Switch == nil or Switch == true then self.menumarkzones = true else self.menumarkzones = false end return self end --- Enable or disable F10 radio menu for marking zones via smoke. -- @param #AIRBOSS self -- @param #boolean Switch If true or nil, menu is enabled. If false, menu is not available to players. -- @return #AIRBOSS self function AIRBOSS:SetMenuSmokeZones( Switch ) if Switch == nil or Switch == true then self.menusmokezones = true else self.menusmokezones = false end return self end --- Enable saving of player's trap sheets and specify an optional directory path. -- @param #AIRBOSS self -- @param #string Path (Optional) Path where to save the trap sheets. -- @param #string Prefix (Optional) Prefix for trap sheet files. File name will be saved as *prefix_aircrafttype-0001.csv*, *prefix_aircrafttype-0002.csv*, etc. -- @return #AIRBOSS self function AIRBOSS:SetTrapSheet( Path, Prefix ) if io then self.trapsheet = true self.trappath = Path self.trapprefix = Prefix else self:E( self.lid .. "ERROR: io is not desanitized. Cannot save trap sheet." ) end return self end --- Specify weather the mission has set static or dynamic weather. -- @param #AIRBOSS self -- @param #boolean Switch If true or nil, mission uses static weather. If false, dynamic weather is used in this mission. -- @return #AIRBOSS self function AIRBOSS:SetStaticWeather( Switch ) if Switch == nil or Switch == true then self.staticweather = true else self.staticweather = false end return self end --- Disable automatic TACAN activation -- @param #AIRBOSS self -- @return #AIRBOSS self function AIRBOSS:SetTACANoff() self.TACANon = false return self end --- Set TACAN channel of carrier and switches TACAN on. -- @param #AIRBOSS self -- @param #number Channel (Optional) TACAN channel. Default 74. -- @param #string Mode (Optional) TACAN mode, i.e. "X" or "Y". Default "X". -- @param #string MorseCode (Optional) Morse code identifier. Three letters, e.g. "STN". Default "STN". -- @return #AIRBOSS self function AIRBOSS:SetTACAN( Channel, Mode, MorseCode ) self.TACANchannel = Channel or 74 self.TACANmode = Mode or "X" self.TACANmorse = MorseCode or "STN" self.TACANon = true return self end --- Disable automatic ICLS activation. -- @param #AIRBOSS self -- @return #AIRBOSS self function AIRBOSS:SetICLSoff() self.ICLSon = false return self end --- Set ICLS channel of carrier. -- @param #AIRBOSS self -- @param #number Channel (Optional) ICLS channel. Default 1. -- @param #string MorseCode (Optional) Morse code identifier. Three letters, e.g. "STN". Default "STN". -- @return #AIRBOSS self function AIRBOSS:SetICLS( Channel, MorseCode ) self.ICLSchannel = Channel or 1 self.ICLSmorse = MorseCode or "STN" self.ICLSon = true return self end --- Set beacon (TACAN/ICLS) time refresh interfal in case the beacons die. -- @param #AIRBOSS self -- @param #number TimeInterval (Optional) Time interval in seconds. Default 1200 sec = 20 min. -- @return #AIRBOSS self function AIRBOSS:SetBeaconRefresh( TimeInterval ) self.dTbeacon = TimeInterval or (20 * 60) return self end --- Set up SRS for usage without sound files -- @param #AIRBOSS self -- @param #string PathToSRS Path to SRS folder, e.g. "C:\\Program Files\\DCS-SimpleRadio-Standalone". -- @param #number Port Port of the SRS server, defaults to 5002. -- @param #string Culture (Optional, Airboss Culture) Culture, defaults to "en-US". -- @param #string Gender (Optional, Airboss Gender) Gender, e.g. "male" or "female". Defaults to "male". -- @param #string Voice (Optional, Airboss Voice) Set to use a specific voice. Will **override gender and culture** settings. -- @param #string GoogleCreds (Optional) Path to Google credentials, e.g. "C:\\Program Files\\DCS-SimpleRadio-Standalone\\yourgooglekey.json". -- @param #number Volume (Optional) E.g. 0.75. Defaults to 1.0 (loudest). -- @param #table AltBackend (Optional) See MSRS for details. -- @return #AIRBOSS self function AIRBOSS:EnableSRS(PathToSRS,Port,Culture,Gender,Voice,GoogleCreds,Volume,AltBackend) -- SRS local Frequency = self.AirbossRadio.frequency local Modulation = self.AirbossRadio.modulation self.SRS = MSRS:New(PathToSRS,Frequency,Modulation,AltBackend) self.SRS:SetCoalition(self:GetCoalition()) self.SRS:SetCoordinate(self:GetCoordinate()) self.SRS:SetCulture(Culture or "en-US") --self.SRS:SetFrequencies(Frequencies) self.SRS:SetGender(Gender or "male") self.SRS:SetPath(PathToSRS) self.SRS:SetPort(Port or 5002) self.SRS:SetLabel(self.AirbossRadio.alias or "AIRBOSS") self.SRS:SetCoordinate(self.carrier:GetCoordinate()) self.SRS:SetVolume(Volume or 1) --self.SRS:SetModulations(Modulations) if GoogleCreds then self.SRS:SetProviderOptionsGoogle(GoogleCreds,GoogleCreds) self.SRS:SetProvider(MSRS.Provider.GOOGLE) end if Voice then self.SRS:SetVoice(Voice) end self.SRS:SetVolume(Volume or 1.0) -- SRSQUEUE self.SRSQ = MSRSQUEUE:New("AIRBOSS") self.SRSQ:SetTransmitOnlyWithPlayers(true) if not self.PilotRadio then self:SetSRSPilotVoice() end return self end --- Set LSO radio frequency and modulation. Default frequency is 264 MHz AM. -- @param #AIRBOSS self -- @param #number Frequency (Optional) Frequency in MHz. Default 264 MHz. -- @param #string Modulation (Optional) Modulation, "AM" or "FM". Default "AM". -- @param #string Voice (Optional) SRS specific voice -- @param #string Gender (Optional) SRS specific gender -- @param #string Culture (Optional) SRS specific culture -- @return #AIRBOSS self function AIRBOSS:SetLSORadio( Frequency, Modulation, Voice, Gender, Culture ) self.LSOFreq = (Frequency or 264) Modulation = Modulation or "AM" if Modulation == "FM" then self.LSOModu = radio.modulation.FM else self.LSOModu = radio.modulation.AM end self.LSORadio = {} -- #AIRBOSS.Radio self.LSORadio.frequency = self.LSOFreq self.LSORadio.modulation = self.LSOModu self.LSORadio.alias = "LSO" self.LSORadio.voice = Voice self.LSORadio.gender = Gender or "male" self.LSORadio.culture = Culture or "en-US" return self end --- Set Airboss radio frequency and modulation. Default frequency is Tower frequency. -- @param #AIRBOSS self -- @param #number Frequency (Optional) Frequency in MHz. Default frequency is Tower frequency. -- @param #string Modulation (Optional) Modulation, "AM" or "FM". Default "AM". -- @param #string Voice (Optional) SRS specific voice -- @param #string Gender (Optional) SRS specific gender -- @param #string Culture (Optional) SRS specific culture -- @return #AIRBOSS self -- @usage -- -- Set single frequency -- myairboss:SetAirbossRadio(127.5,"AM",MSRS.Voices.Google.Standard.en_GB_Standard_F) -- -- -- Set multiple frequencies, note you **need** to pass one modulation per frequency given! -- myairboss:SetAirbossRadio({127.5,243},{radio.modulation.AM,radio.modulation.AM},MSRS.Voices.Google.Standard.en_GB_Standard_F) function AIRBOSS:SetAirbossRadio( Frequency, Modulation, Voice, Gender, Culture ) self.AirbossFreq = Frequency or self:_GetTowerFrequency() or 127.5 Modulation = Modulation or "AM" if type(Modulation) == "table" then self.AirbossModu = Modulation else if Modulation == "FM" then self.AirbossModu = radio.modulation.FM else self.AirbossModu = radio.modulation.AM end end self.AirbossRadio = {} -- #AIRBOSS.Radio self.AirbossRadio.frequency = self.AirbossFreq self.AirbossRadio.modulation = self.AirbossModu self.AirbossRadio.alias = "AIRBOSS" self.AirbossRadio.voice = Voice self.AirbossRadio.gender = Gender or "male" self.AirbossRadio.culture = Culture or "en-US" return self end --- Set Marshal radio frequency and modulation. Default frequency is 305 MHz AM. -- @param #AIRBOSS self -- @param #number Frequency (Optional) Frequency in MHz. Default 305 MHz. -- @param #string Modulation (Optional) Modulation, "AM" or "FM". Default "AM". -- @param #string Voice (Optional) SRS specific voice -- @param #string Gender (Optional) SRS specific gender -- @param #string Culture (Optional) SRS specific culture -- @return #AIRBOSS self function AIRBOSS:SetMarshalRadio( Frequency, Modulation, Voice, Gender, Culture ) self.MarshalFreq = Frequency or 305 Modulation = Modulation or "AM" if Modulation == "FM" then self.MarshalModu = radio.modulation.FM else self.MarshalModu = radio.modulation.AM end self.MarshalRadio = {} -- #AIRBOSS.Radio self.MarshalRadio.frequency = self.MarshalFreq self.MarshalRadio.modulation = self.MarshalModu self.MarshalRadio.alias = "MARSHAL" self.MarshalRadio.voice = Voice self.MarshalRadio.gender = Gender or "male" self.MarshalRadio.culture = Culture or "en-US" return self end --- Set unit name for sending radio messages. -- @param #AIRBOSS self -- @param #string unitname Name of the unit. -- @return #AIRBOSS self function AIRBOSS:SetRadioUnitName( unitname ) self.senderac = unitname return self end --- Set unit acting as radio relay for the LSO radio. -- @param #AIRBOSS self -- @param #string unitname Name of the unit. -- @return #AIRBOSS self function AIRBOSS:SetRadioRelayLSO( unitname ) self.radiorelayLSO = unitname return self end --- Set unit acting as radio relay for the Marshal radio. -- @param #AIRBOSS self -- @param #string unitname Name of the unit. -- @return #AIRBOSS self function AIRBOSS:SetRadioRelayMarshal( unitname ) self.radiorelayMSH = unitname return self end --- Use user sound output instead of radio transmission for messages. Might be handy if radio transmissions are broken. -- @param #AIRBOSS self -- @return #AIRBOSS self function AIRBOSS:SetUserSoundRadio() self.usersoundradio = true return self end --- Test LSO radio sounds. -- @param #AIRBOSS self -- @param #number delay Delay in seconds be sound check starts. -- @return #AIRBOSS self function AIRBOSS:SoundCheckLSO( delay ) if delay and delay > 0 then -- Delayed call. -- SCHEDULER:New(nil, AIRBOSS.SoundCheckLSO, {self}, delay) self:ScheduleOnce( delay, AIRBOSS.SoundCheckLSO, self ) else local text = "Playing LSO sound files:" for _name, _call in pairs( self.LSOCall ) do local call = _call -- #AIRBOSS.RadioCall -- Debug text. text = text .. string.format( "\nFile=%s.%s, duration=%.2f sec, loud=%s, subtitle=\"%s\".", call.file, call.suffix, call.duration, tostring( call.loud ), call.subtitle ) -- Radio transmission to queue. self:RadioTransmission( self.LSORadio, call, false ) -- Also play the loud version. if call.loud then self:RadioTransmission( self.LSORadio, call, true ) end end -- Debug message. self:T( self.lid .. text ) end end --- Test Marshal radio sounds. -- @param #AIRBOSS self -- @param #number delay Delay in seconds be sound check starts. -- @return #AIRBOSS self function AIRBOSS:SoundCheckMarshal( delay ) if delay and delay > 0 then -- Delayed call. -- SCHEDULER:New(nil, AIRBOSS.SoundCheckMarshal, {self}, delay) self:ScheduleOnce( delay, AIRBOSS.SoundCheckMarshal, self ) else local text = "Playing Marshal sound files:" for _name, _call in pairs( self.MarshalCall ) do local call = _call -- #AIRBOSS.RadioCall -- Debug text. text = text .. string.format( "\nFile=%s.%s, duration=%.2f sec, loud=%s, subtitle=\"%s\".", call.file, call.suffix, call.duration, tostring( call.loud ), call.subtitle ) -- Radio transmission to queue. self:RadioTransmission( self.MarshalRadio, call, false ) -- Also play the loud version. if call.loud then self:RadioTransmission( self.MarshalRadio, call, true ) end end -- Debug message. self:T( self.lid .. text ) end end --- Set number of aircraft units, which can be in the landing pattern before the pattern is full. -- @param #AIRBOSS self -- @param #number nmax Max number. Default 4. Minimum is 1, maximum is 6. -- @return #AIRBOSS self function AIRBOSS:SetMaxLandingPattern( nmax ) nmax = nmax or 4 nmax = math.max( nmax, 1 ) nmax = math.min( nmax, 6 ) self.Nmaxpattern = nmax return self end --- Set number available Case I Marshal stacks. If Marshal stacks are full, flights requesting Marshal will be told to hold outside 10 NM zone until a stack becomes available again. -- Marshal stacks for Case II/III are unlimited. -- @param #AIRBOSS self -- @param #number nmax Max number of stacks available to players and AI flights. Default 3, i.e. angels 2, 3, 4. Minimum is 1. -- @return #AIRBOSS self function AIRBOSS:SetMaxMarshalStacks( nmax ) self.Nmaxmarshal = nmax or 3 self.Nmaxmarshal = math.max( self.Nmaxmarshal, 1 ) return self end --- Set max number of section members. Minimum is one, i.e. the section lead itself. Maximum number is four. Default is two, i.e. the lead and one other human flight. -- @param #AIRBOSS self -- @param #number nmax Number of max allowed members including the lead itself. For example, Nmax=2 means a section lead plus one member. -- @return #AIRBOSS self function AIRBOSS:SetMaxSectionSize( nmax ) nmax = nmax or 2 nmax = math.max( nmax, 1 ) nmax = math.min( nmax, 4 ) self.NmaxSection = nmax - 1 -- We substract one because internally the section lead is not counted! return self end --- Set max number of flights per stack. All members of a section count as one "flight". -- @param #AIRBOSS self -- @param #number nmax Number of max allowed flights per stack. Default is two. Minimum is one, maximum is 4. -- @return #AIRBOSS self function AIRBOSS:SetMaxFlightsPerStack( nmax ) nmax = nmax or 2 nmax = math.max( nmax, 1 ) nmax = math.min( nmax, 4 ) self.NmaxStack = nmax return self end --- Handle AI aircraft. -- @param #AIRBOSS self -- @return #AIRBOSS self function AIRBOSS:SetHandleAION() self.handleai = true return self end --- Will play the inbound calls, commencing, initial, etc. from the player when requesteing marshal -- @param #AIRBOSS self -- @param #AIRBOSS status Boolean to activate (true) / deactivate (false) the radio inbound calls (default is ON) -- @return #AIRBOSS self function AIRBOSS:SetExtraVoiceOvers(status) self.xtVoiceOvers=status return self end --- Will simulate the inbound call, commencing, initial, etc from the AI when requested by Airboss -- @param #AIRBOSS self -- @param #AIRBOSS status Boolean to activate (true) / deactivate (false) the radio inbound calls (default is ON) -- @return #AIRBOSS self function AIRBOSS:SetExtraVoiceOversAI(status) self.xtVoiceOversAI=status return self end --- Do not handle AI aircraft. -- @param #AIRBOSS self -- @return #AIRBOSS self function AIRBOSS:SetHandleAIOFF() self.handleai = false return self end --- Define recovery tanker associated with the carrier. -- @param #AIRBOSS self -- @param Ops.RecoveryTanker#RECOVERYTANKER recoverytanker Recovery tanker object. -- @return #AIRBOSS self function AIRBOSS:SetRecoveryTanker( recoverytanker ) self.tanker = recoverytanker return self end --- Define an AWACS associated with the carrier. -- @param #AIRBOSS self -- @param Ops.RecoveryTanker#RECOVERYTANKER awacs AWACS (recovery tanker) object. -- @return #AIRBOSS self function AIRBOSS:SetAWACS( awacs ) self.awacs = awacs return self end --- Set default player skill. New players will be initialized with this skill. -- -- * "Flight Student" = @{#AIRBOSS.Difficulty.Easy} -- * "Naval Aviator" = @{#AIRBOSS.Difficulty.Normal} -- * "TOPGUN Graduate" = @{#AIRBOSS.Difficulty.Hard} -- @param #AIRBOSS self -- @param #string skill Player skill. Default "Naval Aviator". -- @return #AIRBOSS self function AIRBOSS:SetDefaultPlayerSkill( skill ) -- Set skill or normal. self.defaultskill = skill or AIRBOSS.Difficulty.NORMAL -- Check that defualt skill is valid. local gotit = false for _, _skill in pairs( AIRBOSS.Difficulty ) do if _skill == self.defaultskill then gotit = true end end -- If invalid user input, fall back to normal. if not gotit then self.defaultskill = AIRBOSS.Difficulty.NORMAL self:E( self.lid .. string.format( "ERROR: Invalid default skill = %s. Resetting to Naval Aviator.", tostring( skill ) ) ) end return self end --- Enable auto save of player results each time a player is *finally* graded. *Finally* means after the player landed on the carrier! After intermediate passes (bolter or waveoff) the stats are *not* saved. -- @param #AIRBOSS self -- @param #string path Path where to save the asset data file. Default is the DCS root installation directory or your "Saved Games\\DCS" folder if lfs was desanitized. -- @param #string filename File name. Default is generated automatically from airboss carrier name/alias. -- @return #AIRBOSS self function AIRBOSS:SetAutoSave( path, filename ) self.autosave = true self.autosavepath = path self.autosavefile = filename return self end --- Activate debug mode. Display debug messages on screen. -- @param #AIRBOSS self -- @return #AIRBOSS self function AIRBOSS:SetDebugModeON() self.Debug = true return self end --- Carrier patrols ad inifintum. If the last waypoint is reached, it will go to waypoint one and repeat its route. -- @param #AIRBOSS self -- @param #boolean switch If true or nil, patrol until the end of time. If false, go along the waypoints once and stop. -- @return #AIRBOSS self function AIRBOSS:SetPatrolAdInfinitum( switch ) if switch == false then self.adinfinitum = false else self.adinfinitum = true end return self end --- Set the magnetic declination (or variation). By default this is set to the standard declination of the map. -- @param #AIRBOSS self -- @param #number declination Declination in degrees or nil for default declination of the map. -- @return #AIRBOSS self function AIRBOSS:SetMagneticDeclination( declination ) self.magvar = declination or UTILS.GetMagneticDeclination() return self end --- Deactivate debug mode. This is also the default setting. -- @param #AIRBOSS self -- @return #AIRBOSS self function AIRBOSS:SetDebugModeOFF() self.Debug = false return self end --- Set FunkMan socket. LSO grades and trap sheets will be send to your Discord bot. -- **Requires running FunkMan program**. -- @param #AIRBOSS self -- @param #number Port Port. Default `10042`. -- @param #string Host Host. Default `"127.0.0.1"`. -- @return #AIRBOSS self function AIRBOSS:SetFunkManOn(Port, Host) self.funkmanSocket=SOCKET:New(Port, Host) return self end --- Get next time the carrier will start recovering aircraft. -- @param #AIRBOSS self -- @param #boolean InSeconds If true, abs. mission time seconds is returned. Default is a clock #string. -- @return #string Clock start (or start time in abs. seconds). -- @return #string Clock stop (or stop time in abs. seconds). function AIRBOSS:GetNextRecoveryTime( InSeconds ) if self.recoverywindow then if InSeconds then return self.recoverywindow.START, self.recoverywindow.STOP else return UTILS.SecondsToClock( self.recoverywindow.START ), UTILS.SecondsToClock( self.recoverywindow.STOP ) end else if InSeconds then return -1, -1 else return "?", "?" end end end --- Check if carrier is recovering aircraft. -- @param #AIRBOSS self -- @return #boolean If true, time slot for recovery is open. function AIRBOSS:IsRecovering() return self:is( "Recovering" ) end --- Check if carrier is idle, i.e. no operations are carried out. -- @param #AIRBOSS self -- @return #boolean If true, carrier is in idle state. function AIRBOSS:IsIdle() return self:is( "Idle" ) end --- Check if recovery of aircraft is paused. -- @param #AIRBOSS self -- @return #boolean If true, recovery is paused function AIRBOSS:IsPaused() return self:is( "Paused" ) end --- Activate TACAN and ICLS beacons. -- @param #AIRBOSS self function AIRBOSS:_ActivateBeacons() self:T( self.lid .. string.format( "Activating Beacons (TACAN=%s, ICLS=%s)", tostring( self.TACANon ), tostring( self.ICLSon ) ) ) -- Activate TACAN. if self.TACANon then self:I( self.lid .. string.format( "Activating TACAN Channel %d%s (%s)", self.TACANchannel, self.TACANmode, self.TACANmorse ) ) self.beacon:ActivateTACAN( self.TACANchannel, self.TACANmode, self.TACANmorse, true ) end -- Activate ICLS. if self.ICLSon then self:I( self.lid .. string.format( "Activating ICLS Channel %d (%s)", self.ICLSchannel, self.ICLSmorse ) ) self.beacon:ActivateICLS( self.ICLSchannel, self.ICLSmorse ) end -- Set time stamp. self.Tbeacon = timer.getTime() end ------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- -- FSM event functions ------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- --- On after Start event. Starts the AIRBOSS. Adds event handlers and schedules status updates of requests and queue. -- @param #AIRBOSS self -- @param #string From From state. -- @param #string Event Event. -- @param #string To To state. function AIRBOSS:onafterStart( From, Event, To ) -- Events are handled my MOOSE. self:I( self.lid .. string.format( "Starting AIRBOSS v%s for carrier unit %s of type %s on map %s", AIRBOSS.version, self.carrier:GetName(), self.carriertype, self.theatre ) ) -- Activate TACAN and ICLS if desired. self:_ActivateBeacons() -- Schedule radio queue checks. -- self.RQLid=self.radiotimer:Schedule(nil, AIRBOSS._CheckRadioQueue, {self, self.RQLSO, "LSO"}, 1, 0.1) -- self.RQMid=self.radiotimer:Schedule(nil, AIRBOSS._CheckRadioQueue, {self, self.RQMarshal, "MARSHAL"}, 1, 0.1) -- self:I("FF: starting timer.scheduleFunction") -- timer.scheduleFunction(AIRBOSS._CheckRadioQueueT, {airboss=self, radioqueue=self.RQLSO, name="LSO"}, timer.getTime()+1) -- timer.scheduleFunction(AIRBOSS._CheckRadioQueueT, {airboss=self, radioqueue=self.RQMarshal, name="MARSHAL"}, timer.getTime()+1) -- Initial carrier position and orientation. self.Cposition = self:GetCoordinate() self.Corientation = self.carrier:GetOrientationX() self.Corientlast = self.Corientation self.Tpupdate = timer.getTime() -- Check if no recovery window is set. DISABLED! if #self.recoverytimes == 0 and false then -- Open window in 15 minutes for 3 hours. local Topen = timer.getAbsTime() + 15 * 60 local Tclose = Topen + 3 * 60 * 60 -- Add window. self:AddRecoveryWindow( UTILS.SecondsToClock( Topen ), UTILS.SecondsToClock( Tclose ) ) end -- Check Recovery time.s self:_CheckRecoveryTimes() -- Time stamp for checking queues. We substract 60 seconds so the routine is called right after status is called the first time. self.Tqueue = timer.getTime() - 60 -- Handle events. self:HandleEvent( EVENTS.Birth ) self:HandleEvent( EVENTS.RunwayTouch ) self:HandleEvent( EVENTS.EngineShutdown ) self:HandleEvent( EVENTS.Takeoff ) self:HandleEvent( EVENTS.Crash ) self:HandleEvent( EVENTS.Ejection ) self:HandleEvent( EVENTS.PlayerLeaveUnit, self._PlayerLeft ) self:HandleEvent( EVENTS.MissionEnd ) self:HandleEvent( EVENTS.RemoveUnit ) self:HandleEvent( EVENTS.UnitLost, self.OnEventRemoveUnit ) -- self.StatusScheduler=SCHEDULER:New(self) -- self.StatusScheduler:Schedule(self, self._Status, {}, 1, 0.5) self.StatusTimer = TIMER:New( self._Status, self ):Start( 2, 0.5 ) -- Start status check in 1 second. self:__Status( 1 ) end --- On after Status event. Checks for new flights, updates queue and checks player status. -- @param #AIRBOSS self -- @param #string From From state. -- @param #string Event Event. -- @param #string To To state. function AIRBOSS:onafterStatus( From, Event, To ) -- Get current time. local time = timer.getTime() -- Update marshal and pattern queue every 30 seconds. if time - self.Tqueue > self.dTqueue then -- Get time. local clock = UTILS.SecondsToClock( timer.getAbsTime() ) local eta = UTILS.SecondsToClock( self:_GetETAatNextWP() ) -- Current heading and position of the carrier. local hdg = self:GetHeading() local pos = self:GetCoordinate() local speed = self.carrier:GetVelocityKNOTS() -- Update magnetic variation if we can get it from DCS. if require then self.magvar=pos:GetMagneticDeclination() --env.info(string.format("FF magvar=%.1f", self.magvar)) end -- Check water is ahead. local collision = false -- self:_CheckCollisionCoord(pos:Translate(self.collisiondist, hdg)) local holdtime = 0 if self.holdtimestamp then holdtime = timer.getTime() - self.holdtimestamp end -- Check if carrier is stationary. local NextWP = self:_GetNextWaypoint() local ExpectedSpeed = UTILS.MpsToKnots( NextWP:GetVelocity() ) if speed < 0.5 and ExpectedSpeed > 0 and not (self.detour or self.turnintowind) then if not self.holdtimestamp then self:E( self.lid .. string.format( "Carrier came to an unexpected standstill. Trying to re-route in 3 min. Speed=%.1f knots, expected=%.1f knots", speed, ExpectedSpeed ) ) self.holdtimestamp = timer.getTime() else if holdtime > 3 * 60 then local coord = self:GetCoordinate():Translate( 500, hdg + 10 ) -- coord:MarkToAll("Re-route after standstill.") self:CarrierResumeRoute( coord ) self.holdtimestamp = nil end end end -- Debug info. local text = string.format( "Time %s - Status %s (case=%d) - Speed=%.1f kts - Heading=%d - WP=%d - ETA=%s - Turning=%s - Collision Warning=%s - Detour=%s - Turn Into Wind=%s - Holdtime=%d sec", clock, self:GetState(), self.case, speed, hdg, self.currentwp, eta, tostring( self.turning ), tostring( collision ), tostring( self.detour ), tostring( self.turnintowind ), holdtime ) self:T( self.lid .. text ) -- Players online: text = "Players:" local i = 0 for _name, _player in pairs( self.players ) do i = i + 1 local player = _player -- #AIRBOSS.FlightGroup text = text .. string.format( "\n%d.) %s: Step=%s, Unit=%s, Airframe=%s", i, tostring( player.name ), tostring( player.step ), tostring( player.unitname ), tostring( player.actype ) ) end if i == 0 then text = text .. " none" end self:T( self.lid .. text ) -- Check for collision. if collision then -- We are currently turning into the wind. if self.turnintowind then -- Carrier resumes its initial route. This disables turnintowind switch. self:CarrierResumeRoute( self.Creturnto ) -- Since current window would stay open, we disable the WIND switch. if self:IsRecovering() and self.recoverywindow and self.recoverywindow.WIND then -- Disable turn into the wind for this window so that we do not do this all over again. self.recoverywindow.WIND = false end end end -- Check recovery times and start/stop recovery mode if necessary. self:_CheckRecoveryTimes() -- Remove dead/zombie flight groups. Player leaving the server whilst in pattern etc. -- self:_RemoveDeadFlightGroups() -- Scan carrier zone for new aircraft. self:_ScanCarrierZone() -- Check marshal and pattern queues. self:_CheckQueue() -- Check if carrier is currently turning. self:_CheckCarrierTurning() -- Check if marshal pattern of AI needs an update. self:_CheckPatternUpdate() -- Time stamp. self.Tqueue = time end -- (Re-)activate TACAN and ICLS channels. if time - self.Tbeacon > self.dTbeacon then self:_ActivateBeacons() end -- Call status every ~0.5 seconds. self:__Status( -30 ) end --- Check AI status. Pattern queue AI in the groove? Marshal queue AI arrived in holding zone? -- @param #AIRBOSS self function AIRBOSS:_Status() -- Check player status. self:_CheckPlayerStatus() -- Check AI landing pattern status self:_CheckAIStatus() end --- Check AI status. Pattern queue AI in the groove? Marshal queue AI arrived in holding zone? -- @param #AIRBOSS self function AIRBOSS:_CheckAIStatus() -- Loop over all flights in Marshal stack. for _, _flight in pairs( self.Qmarshal ) do local flight = _flight -- #AIRBOSS.FlightGroup -- Only AI! if flight.ai then -- Get fuel amount in %. local fuel = flight.group:GetFuelMin() * 100 -- Debug text. local text = string.format( "Group %s fuel=%.1f %%", flight.groupname, fuel ) self:T3( self.lid .. text ) -- Check if flight is low on fuel and not yet refueling. if self.lowfuelAI and fuel < self.lowfuelAI and not flight.refueling then -- Send AI for refueling at tanker or divert field. self:_RefuelAI( flight ) -- Remove flight from marshal queue. self:_RemoveFlightFromMarshalQueue( flight, true ) end end end -- Loop over all flights in landing pattern. for _, _flight in pairs( self.Qpattern ) do local flight = _flight -- #AIRBOSS.FlightGroup -- Only AI! if flight.ai then -- Loop over all units in AI flight. for _, _element in pairs( flight.elements ) do local element = _element -- #AIRBOSS.FlightElement -- Unit local unit = element.unit -- Get lineup and distance to carrier. local lineup = self:_Lineup( unit, true ) local unitcoord = unit:GetCoord() local dist = unitcoord:Get2DDistance( self:GetCoord() ) -- Distance in NM. local distance = UTILS.MetersToNM( dist ) -- Altitude in ft. local alt = UTILS.MetersToFeet( unitcoord.y ) -- Check if parameters are right and flight is in the groove. if lineup < 2 and distance <= 0.75 and alt < 500 and not element.ballcall then -- Paddles: Call the ball! self:RadioTransmission( self.LSORadio, self.LSOCall.CALLTHEBALL, nil, nil, nil, true ) -- Pilot: "405, Hornet Ball, 3.2" self:_LSOCallAircraftBall( element.onboard, self:_GetACNickname( unit:GetTypeName() ), self:_GetFuelState( unit ) / 1000 ) -- Paddles: Roger ball after 0.5 seconds. self:RadioTransmission( self.LSORadio, self.LSOCall.ROGERBALL, nil, nil, 0.5, true ) -- Flight element called the ball. element.ballcall = true -- This is for the whole flight. Maybe we need it. flight.ballcall = true end end end end end --- Check if player in the landing pattern is too close to another aircarft in the pattern. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData player Player data. function AIRBOSS:_CheckPlayerPatternDistance( player ) -- Check if player is too close to another aircraft in the pattern. -- TODO: At which steps is the really necessary. Case II/III? if player.step==AIRBOSS.PatternStep.INITIAL or player.step==AIRBOSS.PatternStep.BREAKENTRY or player.step==AIRBOSS.PatternStep.EARLYBREAK or player.step==AIRBOSS.PatternStep.LATEBREAK or player.step==AIRBOSS.PatternStep.ABEAM or player.step==AIRBOSS.PatternStep.GROOVE_XX or player.step==AIRBOSS.PatternStep.GROOVE_IM then -- Right step but not implemented. return else -- Wrong step - no check performed. return end -- Nothing to do since we check only in the pattern. if #self.Qpattern == 0 then return end --- Function that checks if unit1 is too close to unit2. local function _checkclose( _unit1, _unit2 ) local unit1 = _unit1 -- Wrapper.Unit#UNIT local unit2 = _unit2 -- Wrapper.Unit#UNIT if (not unit1) or (not unit2) then return false end -- Check that this is not the same unit. if unit1:GetName() == unit2:GetName() then return false end -- Return false when unit2 is not in air? Could be on the carrier. if not unit2:InAir() then return false end -- Positions of units. local c1 = unit1:GetCoordinate() local c2 = unit2:GetCoordinate() -- Vector from unit1 to unit2 local vec12 = { x = c2.x - c1.x, y = 0, z = c2.z - c1.z } -- DCS#Vec3 -- Distance between units. local dist = UTILS.VecNorm( vec12 ) -- Orientation of unit 1 in space. local vec1 = unit1:GetOrientationX() vec1.y = 0 -- Get angle between the two orientation vectors. Does the player aircraft nose point into the direction of the other aircraft? (Could be behind him!) local rhdg = math.deg( math.acos( UTILS.VecDot( vec12, vec1 ) / UTILS.VecNorm( vec12 ) / UTILS.VecNorm( vec1 ) ) ) -- Check altitude difference? local dalt = math.abs( c2.y - c1.y ) -- 650 feet ~= 200 meters distance between flights local dcrit = UTILS.FeetToMeters( 650 ) -- Direction in 30 degrees cone and distance < 200 meters and altitude difference <50 -- TODO: Test parameter values. if math.abs( rhdg ) < 10 and dist < dcrit and dalt < 50 then return true else return false end end -- Loop over all other flights in pattern. for _, _flight in pairs( self.Qpattern ) do local flight = _flight -- #AIRBOSS.FlightGroup -- Now we still need to loop over all units in the flight. for _, _element in pairs( flight.elements ) do local element = _element -- #AIRBOSS.FlightElement -- Check if player is too close to another aircraft in the pattern. local tooclose = _checkclose( player.unit, element.unit ) -- Check if we are too close. if tooclose then -- Debug message. local text = string.format( "Player %s too close (<200 meters) to aircraft %s!", player.name, element.unit:GetName() ) self:T2( self.lid .. text ) -- MESSAGE:New(text, 20, "DEBUG"):ToAllIf(self.Debug) -- Inform player that he is too close. -- TODO: Pattern wave off? -- TODO: This function needs a switch so that it is not called over and over again! -- local text=string.format("you're getting too close to the aircraft, %s, ahead of you!\nKeep a min distance of at least 650 ft.", element.onboard) -- self:MessageToPlayer(player, text, "LSO") end end end end --- Check recovery times and start/stop recovery mode of aircraft. -- @param #AIRBOSS self function AIRBOSS:_CheckRecoveryTimes() -- Get current abs time. local time = timer.getAbsTime() local Cnow = UTILS.SecondsToClock( time ) -- Debug output: local text = string.format( self.lid .. "Recovery time windows:" ) -- Handle case with no recoveries. if #self.recoverytimes == 0 then text = text .. " none!" end -- Sort windows wrt to start time. local _sort = function( a, b ) return a.START < b.START end table.sort( self.recoverytimes, _sort ) -- Next recovery case in the future. local nextwindow = nil -- #AIRBOSS.Recovery local currwindow = nil -- #AIRBOSS.Recovery -- Loop over all slots. for _, _recovery in pairs( self.recoverytimes ) do local recovery = _recovery -- #AIRBOSS.Recovery -- Get start/stop clock strings. local Cstart = UTILS.SecondsToClock( recovery.START ) local Cstop = UTILS.SecondsToClock( recovery.STOP ) -- Status info. local state = "" -- Check if start time passed. if time >= recovery.START then -- Start time has passed. if time < recovery.STOP then -- Stop time has NOT passed. if self:IsRecovering() then -- Carrier is already recovering. state = "in progress" else -- Start recovery. self:RecoveryStart( recovery.CASE, recovery.OFFSET ) state = "starting now" recovery.OPEN = true end -- Set current recovery window. currwindow = recovery else -- Stop time HAS passed. if self:IsRecovering() and not recovery.OVER then -- Get number of airborne aircraft units(!) currently in pattern. local _, npattern = self:_GetQueueInfo( self.Qpattern ) if npattern > 0 then -- Extend recovery time. 5 min per flight. local extmin = 5 * npattern recovery.STOP = recovery.STOP + extmin * 60 local text = string.format( "We still got flights in the pattern.\nRecovery time prolonged by %d minutes.\nNow get your act together and no more bolters!", extmin ) self:MessageToPattern( text, "AIRBOSS", "99", 10, false, nil ) else -- Set carrier to idle. self:RecoveryStop() state = "closing now" -- Closed. recovery.OPEN = false -- Window just closed. recovery.OVER = true end else -- Carrier is already idle. state = "closed" end end else -- This recovery is in the future. state = "in the future" -- This is the next to come as we sorted by start time. if nextwindow == nil then nextwindow = recovery state = "next in line" end end -- Debug text. text = text .. string.format( "\n- Start=%s Stop=%s Case=%d Offset=%d Open=%s Closed=%s Status=\"%s\"", Cstart, Cstop, recovery.CASE, recovery.OFFSET, tostring( recovery.OPEN ), tostring( recovery.OVER ), state ) end -- Debug output. self:T( self.lid .. text ) -- Current recovery window. self.recoverywindow = nil if self:IsIdle() then ----------------------------------------------------------------------------------------------------------------- -- Carrier is idle: We need to make sure that incoming flights get the correct recovery info of the next window. ----------------------------------------------------------------------------------------------------------------- -- Check if there is a next windows defined. if nextwindow then -- Set case and offset of the next window. self:RecoveryCase( nextwindow.CASE, nextwindow.OFFSET ) -- Check if time is less than 5 minutes. if nextwindow.WIND and nextwindow.START - time < self.dTturn and not self.turnintowind then -- Check that wind is blowing from a direction > 5° different from the current heading. local hdg = self:GetHeading() local wind = self:GetHeadingIntoWind(nextwindow.SPEED) local delta = self:_GetDeltaHeading( hdg, wind ) local uturn = delta > 5 -- Check if wind is actually blowing (0.1 m/s = 0.36 km/h = 0.2 knots) local _, vwind = self:GetWind() if vwind < 0.1 then uturn = false end -- U-turn disabled by user input. if not nextwindow.UTURN then uturn = false end -- Debug info self:T( self.lid .. string.format( "Heading=%03d°, Wind=%03d° %.1f kts, Delta=%03d° ==> U-turn=%s", hdg, wind, UTILS.MpsToKnots( vwind ), delta, tostring( uturn ) ) ) -- Time into the wind 1 day or if longer recovery time + the 5 min early. local t = math.max( nextwindow.STOP - nextwindow.START + self.dTturn, 60 * 60 * 24 ) -- Recovery wind on deck in knots. local v = UTILS.KnotsToMps( nextwindow.SPEED ) -- Check that we do not go above max possible speed. local vmax = self.carrier:GetSpeedMax() / 3.6 -- convert to m/s v = math.min( v, vmax ) -- Route carrier into the wind. Sets self.turnintowind=true self:CarrierTurnIntoWind( t, v, uturn ) end -- Set current recovery window. self.recoverywindow = nextwindow else -- No next window. Set default values. self:RecoveryCase() end else ------------------------------------------------------------------------------------- -- Carrier is recovering: We set the recovery window to the current one or next one. ------------------------------------------------------------------------------------- if currwindow then self.recoverywindow = currwindow else self.recoverywindow = nextwindow end end self:T2( { "FF", recoverywindow = self.recoverywindow } ) end --- Get section lead of a flight. -- @param #AIRBOSS self -- @param #AIRBOSS.FlightGroup flight -- @return #AIRBOSS.FlightGroup The leader of the section. Could be the flight itself. -- @return #boolean If true, flight is lead. function AIRBOSS:_GetFlightLead( flight ) if flight.name ~= flight.seclead then -- Section lead of flight. local lead = self.players[flight.seclead] return lead, false else -- Flight without section or section lead. return flight, true end end --- On before "RecoveryCase" event. Check if case or holding offset did change. If not transition is denied. -- @param #AIRBOSS self -- @param #string From From state. -- @param #string Event Event. -- @param #string To To state. -- @param #number Case The recovery case (1, 2 or 3) to switch to. -- @param #number Offset Holding pattern offset angle in degrees for CASE II/III recoveries. function AIRBOSS:onbeforeRecoveryCase( From, Event, To, Case, Offset ) -- Input or default value. Case = Case or self.defaultcase -- Input or default value Offset = Offset or self.defaultoffset if Case == self.case and Offset == self.holdingoffset then return false end return true end --- On after "RecoveryCase" event. Sets new aircraft recovery case. Updates -- @param #AIRBOSS self -- @param #string From From state. -- @param #string Event Event. -- @param #string To To state. -- @param #number Case The recovery case (1, 2 or 3) to switch to. -- @param #number Offset Holding pattern offset angle in degrees for CASE II/III recoveries. function AIRBOSS:onafterRecoveryCase( From, Event, To, Case, Offset ) -- Input or default value. Case = Case or self.defaultcase -- Input or default value Offset = Offset or self.defaultoffset -- Debug output. local text = string.format( "Switching recovery case %d ==> %d", self.case, Case ) if Case > 1 then text = text .. string.format( " Holding offset angle %d degrees.", Offset ) end MESSAGE:New( text, 20, self.alias ):ToAllIf( self.Debug ) self:T( self.lid .. text ) -- Set new recovery case. self.case = Case -- Set holding offset. self.holdingoffset = Offset -- Update case of all flights not in Marshal or Pattern queue. for _, _flight in pairs( self.flights ) do local flight = _flight -- #AIRBOSS.FlightGroup if not (self:_InQueue( self.Qmarshal, flight.group ) or self:_InQueue( self.Qpattern, flight.group )) then -- Also not for section members. These are not in the marshal or pattern queue if the lead is. if flight.name ~= flight.seclead then local lead = self.players[flight.seclead] if lead and not (self:_InQueue( self.Qmarshal, lead.group ) or self:_InQueue( self.Qpattern, lead.group )) then -- This is section member and the lead is not in the Marshal or Pattern queue. flight.case = self.case end else -- This is a flight without section or the section lead. flight.case = self.case end end end end --- On after "RecoveryStart" event. Recovery of aircraft is started and carrier switches to state "Recovering". -- @param #AIRBOSS self -- @param #string From From state. -- @param #string Event Event. -- @param #string To To state. -- @param #number Case The recovery case (1, 2 or 3) to start. -- @param #number Offset Holding pattern offset angle in degrees for CASE II/III recoveries. function AIRBOSS:onafterRecoveryStart( From, Event, To, Case, Offset ) -- Input or default value. Case = Case or self.defaultcase -- Input or default value. Offset = Offset or self.defaultoffset -- Radio message: "99, starting aircraft recovery case X ops. (Marshal radial XYZ degrees)" self:_MarshalCallRecoveryStart( Case ) -- Switch to case. self:RecoveryCase( Case, Offset ) end --- On after "RecoveryStop" event. Recovery of aircraft is stopped and carrier switches to state "Idle". Running recovery window is deleted. -- @param #AIRBOSS self -- @param #string From From state. -- @param #string Event Event. -- @param #string To To state. function AIRBOSS:onafterRecoveryStop( From, Event, To ) -- Debug output. self:T( self.lid .. string.format( "Stopping aircraft recovery." ) ) -- Recovery ops stopped message. self:_MarshalCallRecoveryStopped( self.case ) -- If carrier is currently heading into the wind, we resume the original route. if self.turnintowind then -- Coordinate to return to. local coord = self.Creturnto -- No U-turn. if self.recoverywindow and self.recoverywindow.UTURN == false then coord = nil end -- Carrier resumes route. self:CarrierResumeRoute( coord ) end -- Delete current recovery window if open. if self.recoverywindow and self.recoverywindow.OPEN == true then self.recoverywindow.OPEN = false self.recoverywindow.OVER = true self:DeleteRecoveryWindow( self.recoverywindow ) end -- Check recovery windows. This sets self.recoverywindow to the next window. self:_CheckRecoveryTimes() end --- On after "RecoveryPause" event. Recovery of aircraft is paused. Marshal queue stays intact. -- @param #AIRBOSS self -- @param #string From From state. -- @param #string Event Event. -- @param #string To To state. -- @param #number duration Duration of pause in seconds. After that recovery is resumed automatically. function AIRBOSS:onafterRecoveryPause( From, Event, To, duration ) -- Debug output. self:T( self.lid .. string.format( "Pausing aircraft recovery." ) ) -- Message text if duration then -- Auto resume. self:__RecoveryUnpause( duration ) -- Time to resume. local clock = UTILS.SecondsToClock( timer.getAbsTime() + duration ) -- Marshal call: "99, aircraft recovery paused and will be resume at XX:YY." self:_MarshalCallRecoveryPausedResumedAt( clock ) else local text = string.format( "aircraft recovery is paused until further notice." ) -- Marshal call: "99, aircraft recovery paused until further notice." self:_MarshalCallRecoveryPausedNotice() end end --- On after "RecoveryUnpause" event. Recovery of aircraft is resumed. -- @param #AIRBOSS self -- @param #string From From state. -- @param #string Event Event. -- @param #string To To state. function AIRBOSS:onafterRecoveryUnpause( From, Event, To ) -- Debug output. self:T( self.lid .. string.format( "Unpausing aircraft recovery." ) ) -- Resume recovery. self:_MarshalCallResumeRecovery() end --- On after "PassingWaypoint" event. Carrier has just passed a waypoint -- @param #AIRBOSS self -- @param #string From From state. -- @param #string Event Event. -- @param #string To To state. -- @param #number n Number of waypoint that was passed. function AIRBOSS:onafterPassingWaypoint( From, Event, To, n ) -- Debug output. self:I( self.lid .. string.format( "Carrier passed waypoint %d.", n ) ) end --- On after "Idle" event. Carrier goes to state "Idle". -- @param #AIRBOSS self -- @param #string From From state. -- @param #string Event Event. -- @param #string To To state. function AIRBOSS:onafterIdle( From, Event, To ) -- Debug output. self:T( self.lid .. string.format( "Carrier goes to idle." ) ) end --- On after Stop event. Unhandle events. -- @param #AIRBOSS self -- @param #string From From state. -- @param #string Event Event. -- @param #string To To state. function AIRBOSS:onafterStop( From, Event, To ) self:I( self.lid .. string.format( "Stopping airboss script." ) ) -- Unhandle events. self:UnHandleEvent( EVENTS.Birth ) self:UnHandleEvent( EVENTS.RunwayTouch ) self:UnHandleEvent( EVENTS.EngineShutdown ) self:UnHandleEvent( EVENTS.Takeoff ) self:UnHandleEvent( EVENTS.Crash ) self:UnHandleEvent( EVENTS.Ejection ) self:UnHandleEvent( EVENTS.PlayerLeaveUnit ) self:UnHandleEvent( EVENTS.MissionEnd ) self.CallScheduler:Clear() end ---------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- -- Parameter initialization ---------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- --- Init parameters for USS Stennis carrier. -- @param #AIRBOSS self function AIRBOSS:_InitStennis() -- Carrier Parameters. self.carrierparam.sterndist = -153 self.carrierparam.deckheight = 18.30 -- Total size of the carrier (approx as rectangle). self.carrierparam.totlength = 310 -- Wiki says 332.8 meters overall length. self.carrierparam.totwidthport = 40 -- Wiki says 76.8 meters overall beam. self.carrierparam.totwidthstarboard = 30 -- Landing runway. self.carrierparam.rwyangle = -9.1359 self.carrierparam.rwylength = 225 self.carrierparam.rwywidth = 20 -- Wires. self.carrierparam.wire1 = 46 -- Distance from stern to first wire. self.carrierparam.wire2 = 46 + 12 self.carrierparam.wire3 = 46 + 24 self.carrierparam.wire4 = 46 + 35 -- Last wire is strangely one meter closer. -- Landing distance. self.carrierparam.landingdist = self.carrierparam.sterndist+self.carrierparam.wire3 -- Platform at 5k. Reduce descent rate to 2000 ft/min to 1200 dirty up level flight. self.Platform.name = "Platform 5k" self.Platform.Xmin = -UTILS.NMToMeters( 22 ) -- Not more than 22 NM behind the boat. Last check was at 21 NM. self.Platform.Xmax = nil self.Platform.Zmin = -UTILS.NMToMeters( 30 ) -- Not more than 30 NM port of boat. self.Platform.Zmax = UTILS.NMToMeters( 30 ) -- Not more than 30 NM starboard of boat. self.Platform.LimitXmin = nil -- Limits via zone self.Platform.LimitXmax = nil self.Platform.LimitZmin = nil self.Platform.LimitZmax = nil -- Level out at 1200 ft and dirty up. self.DirtyUp.name = "Dirty Up" self.DirtyUp.Xmin = -UTILS.NMToMeters( 21 ) -- Not more than 21 NM behind the boat. self.DirtyUp.Xmax = nil self.DirtyUp.Zmin = -UTILS.NMToMeters( 30 ) -- Not more than 30 NM port of boat. self.DirtyUp.Zmax = UTILS.NMToMeters( 30 ) -- Not more than 30 NM starboard of boat. self.DirtyUp.LimitXmin = nil -- Limits via zone self.DirtyUp.LimitXmax = nil self.DirtyUp.LimitZmin = nil self.DirtyUp.LimitZmax = nil -- Intercept glide slope and follow bullseye. self.Bullseye.name = "Bullseye" self.Bullseye.Xmin = -UTILS.NMToMeters( 11 ) -- Not more than 11 NM behind the boat. Last check was at 10 NM. self.Bullseye.Xmax = nil self.Bullseye.Zmin = -UTILS.NMToMeters( 30 ) -- Not more than 30 NM port. self.Bullseye.Zmax = UTILS.NMToMeters( 30 ) -- Not more than 30 NM starboard. self.Bullseye.LimitXmin = nil -- Limits via zone. self.Bullseye.LimitXmax = nil self.Bullseye.LimitZmin = nil self.Bullseye.LimitZmax = nil -- Break entry. self.BreakEntry.name = "Break Entry" self.BreakEntry.Xmin = -UTILS.NMToMeters( 4 ) -- Not more than 4 NM behind the boat. Check for initial is at 3 NM with a radius of 500 m and 100 m starboard. self.BreakEntry.Xmax = nil self.BreakEntry.Zmin = -UTILS.NMToMeters( 0.5 ) -- Not more than 0.5 NM port of boat. self.BreakEntry.Zmax = UTILS.NMToMeters( 1.5 ) -- Not more than 1.5 NM starboard. self.BreakEntry.LimitXmin = 0 -- Check and next step when at carrier and starboard of carrier. self.BreakEntry.LimitXmax = nil self.BreakEntry.LimitZmin = nil self.BreakEntry.LimitZmax = nil -- Early break. self.BreakEarly.name = "Early Break" self.BreakEarly.Xmin = -UTILS.NMToMeters( 1 ) -- Not more than 1 NM behind the boat. Last check was at 0. self.BreakEarly.Xmax = UTILS.NMToMeters( 5 ) -- Not more than 5 NM in front of the boat. Enough for late breaks? self.BreakEarly.Zmin = -UTILS.NMToMeters( 2 ) -- Not more than 2 NM port. self.BreakEarly.Zmax = UTILS.NMToMeters( 1 ) -- Not more than 1 NM starboard. self.BreakEarly.LimitXmin = 0 -- Check and next step 0.2 NM port and in front of boat. self.BreakEarly.LimitXmax = nil self.BreakEarly.LimitZmin = -UTILS.NMToMeters( 0.2 ) -- -370 m port self.BreakEarly.LimitZmax = nil -- Late break. self.BreakLate.name = "Late Break" self.BreakLate.Xmin = -UTILS.NMToMeters( 1 ) -- Not more than 1 NM behind the boat. Last check was at 0. self.BreakLate.Xmax = UTILS.NMToMeters( 5 ) -- Not more than 5 NM in front of the boat. Enough for late breaks? self.BreakLate.Zmin = -UTILS.NMToMeters( 2 ) -- Not more than 2 NM port. self.BreakLate.Zmax = UTILS.NMToMeters( 1 ) -- Not more than 1 NM starboard. self.BreakLate.LimitXmin = 0 -- Check and next step 0.8 NM port and in front of boat. self.BreakLate.LimitXmax = nil self.BreakLate.LimitZmin = -UTILS.NMToMeters( 0.8 ) -- -1470 m port self.BreakLate.LimitZmax = nil -- Abeam position. self.Abeam.name = "Abeam Position" self.Abeam.Xmin = -UTILS.NMToMeters( 5 ) -- Not more then 5 NM astern of boat. Should be LIG call anyway. self.Abeam.Xmax = UTILS.NMToMeters( 5 ) -- Not more then 5 NM ahead of boat. self.Abeam.Zmin = -UTILS.NMToMeters( 2 ) -- Not more than 2 NM port. self.Abeam.Zmax = 500 -- Not more than 500 m starboard. Must be port! self.Abeam.LimitXmin = -200 -- Check and next step 200 meters behind the ship. self.Abeam.LimitXmax = nil self.Abeam.LimitZmin = nil self.Abeam.LimitZmax = nil -- At the Ninety. self.Ninety.name = "Ninety" self.Ninety.Xmin = -UTILS.NMToMeters( 4 ) -- Not more than 4 NM behind the boat. LIG check anyway. self.Ninety.Xmax = 0 -- Must be behind the boat. self.Ninety.Zmin = -UTILS.NMToMeters( 2 ) -- Not more than 2 NM port of boat. self.Ninety.Zmax = nil self.Ninety.LimitXmin = nil self.Ninety.LimitXmax = nil self.Ninety.LimitZmin = nil self.Ninety.LimitZmax = -UTILS.NMToMeters( 0.6 ) -- Check and next step when 0.6 NM port. -- At the Wake. self.Wake.name = "Wake" self.Wake.Xmin = -UTILS.NMToMeters( 4 ) -- Not more than 4 NM behind the boat. self.Wake.Xmax = 0 -- Must be behind the boat. self.Wake.Zmin = -2000 -- Not more than 2 km port of boat. self.Wake.Zmax = nil self.Wake.LimitXmin = nil self.Wake.LimitXmax = nil self.Wake.LimitZmin = 0 -- Check and next step when directly behind the boat. self.Wake.LimitZmax = nil -- Turn to final. self.Final.name = "Final" self.Final.Xmin = -UTILS.NMToMeters( 4 ) -- Not more than 4 NM behind the boat. self.Final.Xmax = 0 -- Must be behind the boat. self.Final.Zmin = -2000 -- Not more than 2 km port. self.Final.Zmax = nil self.Final.LimitXmin = nil -- No limits. Check is carried out differently. self.Final.LimitXmax = nil self.Final.LimitZmin = nil self.Final.LimitZmax = nil -- In the Groove. self.Groove.name = "Groove" self.Groove.Xmin = -UTILS.NMToMeters( 4 ) -- Not more than 4 NM behind the boat. self.Groove.Xmax = nil self.Groove.Zmin = -UTILS.NMToMeters( 2 ) -- Not more than 2 NM port self.Groove.Zmax = UTILS.NMToMeters( 2 ) -- Not more than 2 NM starboard. self.Groove.LimitXmin = nil -- No limits. Check is carried out differently. self.Groove.LimitXmax = nil self.Groove.LimitZmin = nil self.Groove.LimitZmax = nil end --- Init parameters for Nimitz class super carriers. -- @param #AIRBOSS self function AIRBOSS:_InitNimitz() -- Init Stennis as default. self:_InitStennis() -- Carrier Parameters. self.carrierparam.sterndist = -164 self.carrierparam.deckheight = 20.1494 -- DCS World OpenBeta\CoreMods\tech\USS_Nimitz\Database\USS_CVN_7X.lua -- Total size of the carrier (approx as rectangle). self.carrierparam.totlength = 332.8 -- Wiki says 332.8 meters overall length. self.carrierparam.totwidthport = 45 -- Wiki says 76.8 meters overall beam. self.carrierparam.totwidthstarboard = 35 -- Landing runway. self.carrierparam.rwyangle = -9.1359 -- DCS World OpenBeta\CoreMods\tech\USS_Nimitz\scripts\USS_Nimitz_RunwaysAndRoutes.lua self.carrierparam.rwylength = 250 self.carrierparam.rwywidth = 25 -- Wires. self.carrierparam.wire1 = 55 -- Distance from stern to first wire. self.carrierparam.wire2 = 67 self.carrierparam.wire3 = 79 self.carrierparam.wire4 = 92 -- Landing distance. self.carrierparam.landingdist = self.carrierparam.sterndist+self.carrierparam.wire3 end --- Init parameters for Forrestal class super carriers. -- @param #AIRBOSS self function AIRBOSS:_InitForrestal() -- Init Nimitz as default. self:_InitNimitz() -- Carrier Parameters. self.carrierparam.sterndist = -135.5 self.carrierparam.deckheight = 20 -- 20.1494 --DCS World OpenBeta\CoreMods\tech\USS_Nimitz\Database\USS_CVN_7X.lua -- Total size of the carrier (approx as rectangle). self.carrierparam.totlength = 315 -- Wiki says 325 meters overall length. self.carrierparam.totwidthport = 45 -- Wiki says 73 meters overall beam. self.carrierparam.totwidthstarboard = 35 -- Landing runway. self.carrierparam.rwyangle = -9.1359 -- DCS World OpenBeta\CoreMods\tech\USS_Nimitz\scripts\USS_Nimitz_RunwaysAndRoutes.lua self.carrierparam.rwylength = 212 self.carrierparam.rwywidth = 25 -- Wires. self.carrierparam.wire1 = 44 -- Distance from stern to first wire. Original from Frank - 42 self.carrierparam.wire2 = 54 -- 51.5 self.carrierparam.wire3 = 64 -- 62 self.carrierparam.wire4 = 74 -- 72.5 -- Landing distance. self.carrierparam.landingdist = self.carrierparam.sterndist+self.carrierparam.wire3 end --- Init parameters for R12 HMS Hermes carrier. -- @param #AIRBOSS self function AIRBOSS:_InitHermes() -- Init Stennis as default. self:_InitStennis() -- Carrier Parameters. self.carrierparam.sterndist = -105 self.carrierparam.deckheight = 12 -- From model viewer WL0. -- Total size of the carrier (approx as rectangle). self.carrierparam.totlength = 228.19 self.carrierparam.totwidthport = 20.5 self.carrierparam.totwidthstarboard = 24.5 -- Landing runway. self.carrierparam.rwyangle = 0 self.carrierparam.rwylength = 215 self.carrierparam.rwywidth = 13 -- Wires. self.carrierparam.wire1 = nil self.carrierparam.wire2 = nil self.carrierparam.wire3 = nil self.carrierparam.wire4 = nil -- Distance to landing spot. self.carrierparam.landingspot=69 -- Landing distance. self.carrierparam.landingdist = self.carrierparam.sterndist+self.carrierparam.landingspot -- Late break. self.BreakLate.name = "Late Break" self.BreakLate.Xmin = -UTILS.NMToMeters( 1 ) -- Not more than 1 NM behind the boat. Last check was at 0. self.BreakLate.Xmax = UTILS.NMToMeters( 5 ) -- Not more than 5 NM in front of the boat. Enough for late breaks? self.BreakLate.Zmin = -UTILS.NMToMeters( 1.6 ) -- Not more than 1.6 NM port. self.BreakLate.Zmax = UTILS.NMToMeters( 1 ) -- Not more than 1 NM starboard. self.BreakLate.LimitXmin = 0 -- Check and next step 0.8 NM port and in front of boat. self.BreakLate.LimitXmax = nil self.BreakLate.LimitZmin = -UTILS.NMToMeters( 0.5 ) -- 926 m port, closer than the stennis as abeam is 0.8-1.0 rather than 1.2 self.BreakLate.LimitZmax = nil end --- Init parameters for R05 HMS Invincible carrier. -- @param #AIRBOSS self function AIRBOSS:_InitInvincible() -- Init Stennis as default. self:_InitStennis() -- Carrier Parameters. self.carrierparam.sterndist = -105 self.carrierparam.deckheight = 12 -- From model viewer WL0. -- Total size of the carrier (approx as rectangle). self.carrierparam.totlength = 228.19 self.carrierparam.totwidthport = 20.5 self.carrierparam.totwidthstarboard = 24.5 -- Landing runway. self.carrierparam.rwyangle = 0 self.carrierparam.rwylength = 215 self.carrierparam.rwywidth = 13 -- Wires. self.carrierparam.wire1 = nil self.carrierparam.wire2 = nil self.carrierparam.wire3 = nil self.carrierparam.wire4 = nil -- Distance to landing spot. self.carrierparam.landingspot=69 -- Landing distance. self.carrierparam.landingdist = self.carrierparam.sterndist+self.carrierparam.landingspot -- Late break. self.BreakLate.name = "Late Break" self.BreakLate.Xmin = -UTILS.NMToMeters( 1 ) -- Not more than 1 NM behind the boat. Last check was at 0. self.BreakLate.Xmax = UTILS.NMToMeters( 5 ) -- Not more than 5 NM in front of the boat. Enough for late breaks? self.BreakLate.Zmin = -UTILS.NMToMeters( 1.6 ) -- Not more than 1.6 NM port. self.BreakLate.Zmax = UTILS.NMToMeters( 1 ) -- Not more than 1 NM starboard. self.BreakLate.LimitXmin = 0 -- Check and next step 0.8 NM port and in front of boat. self.BreakLate.LimitXmax = nil self.BreakLate.LimitZmin = -UTILS.NMToMeters( 0.5 ) -- 926 m port, closer than the stennis as abeam is 0.8-1.0 rather than 1.2 self.BreakLate.LimitZmax = nil end --- Init parameters for LHA-1 Tarawa carrier. -- @param #AIRBOSS self function AIRBOSS:_InitTarawa() -- Init Stennis as default. self:_InitStennis() -- Carrier Parameters. self.carrierparam.sterndist = -125 self.carrierparam.deckheight = 21 -- 69 ft -- Total size of the carrier (approx as rectangle). self.carrierparam.totlength = 245 self.carrierparam.totwidthport = 10 self.carrierparam.totwidthstarboard = 25 -- Landing runway. self.carrierparam.rwyangle = 0 self.carrierparam.rwylength = 225 self.carrierparam.rwywidth = 15 -- Wires. self.carrierparam.wire1 = nil self.carrierparam.wire2 = nil self.carrierparam.wire3 = nil self.carrierparam.wire4 = nil -- Distance to landing spot. self.carrierparam.landingspot=57 -- Landing distance. self.carrierparam.landingdist = self.carrierparam.sterndist+self.carrierparam.landingspot -- Late break. self.BreakLate.name = "Late Break" self.BreakLate.Xmin = -UTILS.NMToMeters( 1 ) -- Not more than 1 NM behind the boat. Last check was at 0. self.BreakLate.Xmax = UTILS.NMToMeters( 5 ) -- Not more than 5 NM in front of the boat. Enough for late breaks? self.BreakLate.Zmin = -UTILS.NMToMeters( 1.6 ) -- Not more than 1.6 NM port. self.BreakLate.Zmax = UTILS.NMToMeters( 1 ) -- Not more than 1 NM starboard. self.BreakLate.LimitXmin = 0 -- Check and next step 0.8 NM port and in front of boat. self.BreakLate.LimitXmax = nil self.BreakLate.LimitZmin = -UTILS.NMToMeters( 0.5 ) -- 926 m port, closer than the stennis as abeam is 0.8-1.0 rather than 1.2 self.BreakLate.LimitZmax = nil end --- Init parameters for LHA-6 America carrier. -- @param #AIRBOSS self function AIRBOSS:_InitAmerica() -- Init Stennis as default. self:_InitStennis() -- Carrier Parameters. self.carrierparam.sterndist = -125 self.carrierparam.deckheight = 20 -- 67 ft -- Total size of the carrier (approx as rectangle). self.carrierparam.totlength = 257 self.carrierparam.totwidthport = 11 self.carrierparam.totwidthstarboard = 25 -- Landing runway. self.carrierparam.rwyangle = 0 self.carrierparam.rwylength = 240 self.carrierparam.rwywidth = 15 -- Wires. self.carrierparam.wire1 = nil self.carrierparam.wire2 = nil self.carrierparam.wire3 = nil self.carrierparam.wire4 = nil -- Distance to landing spot. self.carrierparam.landingspot=59 -- Landing distance. self.carrierparam.landingdist = self.carrierparam.sterndist+self.carrierparam.landingspot -- Late break. self.BreakLate.name = "Late Break" self.BreakLate.Xmin = -UTILS.NMToMeters( 1 ) -- Not more than 1 NM behind the boat. Last check was at 0. self.BreakLate.Xmax = UTILS.NMToMeters( 5 ) -- Not more than 5 NM in front of the boat. Enough for late breaks? self.BreakLate.Zmin = -UTILS.NMToMeters( 1.6 ) -- Not more than 1.6 NM port. self.BreakLate.Zmax = UTILS.NMToMeters( 1 ) -- Not more than 1 NM starboard. self.BreakLate.LimitXmin = 0 -- Check and next step 0.8 NM port and in front of boat. self.BreakLate.LimitXmax = nil self.BreakLate.LimitZmin = -UTILS.NMToMeters( 0.5 ) -- 926 m port, closer than the stennis as abeam is 0.8-1.0 rather than 1.2 self.BreakLate.LimitZmax = nil end --- Init parameters for L61 Juan Carlos carrier. -- @param #AIRBOSS self function AIRBOSS:_InitJcarlos() -- Init Stennis as default. self:_InitStennis() -- Carrier Parameters. self.carrierparam.sterndist = -125 self.carrierparam.deckheight = 20 -- 67 ft -- Total size of the carrier (approx as rectangle). self.carrierparam.totlength = 231 self.carrierparam.totwidthport = 10 self.carrierparam.totwidthstarboard = 22 -- Landing runway. self.carrierparam.rwyangle = 0 self.carrierparam.rwylength = 202 self.carrierparam.rwywidth = 14 -- Wires. self.carrierparam.wire1 = nil self.carrierparam.wire2 = nil self.carrierparam.wire3 = nil self.carrierparam.wire4 = nil -- Distance to landing spot. self.carrierparam.landingspot=89 -- Landing distance. self.carrierparam.landingdist = self.carrierparam.sterndist+self.carrierparam.landingspot -- Late break. self.BreakLate.name = "Late Break" self.BreakLate.Xmin = -UTILS.NMToMeters( 1 ) -- Not more than 1 NM behind the boat. Last check was at 0. self.BreakLate.Xmax = UTILS.NMToMeters( 5 ) -- Not more than 5 NM in front of the boat. Enough for late breaks? self.BreakLate.Zmin = -UTILS.NMToMeters( 1.6 ) -- Not more than 1.6 NM port. self.BreakLate.Zmax = UTILS.NMToMeters( 1 ) -- Not more than 1 NM starboard. self.BreakLate.LimitXmin = 0 -- Check and next step 0.8 NM port and in front of boat. self.BreakLate.LimitXmax = nil self.BreakLate.LimitZmin = -UTILS.NMToMeters( 0.5 ) -- 926 m port, closer than the stennis as abeam is 0.8-1.0 rather than 1.2 self.BreakLate.LimitZmax = nil end --- Init parameters for L02 Canberra carrier. -- @param #AIRBOSS self function AIRBOSS:_InitCanberra() -- Init Juan Carlos as default. self:_InitJcarlos() end --- Init parameters for Marshal Voice overs *Gabriella* by HighwaymanEd. -- @param #AIRBOSS self -- @param #string mizfolder (Optional) Folder within miz file where the sound files are located. function AIRBOSS:SetVoiceOversMarshalByGabriella( mizfolder ) -- Set sound files folder. if mizfolder then local lastchar = string.sub( mizfolder, -1 ) if lastchar ~= "/" then mizfolder = mizfolder .. "/" end self.soundfolderMSH = mizfolder else -- Default is the general folder. self.soundfolderMSH = self.soundfolder end -- Report for duty. self:I( self.lid .. string.format( "Marshal Gabriella reporting for duty! Soundfolder=%s", tostring( self.soundfolderMSH ) ) ) self.MarshalCall.AFFIRMATIVE.duration = 0.65 self.MarshalCall.ALTIMETER.duration = 0.60 self.MarshalCall.BRC.duration = 0.67 self.MarshalCall.CARRIERTURNTOHEADING.duration = 1.62 self.MarshalCall.CASE.duration = 0.30 self.MarshalCall.CHARLIETIME.duration = 0.77 self.MarshalCall.CLEAREDFORRECOVERY.duration = 0.93 self.MarshalCall.DECKCLOSED.duration = 0.73 self.MarshalCall.DEGREES.duration = 0.48 self.MarshalCall.EXPECTED.duration = 0.50 self.MarshalCall.FLYNEEDLES.duration = 0.89 self.MarshalCall.HOLDATANGELS.duration = 0.81 self.MarshalCall.HOURS.duration = 0.41 self.MarshalCall.MARSHALRADIAL.duration = 0.95 self.MarshalCall.N0.duration = 0.41 self.MarshalCall.N1.duration = 0.30 self.MarshalCall.N2.duration = 0.34 self.MarshalCall.N3.duration = 0.31 self.MarshalCall.N4.duration = 0.34 self.MarshalCall.N5.duration = 0.30 self.MarshalCall.N6.duration = 0.33 self.MarshalCall.N7.duration = 0.38 self.MarshalCall.N8.duration = 0.35 self.MarshalCall.N9.duration = 0.35 self.MarshalCall.NEGATIVE.duration = 0.60 self.MarshalCall.NEWFB.duration = 0.95 self.MarshalCall.OPS.duration = 0.23 self.MarshalCall.POINT.duration = 0.38 self.MarshalCall.RADIOCHECK.duration = 1.27 self.MarshalCall.RECOVERY.duration = 0.60 self.MarshalCall.RECOVERYOPSSTOPPED.duration = 1.25 self.MarshalCall.RECOVERYPAUSEDNOTICE.duration = 2.55 self.MarshalCall.RECOVERYPAUSEDRESUMED.duration = 2.55 self.MarshalCall.REPORTSEEME.duration = 0.87 self.MarshalCall.RESUMERECOVERY.duration = 1.55 self.MarshalCall.ROGER.duration = 0.50 self.MarshalCall.SAYNEEDLES.duration = 0.82 self.MarshalCall.STACKFULL.duration = 5.70 self.MarshalCall.STARTINGRECOVERY.duration = 1.61 end --- Init parameters for Marshal Voice overs by *Raynor*. -- @param #AIRBOSS self -- @param #string mizfolder (Optional) Folder within miz file where the sound files are located. function AIRBOSS:SetVoiceOversMarshalByRaynor( mizfolder ) -- Set sound files folder. if mizfolder then local lastchar = string.sub( mizfolder, -1 ) if lastchar ~= "/" then mizfolder = mizfolder .. "/" end self.soundfolderMSH = mizfolder else -- Default is the general folder. self.soundfolderMSH = self.soundfolder end -- Report for duty. self:I( self.lid .. string.format( "Marshal Raynor reporting for duty! Soundfolder=%s", tostring( self.soundfolderMSH ) ) ) self.MarshalCall.AFFIRMATIVE.duration = 0.70 self.MarshalCall.ALTIMETER.duration = 0.60 self.MarshalCall.BRC.duration = 0.60 self.MarshalCall.CARRIERTURNTOHEADING.duration = 1.87 self.MarshalCall.CASE.duration = 0.60 self.MarshalCall.CHARLIETIME.duration = 0.81 self.MarshalCall.CLEAREDFORRECOVERY.duration = 1.21 self.MarshalCall.DECKCLOSED.duration = 0.86 self.MarshalCall.DEGREES.duration = 0.55 self.MarshalCall.EXPECTED.duration = 0.61 self.MarshalCall.FLYNEEDLES.duration = 0.90 self.MarshalCall.HOLDATANGELS.duration = 0.91 self.MarshalCall.HOURS.duration = 0.54 self.MarshalCall.MARSHALRADIAL.duration = 0.80 self.MarshalCall.N0.duration = 0.38 self.MarshalCall.N1.duration = 0.30 self.MarshalCall.N2.duration = 0.30 self.MarshalCall.N3.duration = 0.30 self.MarshalCall.N4.duration = 0.32 self.MarshalCall.N5.duration = 0.41 self.MarshalCall.N6.duration = 0.48 self.MarshalCall.N7.duration = 0.51 self.MarshalCall.N8.duration = 0.38 self.MarshalCall.N9.duration = 0.34 self.MarshalCall.NEGATIVE.duration = 0.60 self.MarshalCall.NEWFB.duration = 1.10 self.MarshalCall.OPS.duration = 0.46 self.MarshalCall.POINT.duration = 0.21 self.MarshalCall.RADIOCHECK.duration = 0.95 self.MarshalCall.RECOVERY.duration = 0.63 self.MarshalCall.RECOVERYOPSSTOPPED.duration = 1.36 self.MarshalCall.RECOVERYPAUSEDNOTICE.duration = 2.8 -- Strangely the file is actually a shorter ~2.4 sec. self.MarshalCall.RECOVERYPAUSEDRESUMED.duration = 2.75 self.MarshalCall.REPORTSEEME.duration = 1.06 -- 0.96 self.MarshalCall.RESUMERECOVERY.duration = 1.41 self.MarshalCall.ROGER.duration = 0.41 self.MarshalCall.SAYNEEDLES.duration = 0.79 self.MarshalCall.STACKFULL.duration = 4.70 self.MarshalCall.STARTINGRECOVERY.duration = 2.06 end --- Set parameters for LSO Voice overs by *Raynor*. -- @param #AIRBOSS self -- @param #string mizfolder (Optional) Folder within miz file where the sound files are located. function AIRBOSS:SetVoiceOversLSOByRaynor( mizfolder ) -- Set sound files folder. if mizfolder then local lastchar = string.sub( mizfolder, -1 ) if lastchar ~= "/" then mizfolder = mizfolder .. "/" end self.soundfolderLSO = mizfolder else -- Default is the general folder. self.soundfolderLSO = self.soundfolder end -- Report for duty. self:I( self.lid .. string.format( "LSO Raynor reporting for duty! Soundfolder=%s", tostring( self.soundfolderLSO ) ) ) self.LSOCall.BOLTER.duration = 0.75 self.LSOCall.CALLTHEBALL.duration = 0.625 self.LSOCall.CHECK.duration = 0.40 self.LSOCall.CLEAREDTOLAND.duration = 0.85 self.LSOCall.COMELEFT.duration = 0.60 self.LSOCall.DEPARTANDREENTER.duration = 1.10 self.LSOCall.EXPECTHEAVYWAVEOFF.duration = 1.30 self.LSOCall.EXPECTSPOT75.duration = 1.85 self.LSOCall.EXPECTSPOT5.duration = 1.3 self.LSOCall.FAST.duration = 0.75 self.LSOCall.FOULDECK.duration = 0.75 self.LSOCall.HIGH.duration = 0.65 self.LSOCall.IDLE.duration = 0.40 self.LSOCall.LONGINGROOVE.duration = 1.25 self.LSOCall.LOW.duration = 0.60 self.LSOCall.N0.duration = 0.38 self.LSOCall.N1.duration = 0.30 self.LSOCall.N2.duration = 0.30 self.LSOCall.N3.duration = 0.30 self.LSOCall.N4.duration = 0.32 self.LSOCall.N5.duration = 0.41 self.LSOCall.N6.duration = 0.48 self.LSOCall.N7.duration = 0.51 self.LSOCall.N8.duration = 0.38 self.LSOCall.N9.duration = 0.34 self.LSOCall.PADDLESCONTACT.duration = 0.91 self.LSOCall.POWER.duration = 0.45 self.LSOCall.RADIOCHECK.duration = 0.90 self.LSOCall.RIGHTFORLINEUP.duration = 0.70 self.LSOCall.ROGERBALL.duration = 0.72 self.LSOCall.SLOW.duration = 0.63 -- self.LSOCall.SLOW.duration=0.59 --TODO self.LSOCall.STABILIZED.duration = 0.75 self.LSOCall.WAVEOFF.duration = 0.55 self.LSOCall.WELCOMEABOARD.duration = 0.80 end --- Set parameters for LSO Voice overs by *funkyfranky*. -- @param #AIRBOSS self -- @param #string mizfolder (Optional) Folder within miz file where the sound files are located. function AIRBOSS:SetVoiceOversLSOByFF( mizfolder ) -- Set sound files folder. if mizfolder then local lastchar = string.sub( mizfolder, -1 ) if lastchar ~= "/" then mizfolder = mizfolder .. "/" end self.soundfolderLSO = mizfolder else -- Default is the general folder. self.soundfolderLSO = self.soundfolder end -- Report for duty. self:I( self.lid .. string.format( "LSO FF reporting for duty! Soundfolder=%s", tostring( self.soundfolderLSO ) ) ) self.LSOCall.BOLTER.duration = 0.75 self.LSOCall.CALLTHEBALL.duration = 0.60 self.LSOCall.CHECK.duration = 0.45 self.LSOCall.CLEAREDTOLAND.duration = 1.00 self.LSOCall.COMELEFT.duration = 0.60 self.LSOCall.DEPARTANDREENTER.duration = 1.10 self.LSOCall.EXPECTHEAVYWAVEOFF.duration = 1.20 self.LSOCall.EXPECTSPOT75.duration = 2.00 self.LSOCall.EXPECTSPOT5.duration = 1.3 self.LSOCall.FAST.duration = 0.70 self.LSOCall.FOULDECK.duration = 0.62 self.LSOCall.HIGH.duration = 0.65 self.LSOCall.IDLE.duration = 0.45 self.LSOCall.LONGINGROOVE.duration = 1.20 self.LSOCall.LOW.duration = 0.50 self.LSOCall.N0.duration = 0.40 self.LSOCall.N1.duration = 0.25 self.LSOCall.N2.duration = 0.37 self.LSOCall.N3.duration = 0.37 self.LSOCall.N4.duration = 0.39 self.LSOCall.N5.duration = 0.39 self.LSOCall.N6.duration = 0.40 self.LSOCall.N7.duration = 0.40 self.LSOCall.N8.duration = 0.37 self.LSOCall.N9.duration = 0.40 self.LSOCall.PADDLESCONTACT.duration = 1.00 self.LSOCall.POWER.duration = 0.50 self.LSOCall.RADIOCHECK.duration = 1.10 self.LSOCall.RIGHTFORLINEUP.duration = 0.80 self.LSOCall.ROGERBALL.duration = 1.00 self.LSOCall.SLOW.duration = 0.65 self.LSOCall.SLOW.duration = 0.59 self.LSOCall.STABILIZED.duration = 0.90 self.LSOCall.WAVEOFF.duration = 0.60 self.LSOCall.WELCOMEABOARD.duration = 1.00 end --- Intit parameters for Marshal Voice overs by *funkyfranky*. -- @param #AIRBOSS self -- @param #string mizfolder (Optional) Folder within miz file where the sound files are located. function AIRBOSS:SetVoiceOversMarshalByFF( mizfolder ) -- Set sound files folder. if mizfolder then local lastchar = string.sub( mizfolder, -1 ) if lastchar ~= "/" then mizfolder = mizfolder .. "/" end self.soundfolderMSH = mizfolder else -- Default is the general folder. self.soundfolderMSH = self.soundfolder end -- Report for duty. self:I( self.lid .. string.format( "Marshal FF reporting for duty! Soundfolder=%s", tostring( self.soundfolderMSH ) ) ) self.MarshalCall.AFFIRMATIVE.duration = 0.90 self.MarshalCall.ALTIMETER.duration = 0.85 self.MarshalCall.BRC.duration = 0.80 self.MarshalCall.CARRIERTURNTOHEADING.duration = 2.48 self.MarshalCall.CASE.duration = 0.40 self.MarshalCall.CHARLIETIME.duration = 0.90 self.MarshalCall.CLEAREDFORRECOVERY.duration = 1.25 self.MarshalCall.DECKCLOSED.duration = 1.10 self.MarshalCall.DEGREES.duration = 0.60 self.MarshalCall.EXPECTED.duration = 0.55 self.MarshalCall.FLYNEEDLES.duration = 0.90 self.MarshalCall.HOLDATANGELS.duration = 1.10 self.MarshalCall.HOURS.duration = 0.60 self.MarshalCall.MARSHALRADIAL.duration = 1.10 self.MarshalCall.N0.duration = 0.40 self.MarshalCall.N1.duration = 0.25 self.MarshalCall.N2.duration = 0.37 self.MarshalCall.N3.duration = 0.37 self.MarshalCall.N4.duration = 0.39 self.MarshalCall.N5.duration = 0.39 self.MarshalCall.N6.duration = 0.40 self.MarshalCall.N7.duration = 0.40 self.MarshalCall.N8.duration = 0.37 self.MarshalCall.N9.duration = 0.40 self.MarshalCall.NEGATIVE.duration = 0.80 self.MarshalCall.NEWFB.duration = 1.35 self.MarshalCall.OPS.duration = 0.48 self.MarshalCall.POINT.duration = 0.33 self.MarshalCall.RADIOCHECK.duration = 1.20 self.MarshalCall.RECOVERY.duration = 0.70 self.MarshalCall.RECOVERYOPSSTOPPED.duration = 1.65 self.MarshalCall.RECOVERYPAUSEDNOTICE.duration = 2.9 -- Strangely the file is actually a shorter ~2.4 sec. self.MarshalCall.RECOVERYPAUSEDRESUMED.duration = 3.40 self.MarshalCall.REPORTSEEME.duration = 0.95 self.MarshalCall.RESUMERECOVERY.duration = 1.75 self.MarshalCall.ROGER.duration = 0.53 self.MarshalCall.SAYNEEDLES.duration = 0.90 self.MarshalCall.STACKFULL.duration = 6.35 self.MarshalCall.STARTINGRECOVERY.duration = 2.65 end --- Init voice over radio transmission call. -- @param #AIRBOSS self function AIRBOSS:_InitVoiceOvers() --------------- -- LSO Radio -- --------------- -- LSO Radio Calls. self.LSOCall = { BOLTER = { file = "LSO-BolterBolter", suffix = "ogg", loud = false, subtitle = "Bolter, Bolter", duration = 0.75, subduration = 5 }, CALLTHEBALL = { file = "LSO-CallTheBall", suffix = "ogg", loud = false, subtitle = "Call the ball", duration = 0.6, subduration = 2 }, CHECK = { file = "LSO-Check", suffix = "ogg", loud = false, subtitle = "Check", duration = 0.45, subduration = 2.5 }, CLEAREDTOLAND = { file = "LSO-ClearedToLand", suffix = "ogg", loud = false, subtitle = "Cleared to land", duration = 1.0, subduration = 5 }, COMELEFT = { file = "LSO-ComeLeft", suffix = "ogg", loud = true, subtitle = "Come left", duration = 0.60, subduration = 1 }, RADIOCHECK = { file = "LSO-RadioCheck", suffix = "ogg", loud = false, subtitle = "Paddles, radio check", duration = 1.1, subduration = 5 }, RIGHTFORLINEUP = { file = "LSO-RightForLineup", suffix = "ogg", loud = true, subtitle = "Right for line up", duration = 0.80, subduration = 1 }, HIGH = { file = "LSO-High", suffix = "ogg", loud = true, subtitle = "You're high", duration = 0.65, subduration = 1 }, LOW = { file = "LSO-Low", suffix = "ogg", loud = true, subtitle = "You're low", duration = 0.50, subduration = 1 }, POWER = { file = "LSO-Power", suffix = "ogg", loud = true, subtitle = "Power", duration = 0.50, subduration = 1 }, -- duration 0.45 was too short SLOW = { file = "LSO-Slow", suffix = "ogg", loud = true, subtitle = "You're slow", duration = 0.65, subduration = 1 }, FAST = { file = "LSO-Fast", suffix = "ogg", loud = true, subtitle = "You're fast", duration = 0.70, subduration = 1 }, ROGERBALL = { file = "LSO-RogerBall", suffix = "ogg", loud = false, subtitle = "Roger ball", duration = 1.00, subduration = 2 }, WAVEOFF = { file = "LSO-WaveOff", suffix = "ogg", loud = false, subtitle = "Wave off", duration = 0.6, subduration = 5 }, LONGINGROOVE = { file = "LSO-LongInTheGroove", suffix = "ogg", loud = false, subtitle = "You're long in the groove", duration = 1.2, subduration = 5 }, FOULDECK = { file = "LSO-FoulDeck", suffix = "ogg", loud = false, subtitle = "Foul deck", duration = 0.62, subduration = 5 }, DEPARTANDREENTER = { file = "LSO-DepartAndReenter", suffix = "ogg", loud = false, subtitle = "Depart and re-enter", duration = 1.1, subduration = 5 }, PADDLESCONTACT = { file = "LSO-PaddlesContact", suffix = "ogg", loud = false, subtitle = "Paddles, contact", duration = 1.0, subduration = 5 }, WELCOMEABOARD = { file = "LSO-WelcomeAboard", suffix = "ogg", loud = false, subtitle = "Welcome aboard", duration = 1.0, subduration = 5 }, EXPECTHEAVYWAVEOFF = { file = "LSO-ExpectHeavyWaveoff", suffix = "ogg", loud = false, subtitle = "Expect heavy waveoff", duration = 1.2, subduration = 5 }, EXPECTSPOT75 = { file = "LSO-ExpectSpot75", suffix = "ogg", loud = false, subtitle = "Expect spot 7.5", duration = 2.0, subduration = 5 }, EXPECTSPOT5 = { file = "LSO-ExpectSpot5", suffix = "ogg", loud = false, subtitle = "Expect spot 5", duration = 1.3, subduration = 5 }, STABILIZED = { file = "LSO-Stabilized", suffix = "ogg", loud = false, subtitle = "Stabilized", duration = 0.9, subduration = 5 }, IDLE = { file = "LSO-Idle", suffix = "ogg", loud = false, subtitle = "Idle", duration = 0.45, subduration = 5 }, N0 = { file = "LSO-N0", suffix = "ogg", loud = false, subtitle = "", duration = 0.40 }, N1 = { file = "LSO-N1", suffix = "ogg", loud = false, subtitle = "", duration = 0.25 }, N2 = { file = "LSO-N2", suffix = "ogg", loud = false, subtitle = "", duration = 0.37 }, N3 = { file = "LSO-N3", suffix = "ogg", loud = false, subtitle = "", duration = 0.37 }, N4 = { file = "LSO-N4", suffix = "ogg", loud = false, subtitle = "", duration = 0.39 }, N5 = { file = "LSO-N5", suffix = "ogg", loud = false, subtitle = "", duration = 0.39 }, N6 = { file = "LSO-N6", suffix = "ogg", loud = false, subtitle = "", duration = 0.40 }, N7 = { file = "LSO-N7", suffix = "ogg", loud = false, subtitle = "", duration = 0.40 }, N8 = { file = "LSO-N8", suffix = "ogg", loud = false, subtitle = "", duration = 0.37 }, N9 = { file = "LSO-N9", suffix = "ogg", loud = false, subtitle = "", duration = 0.40 }, CLICK = { file = "AIRBOSS-RadioClick", suffix = "ogg", loud = false, subtitle = "", duration = 0.35 }, NOISE = { file = "AIRBOSS-Noise", suffix = "ogg", loud = false, subtitle = "", duration = 3.6 }, SPINIT = { file = "AIRBOSS-SpinIt", suffix = "ogg", loud = false, subtitle = "", duration = 0.73, subduration = 5 }, } ----------------- -- Pilot Calls -- ----------------- -- Pilot Radio Calls. self.PilotCall = { N0 = { file = "PILOT-N0", suffix = "ogg", loud = false, subtitle = "", duration = 0.40 }, N1 = { file = "PILOT-N1", suffix = "ogg", loud = false, subtitle = "", duration = 0.25 }, N2 = { file = "PILOT-N2", suffix = "ogg", loud = false, subtitle = "", duration = 0.37 }, N3 = { file = "PILOT-N3", suffix = "ogg", loud = false, subtitle = "", duration = 0.37 }, N4 = { file = "PILOT-N4", suffix = "ogg", loud = false, subtitle = "", duration = 0.39 }, N5 = { file = "PILOT-N5", suffix = "ogg", loud = false, subtitle = "", duration = 0.39 }, N6 = { file = "PILOT-N6", suffix = "ogg", loud = false, subtitle = "", duration = 0.40 }, N7 = { file = "PILOT-N7", suffix = "ogg", loud = false, subtitle = "", duration = 0.40 }, N8 = { file = "PILOT-N8", suffix = "ogg", loud = false, subtitle = "", duration = 0.37 }, N9 = { file = "PILOT-N9", suffix = "ogg", loud = false, subtitle = "", duration = 0.40 }, POINT = { file = "PILOT-Point", suffix = "ogg", loud = false, subtitle = "", duration = 0.33 }, SKYHAWK = { file = "PILOT-Skyhawk", suffix = "ogg", loud = false, subtitle = "", duration = 0.95, subduration = 5 }, HARRIER = { file = "PILOT-Harrier", suffix = "ogg", loud = false, subtitle = "", duration = 0.58, subduration = 5 }, HAWKEYE = { file = "PILOT-Hawkeye", suffix = "ogg", loud = false, subtitle = "", duration = 0.63, subduration = 5 }, TOMCAT = { file = "PILOT-Tomcat", suffix = "ogg", loud = false, subtitle = "", duration = 0.66, subduration = 5 }, HORNET = { file = "PILOT-Hornet", suffix = "ogg", loud = false, subtitle = "", duration = 0.56, subduration = 5 }, VIKING = { file = "PILOT-Viking", suffix = "ogg", loud = false, subtitle = "", duration = 0.61, subduration = 5 }, GREYHOUND = { file = "PILOT-Greyhound", suffix = "ogg", loud = false, subtitle = "", duration = 0.61, subduration = 5 }, BALL = { file = "PILOT-Ball", suffix = "ogg", loud = false, subtitle = "", duration = 0.50, subduration = 5 }, BINGOFUEL = { file = "PILOT-BingoFuel", suffix = "ogg", loud = false, subtitle = "", duration = 0.80 }, GASATDIVERT = { file = "PILOT-GasAtDivert", suffix = "ogg", loud = false, subtitle = "", duration = 1.80 }, GASATTANKER = { file = "PILOT-GasAtTanker", suffix = "ogg", loud = false, subtitle = "", duration = 1.95 }, } ------------------- -- MARSHAL Radio -- ------------------- -- MARSHAL Radio Calls. self.MarshalCall = { AFFIRMATIVE = { file = "MARSHAL-Affirmative", suffix = "ogg", loud = false, subtitle = "", duration = 0.90 }, ALTIMETER = { file = "MARSHAL-Altimeter", suffix = "ogg", loud = false, subtitle = "", duration = 0.85 }, BRC = { file = "MARSHAL-BRC", suffix = "ogg", loud = false, subtitle = "", duration = 0.80 }, CARRIERTURNTOHEADING = { file = "MARSHAL-CarrierTurnToHeading", suffix = "ogg", loud = false, subtitle = "", duration = 2.48, subduration = 5 }, CASE = { file = "MARSHAL-Case", suffix = "ogg", loud = false, subtitle = "", duration = 0.40 }, CHARLIETIME = { file = "MARSHAL-CharlieTime", suffix = "ogg", loud = false, subtitle = "", duration = 0.90 }, CLEAREDFORRECOVERY = { file = "MARSHAL-ClearedForRecovery", suffix = "ogg", loud = false, subtitle = "", duration = 1.25 }, DECKCLOSED = { file = "MARSHAL-DeckClosed", suffix = "ogg", loud = false, subtitle = "", duration = 1.10, subduration = 5 }, DEGREES = { file = "MARSHAL-Degrees", suffix = "ogg", loud = false, subtitle = "", duration = 0.60 }, EXPECTED = { file = "MARSHAL-Expected", suffix = "ogg", loud = false, subtitle = "", duration = 0.55 }, FLYNEEDLES = { file = "MARSHAL-FlyYourNeedles", suffix = "ogg", loud = false, subtitle = "Fly your needles", duration = 0.9, subduration = 5 }, HOLDATANGELS = { file = "MARSHAL-HoldAtAngels", suffix = "ogg", loud = false, subtitle = "", duration = 1.10 }, HOURS = { file = "MARSHAL-Hours", suffix = "ogg", loud = false, subtitle = "", duration = 0.60, subduration = 5 }, MARSHALRADIAL = { file = "MARSHAL-MarshalRadial", suffix = "ogg", loud = false, subtitle = "", duration = 1.10 }, N0 = { file = "MARSHAL-N0", suffix = "ogg", loud = false, subtitle = "", duration = 0.40 }, N1 = { file = "MARSHAL-N1", suffix = "ogg", loud = false, subtitle = "", duration = 0.25 }, N2 = { file = "MARSHAL-N2", suffix = "ogg", loud = false, subtitle = "", duration = 0.37 }, N3 = { file = "MARSHAL-N3", suffix = "ogg", loud = false, subtitle = "", duration = 0.37 }, N4 = { file = "MARSHAL-N4", suffix = "ogg", loud = false, subtitle = "", duration = 0.39 }, N5 = { file = "MARSHAL-N5", suffix = "ogg", loud = false, subtitle = "", duration = 0.39 }, N6 = { file = "MARSHAL-N6", suffix = "ogg", loud = false, subtitle = "", duration = 0.40 }, N7 = { file = "MARSHAL-N7", suffix = "ogg", loud = false, subtitle = "", duration = 0.40 }, N8 = { file = "MARSHAL-N8", suffix = "ogg", loud = false, subtitle = "", duration = 0.37 }, N9 = { file = "MARSHAL-N9", suffix = "ogg", loud = false, subtitle = "", duration = 0.40 }, NEGATIVE = { file = "MARSHAL-Negative", suffix = "ogg", loud = false, subtitle = "", duration = 0.80, subduration = 5 }, NEWFB = { file = "MARSHAL-NewFB", suffix = "ogg", loud = false, subtitle = "", duration = 1.35 }, OPS = { file = "MARSHAL-Ops", suffix = "ogg", loud = false, subtitle = "", duration = 0.48 }, POINT = { file = "MARSHAL-Point", suffix = "ogg", loud = false, subtitle = "", duration = 0.33 }, RADIOCHECK = { file = "MARSHAL-RadioCheck", suffix = "ogg", loud = false, subtitle = "Radio check", duration = 1.20, subduration = 5 }, RECOVERY = { file = "MARSHAL-Recovery", suffix = "ogg", loud = false, subtitle = "", duration = 0.70, subduration = 5 }, RECOVERYOPSSTOPPED = { file = "MARSHAL-RecoveryOpsStopped", suffix = "ogg", loud = false, subtitle = "", duration = 1.65, subduration = 5 }, RECOVERYPAUSEDNOTICE = { file = "MARSHAL-RecoveryPausedNotice", suffix = "ogg", loud = false, subtitle = "aircraft recovery paused until further notice", duration = 2.90, subduration = 5 }, RECOVERYPAUSEDRESUMED = { file = "MARSHAL-RecoveryPausedResumed", suffix = "ogg", loud = false, subtitle = "", duration = 3.40, subduration = 5 }, REPORTSEEME = { file = "MARSHAL-ReportSeeMe", suffix = "ogg", loud = false, subtitle = "", duration = 0.95 }, RESUMERECOVERY = { file = "MARSHAL-ResumeRecovery", suffix = "ogg", loud = false, subtitle = "resuming aircraft recovery", duration = 1.75, subduraction = 5 }, ROGER = { file = "MARSHAL-Roger", suffix = "ogg", loud = false, subtitle = "", duration = 0.53, subduration = 5 }, SAYNEEDLES = { file = "MARSHAL-SayNeedles", suffix = "ogg", loud = false, subtitle = "Say needles", duration = 0.90, subduration = 5 }, STACKFULL = { file = "MARSHAL-StackFull", suffix = "ogg", loud = false, subtitle = "Marshal Stack is currently full. Hold outside 10 NM zone and wait for further instructions", duration = 6.35, subduration = 10 }, STARTINGRECOVERY = { file = "MARSHAL-StartingRecovery", suffix = "ogg", loud = false, subtitle = "", duration = 2.65, subduration = 5 }, CLICK = { file = "AIRBOSS-RadioClick", suffix = "ogg", loud = false, subtitle = "", duration = 0.35 }, NOISE = { file = "AIRBOSS-Noise", suffix = "ogg", loud = false, subtitle = "", duration = 3.6 }, } -- Default timings by Raynor self:SetVoiceOversLSOByRaynor() self:SetVoiceOversMarshalByRaynor() end --- Init voice over radio transmission call. -- @param #AIRBOSS self -- @param #AIRBOSS.RadioCall radiocall LSO or Marshal radio call object. -- @param #number duration Duration of the voice over in seconds. -- @param #string subtitle (Optional) Subtitle to be displayed along with voice over. -- @param #number subduration (Optional) Duration how long the subtitle is displayed. -- @param #string filename (Optional) Name of the voice over sound file. -- @param #string suffix (Optional) Extention of file. Default ".ogg". function AIRBOSS:SetVoiceOver( radiocall, duration, subtitle, subduration, filename, suffix ) radiocall.duration = duration radiocall.subtitle = subtitle or radiocall.subtitle radiocall.file = filename radiocall.suffix = suffix or ".ogg" end --- Get optimal aircraft AoA parameters.. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data table. -- @return #AIRBOSS.AircraftAoA AoA parameters for the given aircraft type. function AIRBOSS:_GetAircraftAoA( playerData ) -- Get AC type. local hornet = playerData.actype == AIRBOSS.AircraftCarrier.HORNET or playerData.actype == AIRBOSS.AircraftCarrier.RHINOE or playerData.actype == AIRBOSS.AircraftCarrier.RHINOF or playerData.actype == AIRBOSS.AircraftCarrier.GROWLER local goshawk = playerData.actype == AIRBOSS.AircraftCarrier.T45C local skyhawk = playerData.actype == AIRBOSS.AircraftCarrier.A4EC local harrier = playerData.actype == AIRBOSS.AircraftCarrier.AV8B local tomcat = playerData.actype == AIRBOSS.AircraftCarrier.F14A or playerData.actype == AIRBOSS.AircraftCarrier.F14B -- Table with AoA values. local aoa = {} -- #AIRBOSS.AircraftAoA if hornet then -- F/A-18C Hornet parameters. aoa.SLOW = 9.8 aoa.Slow = 9.3 aoa.OnSpeedMax = 8.8 aoa.OnSpeed = 8.1 aoa.OnSpeedMin = 7.4 aoa.Fast = 6.9 aoa.FAST = 6.3 elseif tomcat then -- F-14A/B Tomcat parameters (taken from NATOPS). Converted from units 0-30 to degrees. -- Currently assuming a linear relationship with 0=-10 degrees and 30=+40 degrees as stated in NATOPS. aoa.SLOW = self:_AoAUnit2Deg( playerData, 17.0 ) -- 18.33 --17.0 units aoa.Slow = self:_AoAUnit2Deg( playerData, 16.0 ) -- 16.67 --16.0 units aoa.OnSpeedMax = self:_AoAUnit2Deg( playerData, 15.5 ) -- 15.83 --15.5 units aoa.OnSpeed = self:_AoAUnit2Deg( playerData, 15.0 ) -- 15.0 --15.0 units aoa.OnSpeedMin = self:_AoAUnit2Deg( playerData, 14.5 ) -- 14.17 --14.5 units aoa.Fast = self:_AoAUnit2Deg( playerData, 14.0 ) -- 13.33 --14.0 units aoa.FAST = self:_AoAUnit2Deg( playerData, 13.0 ) -- 11.67 --13.0 units elseif goshawk then -- T-45C Goshawk parameters. aoa.SLOW = 8.00 -- 19 aoa.Slow = 7.75 -- 18 aoa.OnSpeedMax = 7.25 -- 17.5 aoa.OnSpeed = 7.00 -- 17 aoa.OnSpeedMin = 6.75 -- 16.5 aoa.Fast = 6.25 -- 16 aoa.FAST = 6.00 -- 15 elseif skyhawk then -- A-4E-C Skyhawk parameters from https://forums.eagle.ru/showpost.php?p=3703467&postcount=390 -- Note that these are arbitrary UNITS and not degrees. We need a conversion formula! -- Github repo suggests they simply use a factor of two to get from degrees to units. aoa.SLOW = 9.50 -- =19.0/2 aoa.Slow = 9.25 -- =18.5/2 aoa.OnSpeedMax = 9.00 -- =18.0/2 aoa.OnSpeed = 8.75 -- =17.5/2 8.1 aoa.OnSpeedMin = 8.50 -- =17.0/2 aoa.Fast = 8.25 -- =17.5/2 aoa.FAST = 8.00 -- =16.5/2 elseif harrier then -- AV-8B Harrier parameters. Tuning done on the Fast AoA to allow for abeam and ninety at Nozzles 55. Pene testing aoa.SLOW = 16.0 aoa.Slow = 13.5 aoa.OnSpeedMax = 12.5 aoa.OnSpeed = 10.0 aoa.OnSpeedMin = 9.5 aoa.Fast = 8.0 aoa.FAST = 7.5 end return aoa end --- Convert AoA from arbitrary units to degrees. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data table. -- @param #number aoaunits AoA in arbitrary units. -- @return #number AoA in degrees. function AIRBOSS:_AoAUnit2Deg( playerData, aoaunits ) -- Init. local degrees = aoaunits -- Check aircraft type of player. if playerData.actype == AIRBOSS.AircraftCarrier.F14A or playerData.actype == AIRBOSS.AircraftCarrier.F14B then ------------- -- F-14A/B -- ------------- -- NATOPS: -- unit=0 ==> alpha=-10 degrees. -- unit=30 ==> alpha=+40 degrees. -- Assuming a linear relationship between these to points of the graph. -- However: AoA=15 Units ==> 15 degrees, which is too much. degrees = -10 + 50 / 30 * aoaunits -- HB Facebook page https://www.facebook.com/heatblur/photos/a.683612385159716/754368278084126 -- AoA=15 Units <==> AoA=10.359 degrees. degrees = 0.918 * aoaunits - 3.411 elseif playerData.actype == AIRBOSS.AircraftCarrier.A4EC then ---------- -- A-4E -- ---------- -- A-4E-C source code suggests a simple factor of 1/2 for conversion. degrees = 0.5 * aoaunits end return degrees end --- Convert AoA from degrees to arbitrary units. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data table. -- @param #number degrees AoA in degrees. -- @return #number AoA in arbitrary units. function AIRBOSS:_AoADeg2Units( playerData, degrees ) -- Init. local aoaunits = degrees -- Check aircraft type of player. if playerData.actype == AIRBOSS.AircraftCarrier.F14A or playerData.actype == AIRBOSS.AircraftCarrier.F14B then ------------- -- F-14A/B -- ------------- -- NATOPS: -- unit=0 ==> alpha=-10 degrees. -- unit=30 ==> alpha=+40 degrees. -- Assuming a linear relationship between these to points of the graph. aoaunits = (degrees + 10) * 30 / 50 -- HB Facebook page https://www.facebook.com/heatblur/photos/a.683612385159716/754368278084126 -- AoA=15 Units <==> AoA=10.359 degrees. aoaunits = 1.089 * degrees + 3.715 elseif playerData.actype == AIRBOSS.AircraftCarrier.A4EC then ---------- -- A-4E -- ---------- -- A-4E source code suggests a simple factor of two as conversion. aoaunits = 2 * degrees end return aoaunits end --- Get optimal aircraft flight parameters at checkpoint. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data table. -- @param #string step Pattern step. -- @return #number Altitude in meters or nil. -- @return #number Angle of Attack or nil. -- @return #number Distance to carrier in meters or nil. -- @return #number Speed in m/s or nil. function AIRBOSS:_GetAircraftParameters( playerData, step ) -- Get parameters depended on step. step = step or playerData.step -- Get AC type. local hornet = playerData.actype == AIRBOSS.AircraftCarrier.HORNET or playerData.actype == AIRBOSS.AircraftCarrier.RHINOE or playerData.actype == AIRBOSS.AircraftCarrier.RHINOF or playerData.actype == AIRBOSS.AircraftCarrier.GROWLER local skyhawk = playerData.actype == AIRBOSS.AircraftCarrier.A4EC local tomcat = playerData.actype == AIRBOSS.AircraftCarrier.F14A or playerData.actype == AIRBOSS.AircraftCarrier.F14B local harrier = playerData.actype == AIRBOSS.AircraftCarrier.AV8B local goshawk = playerData.actype == AIRBOSS.AircraftCarrier.T45C -- Return values. local alt local aoa local dist local speed -- Aircraft specific AoA. local aoaac = self:_GetAircraftAoA( playerData ) if step == AIRBOSS.PatternStep.PLATFORM then alt = UTILS.FeetToMeters( 5000 ) -- dist=UTILS.NMToMeters(20) speed = UTILS.KnotsToMps( 250 ) elseif step == AIRBOSS.PatternStep.ARCIN then if tomcat then speed = UTILS.KnotsToMps( 150 ) else speed = UTILS.KnotsToMps( 250 ) end elseif step == AIRBOSS.PatternStep.ARCOUT then if tomcat then speed = UTILS.KnotsToMps( 150 ) else speed = UTILS.KnotsToMps( 250 ) end elseif step == AIRBOSS.PatternStep.DIRTYUP then alt = UTILS.FeetToMeters( 1200 ) -- speed=UTILS.KnotsToMps(250) elseif step == AIRBOSS.PatternStep.BULLSEYE then alt = UTILS.FeetToMeters( 1200 ) dist = -UTILS.NMToMeters( 3 ) aoa = aoaac.OnSpeed elseif step == AIRBOSS.PatternStep.INITIAL then if hornet or tomcat or harrier then alt = UTILS.FeetToMeters( 800 ) speed = UTILS.KnotsToMps( 350 ) elseif skyhawk then alt = UTILS.FeetToMeters( 600 ) speed = UTILS.KnotsToMps( 250 ) elseif goshawk then alt = UTILS.FeetToMeters( 800 ) speed = UTILS.KnotsToMps( 300 ) end elseif step == AIRBOSS.PatternStep.BREAKENTRY then if hornet or tomcat or harrier then alt = UTILS.FeetToMeters( 800 ) speed = UTILS.KnotsToMps( 350 ) elseif skyhawk then alt = UTILS.FeetToMeters( 600 ) speed = UTILS.KnotsToMps( 250 ) elseif goshawk then alt = UTILS.FeetToMeters( 800 ) speed = UTILS.KnotsToMps( 300 ) end elseif step == AIRBOSS.PatternStep.EARLYBREAK then if hornet or tomcat or harrier or goshawk then alt = UTILS.FeetToMeters( 800 ) elseif skyhawk then alt = UTILS.FeetToMeters( 600 ) end elseif step == AIRBOSS.PatternStep.LATEBREAK then if hornet or tomcat or harrier or goshawk then alt = UTILS.FeetToMeters( 800 ) elseif skyhawk then alt = UTILS.FeetToMeters( 600 ) end elseif step == AIRBOSS.PatternStep.ABEAM then if hornet or tomcat or harrier or goshawk then alt = UTILS.FeetToMeters( 600 ) elseif skyhawk then alt = UTILS.FeetToMeters( 500 ) end aoa = aoaac.OnSpeed if goshawk then -- 0.9 to 1.1 NM per natops ch.4 page 48 dist = UTILS.NMToMeters( 0.9 ) elseif harrier then -- 0.8 to 1.0 NM dist = UTILS.NMToMeters( 0.9 ) else dist = UTILS.NMToMeters( 1.1 ) end elseif step == AIRBOSS.PatternStep.NINETY then if hornet or tomcat then alt = UTILS.FeetToMeters( 500 ) elseif goshawk then alt = UTILS.FeetToMeters( 450 ) elseif skyhawk then alt = UTILS.FeetToMeters( 500 ) elseif harrier then alt = UTILS.FeetToMeters( 425 ) end aoa = aoaac.OnSpeed elseif step == AIRBOSS.PatternStep.WAKE then if hornet or goshawk then alt = UTILS.FeetToMeters( 370 ) elseif tomcat then alt = UTILS.FeetToMeters( 430 ) -- Tomcat should be a bit higher as it intercepts the GS a bit higher. elseif skyhawk then alt = UTILS.FeetToMeters( 370 ) -- ? end -- Harrier wont get into wake pos. Runway is not angled and it stays port. aoa = aoaac.OnSpeed elseif step == AIRBOSS.PatternStep.FINAL then if hornet or goshawk then alt = UTILS.FeetToMeters( 300 ) elseif tomcat then alt = UTILS.FeetToMeters( 360 ) elseif skyhawk then alt = UTILS.FeetToMeters( 300 ) -- ? elseif harrier then alt=UTILS.FeetToMeters(312)-- 300-325 ft end aoa = aoaac.OnSpeed end return alt, aoa, dist, speed end ---------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- -- QUEUE Functions ---------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- --- Get next marshal flight which is ready to enter the landing pattern. -- @param #AIRBOSS self -- @return #AIRBOSS.FlightGroup Marshal flight next in line and ready to enter the pattern. Or nil if no flight is ready. function AIRBOSS:_GetNextMarshalFight() -- Loop over all marshal flights. for _, _flight in pairs( self.Qmarshal ) do local flight = _flight -- #AIRBOSS.FlightGroup -- Current stack. local stack = flight.flag -- Total marshal time in seconds. local Tmarshal = timer.getAbsTime() - flight.time -- Min time in marshal stack. local TmarshalMin = 2 * 60 -- Two minutes for human players. if flight.ai then TmarshalMin = 3 * 60 -- Three minutes for AI. end -- Check if conditions are right. if flight.holding ~= nil and Tmarshal >= TmarshalMin then if flight.case == 1 and stack == 1 or flight.case > 1 then if flight.ai then -- Return AI flight. return flight else -- Check for human player if they are already commencing. if flight.step ~= AIRBOSS.PatternStep.COMMENCING then return flight end end end end end return nil end --- Check marshal and pattern queues. -- @param #AIRBOSS self function AIRBOSS:_CheckQueue() -- Print queues. if self.Debug then self:_PrintQueue( self.flights, "All Flights" ) end self:_PrintQueue( self.Qmarshal, "Marshal" ) self:_PrintQueue( self.Qpattern, "Pattern" ) self:_PrintQueue( self.Qwaiting, "Waiting" ) self:_PrintQueue( self.Qspinning, "Spinning" ) -- If flights are waiting outside 10 NM zone and carrier switches from Case I to Case II/III, they should be added to the Marshal stack as now there is no stack limit any more. if self.case > 1 then for _, _flight in pairs( self.Qwaiting ) do local flight = _flight -- #AIRBOSS.FlightGroup -- Remove flight from waiting queue. local removed = self:_RemoveFlightFromQueue( self.Qwaiting, flight ) if removed then -- Get free stack local stack = self:_GetFreeStack( flight.ai ) -- Debug info. self:T( self.lid .. string.format( "Moving flight %s onboard %s from Waiting queue to Case %d Marshal stack %d", flight.groupname, flight.onboard, self.case, stack ) ) -- Send flight to marshal stack. if flight.ai then self:_MarshalAI( flight, stack ) else self:_MarshalPlayer( flight, stack ) end -- Break the loop so that only one flight per 30 seconds is removed. break end end end -- Check if carrier is currently in recovery mode. if not self:IsRecovering() then ----------------------------- -- Switching Recovery Case -- ----------------------------- -- Loop over all flights currently in the marshal queue. for _, _flight in pairs( self.Qmarshal ) do local flight = _flight -- #AIRBOSS.FlightGroup -- TODO: In principle this should be done/necessary only if case 1-->2/3 or 2/3-->1, right? -- When recovery switches from 2->3 or 3-->2 nothing changes in the marshal stack. -- Check if a change of stack is necessary. if (flight.case == 1 and self.case > 1) or (flight.case > 1 and self.case == 1) then -- Remove flight from marshal queue. local removed = self:_RemoveFlightFromQueue( self.Qmarshal, flight ) if removed then -- Get free stack local stack = self:_GetFreeStack( flight.ai ) -- Debug output. self:T( self.lid .. string.format( "Moving flight %s onboard %s from Marshal Case %d ==> %d Marshal stack %d", flight.groupname, flight.onboard, flight.case, self.case, stack ) ) -- Send flight to marshal queue. if flight.ai then self:_MarshalAI( flight, stack ) else self:_MarshalPlayer( flight, stack ) end -- Break the loop so that only one flight per 30 seconds is removed. No spam of messages, no conflict with the loop over queue entries. break elseif flight.case ~= self.case then -- This should handle 2-->3 or 3-->2 flight.case = self.case end end end -- Not recovering ==> skip the rest! return end -- Get number of airborne aircraft units(!) currently in pattern. local _, npattern = self:_GetQueueInfo( self.Qpattern ) -- Get number of aircraft units spinning. local _, nspinning = self:_GetQueueInfo( self.Qspinning ) -- Get next marshal flight. local marshalflight = self:_GetNextMarshalFight() -- Check if there are flights waiting in the Marshal stack and if the pattern is free. No one should be spinning. if marshalflight and npattern < self.Nmaxpattern and nspinning == 0 then -- Time flight is marshaling. local Tmarshal = timer.getAbsTime() - marshalflight.time self:T( self.lid .. string.format( "Marshal time of next group %s = %d seconds", marshalflight.groupname, Tmarshal ) ) -- Time (last) flight has entered landing pattern. local Tpattern = 9999 local npunits = 1 local pcase = 1 if npattern > 0 then -- Last flight group send to pattern. local patternflight = self.Qpattern[#self.Qpattern] -- #AIRBOSS.FlightGroup -- Recovery case of pattern flight. pcase = patternflight.case -- Number of airborne aircraft in this group. Count includes section members. local npunits = self:_GetFlightUnits( patternflight, false ) -- Get time in pattern. Tpattern = timer.getAbsTime() - patternflight.time self:T( self.lid .. string.format( "Pattern time of last group %s = %d seconds. # of units=%d.", patternflight.groupname, Tpattern, npunits ) ) end -- Min time in pattern before next aircraft is allowed. local TpatternMin if pcase == 1 then TpatternMin = 2 * 60 * npunits -- 45*npunits -- 45 seconds interval per plane! else TpatternMin = 2 * 60 * npunits -- 120*npunits -- 120 seconds interval per plane! end -- Check interval to last pattern flight. if Tpattern > TpatternMin then self:T( self.lid .. string.format( "Sending marshal flight %s to pattern.", marshalflight.groupname ) ) self:_ClearForLanding( marshalflight ) end end end --- Clear flight for landing. AI are removed from Marshal queue and the Marshal stack is collapsed. -- If next in line is an AI flight, this is done. If human player is next, we wait for "Commence" via F10 radio menu command. -- @param #AIRBOSS self -- @param #AIRBOSS.FlightGroup flight Flight to go to pattern. function AIRBOSS:_ClearForLanding( flight ) -- Check if flight is AI or human. If AI, we collapse the stack and commence. If human, we suggest to commence. if flight.ai then -- Collapse stack and send AI to pattern. self:_RemoveFlightFromMarshalQueue( flight, false ) self:_LandAI( flight ) -- Cleared for Case X recovery. self:_MarshalCallClearedForRecovery( flight.onboard, flight.case ) -- Voice over of the commencing simulated call from AI if self.xtVoiceOversAI then local leader = flight.group:GetUnits()[1] self:_CommencingCall(leader, flight.onboard) end else -- Cleared for Case X recovery. if flight.step ~= AIRBOSS.PatternStep.COMMENCING then self:_MarshalCallClearedForRecovery( flight.onboard, flight.case ) flight.time = timer.getAbsTime() end -- Set step to commencing. This will trigger the zone check until the player is in the right place. self:_SetPlayerStep( flight, AIRBOSS.PatternStep.COMMENCING, 3 ) end end --- Set player step. Any warning is erased and next step hint shown. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data. -- @param #string step Next step. -- @param #number delay (Optional) Set set after a delay in seconds. function AIRBOSS:_SetPlayerStep( playerData, step, delay ) if delay and delay > 0 then -- Delayed call. -- SCHEDULER:New(nil, self._SetPlayerStep, {self, playerData, step}, delay) self:ScheduleOnce( delay, self._SetPlayerStep, self, playerData, step ) else -- Check if player still exists after possible delay. if playerData then -- Set player step. playerData.step = step -- Erase warning. playerData.warning = nil -- Next step hint. self:_StepHint( playerData ) end end end --- Scan carrier zone for (new) units. -- @param #AIRBOSS self function AIRBOSS:_ScanCarrierZone() -- Carrier position. local coord = self:GetCoordinate() -- Scan radius = radius of the CCA. local RCCZ = self.zoneCCA:GetRadius() -- Debug info. self:T( self.lid .. string.format( "Scanning Carrier Controlled Area. Radius=%.1f NM.", UTILS.MetersToNM( RCCZ ) ) ) -- Scan units in carrier zone. local _, _, _, unitscan = coord:ScanObjects( RCCZ, true, false, false ) -- Make a table with all groups currently in the CCA zone. local insideCCA = {} for _, _unit in pairs( unitscan ) do local unit = _unit -- Wrapper.Unit#UNIT -- Necessary conditions to be met: local airborne = unit:IsAir() -- and unit:InAir() local inzone = unit:IsInZone( self.zoneCCA ) local friendly = self:GetCoalition() == unit:GetCoalition() local carrierac = self:_IsCarrierAircraft( unit ) -- Check if this an aircraft and that it is airborne and closing in. if airborne and inzone and friendly and carrierac then local group = unit:GetGroup() local groupname = group:GetName() if insideCCA[groupname] == nil then insideCCA[groupname] = group end end end -- Find new flights that are inside CCA. for groupname, _group in pairs( insideCCA ) do local group = _group -- Wrapper.Group#GROUP -- Get flight group if possible. local knownflight = self:_GetFlightFromGroupInQueue( group, self.flights ) -- Get aircraft type name. local actype = group:GetTypeName() -- Create a new flight group if knownflight then -- Debug output. self:T2(self.lid..string.format("Known flight group %s of type %s in CCA.", groupname, actype)) -- Check if flight is AI and if we want to handle it at all. if knownflight.ai and knownflight.flag == -100 and self.handleai then local putintomarshal = false -- Get flight group. local flight = _DATABASE:GetOpsGroup( groupname ) if flight and flight:IsInbound() and flight.destbase:GetName() == self.carrier:GetName() then if flight.ishelo then else putintomarshal = true end flight.airboss = self end -- Send AI flight to marshal stack if group closes in more than 5 and has initial flag value. if putintomarshal then -- Get the next free stack for current recovery case. local stack = self:_GetFreeStack( knownflight.ai ) -- Repawn. local respawn = self.respawnAI if stack then -- Send AI to marshal stack. We respawn the group to clean possible departure and destination airbases. self:_MarshalAI( knownflight, stack, respawn ) else -- Send AI to orbit outside 10 NM zone and wait until the next Marshal stack is available. if not self:_InQueue( self.Qwaiting, knownflight.group ) then self:_WaitAI( knownflight, respawn ) -- Group is respawned to clear any attached airfields. end end -- Break the loop to not have all flights at once! Spams the message screen. break end -- Closed in or tanker/AWACS end else -- Unknown new AI flight. Create a new flight group. if not self:_IsHuman( group ) then self:_CreateFlightGroup( group ) end end end -- Find flights that are not in CCA. local remove = {} for _, _flight in pairs( self.flights ) do local flight = _flight -- #AIRBOSS.FlightGroup if insideCCA[flight.groupname] == nil then -- Do not remove flights in marshal pattern. At least for case 2 & 3. If zone is set small, they might be outside in the holding pattern. if flight.ai and not (self:_InQueue( self.Qmarshal, flight.group ) or self:_InQueue( self.Qpattern, flight.group )) then table.insert( remove, flight ) end end end -- Remove flight groups outside CCA. for _, flight in pairs( remove ) do self:_RemoveFlightFromQueue( self.flights, flight ) end end --- Tell player to wait outside the 10 NM zone until a Marshal stack is available. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data. function AIRBOSS:_WaitPlayer( playerData ) -- Check if flight is known to the airboss already. if playerData then -- Number of waiting flights local nwaiting = #self.Qwaiting -- Radio message: Stack is full. self:_MarshalCallStackFull( playerData.onboard, nwaiting ) -- Add player flight to waiting queue. table.insert( self.Qwaiting, playerData ) -- Set time stamp. playerData.time = timer.getAbsTime() -- Set step to waiting. playerData.step = AIRBOSS.PatternStep.WAITING playerData.warning = nil -- Set all flights in section to waiting. for _, _flight in pairs( playerData.section ) do local flight = _flight -- #AIRBOSS.PlayerData flight.step = AIRBOSS.PatternStep.WAITING flight.time = timer.getAbsTime() flight.warning = nil end end end --- Orbit at a specified position at a specified altitude with a specified speed. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data. -- @param #number stack The Marshal stack the player gets. function AIRBOSS:_MarshalPlayer( playerData, stack ) -- Check if flight is known to the airboss already. if playerData then -- Add group to marshal stack. self:_AddMarshalGroup( playerData, stack ) -- Set step to holding. self:_SetPlayerStep( playerData, AIRBOSS.PatternStep.HOLDING ) -- Holding switch to nil until player arrives in the holding zone. playerData.holding = nil -- Set same stack for all flights in section. for _, _flight in pairs( playerData.section ) do local flight = _flight -- #AIRBOSS.PlayerData -- XXX: Inform player? Should be done by lead via radio? -- Set step. self:_SetPlayerStep( flight, AIRBOSS.PatternStep.HOLDING ) -- Holding to nil, until arrived. flight.holding = nil -- Set case to that of lead. flight.case = playerData.case -- Set stack flag. flight.flag = stack -- Trigger Marshal event. self:Marshal( flight ) end else self:E( self.lid .. "ERROR: Could not add player to Marshal stack! playerData=nil" ) end end --- Command AI flight to orbit outside the 10 NM zone and wait for a free Marshal stack. -- If the flight is not already holding in the Marshal stack, it is guided there first. -- @param #AIRBOSS self -- @param #AIRBOSS.FlightGroup flight Flight group. -- @param #boolean respawn If true respawn the group. Otherwise reset the mission task with new waypoints. function AIRBOSS:_WaitAI( flight, respawn ) -- Set flag to something other than -100 and <0 flight.flag = -99 -- Add AI flight to waiting queue. table.insert( self.Qwaiting, flight ) -- Flight group name. local group = flight.group local groupname = flight.groupname -- Aircraft speed 274 knots TAS ~= 250 KIAS when orbiting the pattern. (Orbit expects m/s.) local speedOrbitMps = UTILS.KnotsToMps( 274 ) -- Orbit speed in km/h for waypoints. local speedOrbitKmh = UTILS.KnotsToKmph( 274 ) -- Aircraft speed 400 knots when transiting to holding zone. (Waypoint expects km/h.) local speedTransit = UTILS.KnotsToKmph( 370 ) -- Carrier coordinate local cv = self:GetCoordinate() -- Coordinate of flight group local fc = group:GetCoordinate() -- Carrier heading local hdg = self:GetHeading( false ) -- Heading from carrier to flight group local hdgto = cv:HeadingTo( fc ) -- Holding altitude between angels 6 and 10 (random). local angels = math.random( 6, 10 ) local altitude = UTILS.FeetToMeters( angels * 1000 ) -- Point outsize 10 NM zone of the carrier. local p0 = cv:Translate( UTILS.NMToMeters( 11 ), hdgto ):Translate( UTILS.NMToMeters( 5 ), hdg ):SetAltitude( altitude ) -- Waypoints array to be filled depending on case etc. local wp = {} -- Current position. Always good for as the first waypoint. wp[1] = group:GetCoordinate():WaypointAirTurningPoint( nil, speedTransit, {}, "Current Position" ) -- Set orbit task. local taskorbit = group:TaskOrbit( p0, altitude, speedOrbitMps ) -- Orbit at waypoint. wp[#wp + 1] = p0:WaypointAirTurningPoint( nil, speedOrbitKmh, { taskorbit }, string.format( "Waiting Orbit at Angels %d", angels ) ) -- Debug markers. if self.Debug then p0:MarkToAll( string.format( "Waiting Orbit of flight %s at Angels %s", groupname, angels ) ) end if respawn then -- This should clear the landing waypoints. -- Note: This resets the weapons and the fuel state. But not the units fortunately. -- Get group template. local Template = group:GetTemplate() -- Set route points. Template.route.points = wp -- Respawn the group. group = group:Respawn( Template, true ) end -- Reinit waypoints. group:WayPointInitialize( wp ) -- Route group. group:Route( wp, 1 ) end --- Command AI flight to orbit at a specified position at a specified altitude with a specified speed. If flight is not in the Marshal queue yet, it is added. This fixes the recovery case. -- If the flight is not already holding in the Marshal stack, it is guided there first. -- @param #AIRBOSS self -- @param #AIRBOSS.FlightGroup flight Flight group. -- @param #number nstack Stack number of group. Can also be the current stack if AI position needs to be updated wrt to changed carrier position. -- @param #boolean respawn If true, respawn the flight otherwise update mission task with new waypoints. function AIRBOSS:_MarshalAI( flight, nstack, respawn ) self:F2( { flight = flight, nstack = nstack, respawn = respawn } ) -- Nil check. if flight == nil or flight.group == nil then self:E( self.lid .. "ERROR: flight or flight.group is nil." ) return end -- Nil check. if flight.group:GetCoordinate() == nil then self:E( self.lid .. "ERROR: cannot get coordinate of flight group." ) return end -- Check if flight is already in Marshal queue. if not self:_InQueue(self.Qmarshal,flight.group) then -- Simulate inbound call if self.xtVoiceOversAI then local leader = flight.group:GetUnits()[1] self:_MarshallInboundCall(leader, flight.onboard) end -- Add group to marshal stack queue. self:_AddMarshalGroup( flight, nstack ) end -- Explode unit for testing. Worked! -- local u1=flight.group:GetUnit(1) --Wrapper.Unit#UNIT -- u1:Explode(500, 10) -- Recovery case. local case = flight.case -- Get old/current stack. local ostack = flight.flag -- Flight group name. local group = flight.group local groupname = flight.groupname -- Set new stack. flight.flag = nstack -- Current carrier position. local Carrier = self:GetCoordinate() -- Carrier heading. local hdg = self:GetHeading() -- Aircraft speed 274 knots TAS ~= 250 KIAS when orbiting the pattern. (Orbit expects m/s.) local speedOrbitMps = UTILS.KnotsToMps( 274 ) -- Orbit speed in km/h for waypoints. local speedOrbitKmh = UTILS.KnotsToKmph( 274 ) -- Aircraft speed 400 knots when transiting to holding zone. (Waypoint expects km/h.) local speedTransit = UTILS.KnotsToKmph( 370 ) local altitude local p0 -- Core.Point#COORDINATE local p1 -- Core.Point#COORDINATE local p2 -- Core.Point#COORDINATE -- Get altitude and positions. altitude, p1, p2 = self:_GetMarshalAltitude( nstack, case ) -- Waypoints array to be filled depending on case etc. local wp = {} -- If flight has not arrived in the holding zone, we guide it there. if not flight.holding then ---------------------- -- Route to Holding -- ---------------------- -- Debug info. self:T( self.lid .. string.format( "Guiding AI flight %s to marshal stack %d-->%d.", groupname, ostack, nstack ) ) -- Current position. Always good for as the first waypoint. wp[1] = group:GetCoordinate():WaypointAirTurningPoint( nil, speedTransit, {}, "Current Position" ) -- Task function when arriving at the holding zone. This will set flight.holding=true. local TaskArrivedHolding = flight.group:TaskFunction( "AIRBOSS._ReachedHoldingZone", self, flight ) -- Select case. if case == 1 then -- Initial point 7 NM and a bit port of carrier. local pE = Carrier:Translate( UTILS.NMToMeters( 7 ), hdg - 30 ):SetAltitude( altitude ) -- Entry point 5 NM port and slightly astern the boat. p0 = Carrier:Translate( UTILS.NMToMeters( 5 ), hdg - 135 ):SetAltitude( altitude ) -- Waypoint ahead of carrier's holding zone. wp[#wp + 1] = pE:WaypointAirTurningPoint( nil, speedTransit, { TaskArrivedHolding }, "Entering Case I Marshal Pattern" ) else -- Get correct radial depending on recovery case including offset. local radial = self:GetRadial( case, false, true ) -- Point in the middle of the race track and a 5 NM more port perpendicular. p0 = p2:Translate( UTILS.NMToMeters( 5 ), radial + 90, true ):Translate( UTILS.NMToMeters( 5 ), radial, true ) -- Entering Case II/III marshal pattern waypoint. wp[#wp + 1] = p0:WaypointAirTurningPoint( nil, speedTransit, { TaskArrivedHolding }, "Entering Case II/III Marshal Pattern" ) end else ------------------------ -- In Marshal Pattern -- ------------------------ -- Debug info. self:T( self.lid .. string.format( "Updating AI flight %s at marshal stack %d-->%d.", groupname, ostack, nstack ) ) -- Current position. Speed expected in km/h. wp[1] = group:GetCoordinate():WaypointAirTurningPoint( nil, speedOrbitKmh, {}, "Current Position" ) -- Create new waypoint 0.2 Nm ahead of current positon. p0 = group:GetCoordinate():Translate( UTILS.NMToMeters( 0.2 ), group:GetHeading(), true ) end -- Set orbit task. local taskorbit = group:TaskOrbit( p1, altitude, speedOrbitMps, p2 ) -- Orbit at waypoint. wp[#wp + 1] = p0:WaypointAirTurningPoint( nil, speedOrbitKmh, { taskorbit }, string.format( "Marshal Orbit Stack %d", nstack ) ) -- Debug markers. if self.Debug then p0:MarkToAll( "WP P0 " .. groupname ) p1:MarkToAll( "RT P1 " .. groupname ) p2:MarkToAll( "RT P2 " .. groupname ) end if respawn then -- This should clear the landing waypoints. -- Note: This resets the weapons and the fuel state. But not the units fortunately. -- Get group template. local Template = group:GetTemplate() -- Set route points. Template.route.points = wp -- Respawn the group. flight.group = group:Respawn( Template, true ) end -- Reinit waypoints. flight.group:WayPointInitialize( wp ) -- Route group. flight.group:Route( wp, 1 ) -- Trigger Marshal event. self:Marshal( flight ) end --- Tell AI to refuel. Either at the recovery tanker or at the nearest divert airfield. -- @param #AIRBOSS self -- @param #AIRBOSS.FlightGroup flight Flight group. function AIRBOSS:_RefuelAI( flight ) -- Waypoints array. local wp = {} -- Current speed. local CurrentSpeed = flight.group:GetVelocityKMH() -- Current positon. wp[#wp + 1] = flight.group:GetCoordinate():WaypointAirTurningPoint( nil, CurrentSpeed, {}, "Current position" ) -- Check if aircraft can be refueled. -- TODO: This should also depend on the tanker type AC. local refuelac=false local actype=flight.group:GetTypeName() if actype==AIRBOSS.AircraftCarrier.AV8B or actype==AIRBOSS.AircraftCarrier.F14A or actype==AIRBOSS.AircraftCarrier.F14B or actype==AIRBOSS.AircraftCarrier.F14A_AI or actype==AIRBOSS.AircraftCarrier.HORNET or actype==AIRBOSS.AircraftCarrier.RHINOE or actype==AIRBOSS.AircraftCarrier.RHINOF or actype==AIRBOSS.AircraftCarrier.GROWLER or actype==AIRBOSS.AircraftCarrier.FA18C or actype==AIRBOSS.AircraftCarrier.S3B or actype==AIRBOSS.AircraftCarrier.S3BTANKER then refuelac=true end -- Message. local text = "" -- Refuel or divert? if self.tanker and refuelac then -- Current Tanker position. local tankerpos = self.tanker.tanker:GetCoordinate() -- Task refueling. local TaskRefuel = flight.group:TaskRefueling() -- Task to go back to Marshal. local TaskMarshal = flight.group:TaskFunction( "AIRBOSS._TaskFunctionMarshalAI", self, flight ) -- Waypoint with tasks. wp[#wp + 1] = tankerpos:WaypointAirTurningPoint( nil, CurrentSpeed, { TaskRefuel, TaskMarshal }, "Refueling" ) -- Marshal Message. self:_MarshalCallGasAtTanker( flight.onboard ) else ------------------------------ -- Guide AI to divert field -- ------------------------------ -- Closest Airfield of the coalition. local divertfield = self:GetCoordinate():GetClosestAirbase( Airbase.Category.AIRDROME, self:GetCoalition() ) -- Handle case where there is no divert field of the own coalition and try neutral instead. if divertfield == nil then divertfield = self:GetCoordinate():GetClosestAirbase( Airbase.Category.AIRDROME, 0 ) end if divertfield then -- Coordinate. local divertcoord = divertfield:GetCoordinate() -- Landing waypoint. wp[#wp + 1] = divertcoord:WaypointAirLanding( UTILS.KnotsToKmph( 300 ), divertfield, {}, "Divert Field" ) -- Marshal Message. self:_MarshalCallGasAtDivert( flight.onboard, divertfield:GetName() ) -- Respawn! -- Get group template. local Template = flight.group:GetTemplate() -- Set route points. Template.route.points = wp -- Respawn the group. flight.group = flight.group:Respawn( Template, true ) else -- Set flight to refueling so this is not called again. self:E( self.lid .. string.format( "WARNING: No recovery tanker or divert field available for group %s.", flight.groupname ) ) flight.refueling = true return end end -- Reinit waypoints. flight.group:WayPointInitialize( wp ) -- Route group. flight.group:Route( wp, 1 ) -- Set refueling switch. flight.refueling = true end --- Tell AI to land on the carrier. -- @param #AIRBOSS self -- @param #AIRBOSS.FlightGroup flight Flight group. function AIRBOSS:_LandAI( flight ) -- Debug info. self:T( self.lid .. string.format( "Landing AI flight %s.", flight.groupname ) ) -- NOTE: Looks like the AI needs to approach at the "correct" speed. If they are too fast, they fly an unnecessary circle to bleed of speed first. -- Unfortunately, the correct speed depends on the aircraft type! -- Aircraft speed when flying the pattern. local Speed = UTILS.KnotsToKmph( 200 ) if flight.actype == AIRBOSS.AircraftCarrier.HORNET or flight.actype == AIRBOSS.AircraftCarrier.FA18C or flight.actype == AIRBOSS.AircraftCarrier.RHINOE or flight.actype == AIRBOSS.AircraftCarrier.RHINOF or flight.actype == AIRBOSS.AircraftCarrier.GROWLER then Speed = UTILS.KnotsToKmph( 200 ) elseif flight.actype == AIRBOSS.AircraftCarrier.E2D or flight.actype == AIRBOSS.AircraftCarrier.C2A then Speed = UTILS.KnotsToKmph( 150 ) elseif flight.actype == AIRBOSS.AircraftCarrier.F14A_AI or flight.actype == AIRBOSS.AircraftCarrier.F14A or flight.actype == AIRBOSS.AircraftCarrier.F14B then Speed = UTILS.KnotsToKmph( 175 ) elseif flight.actype == AIRBOSS.AircraftCarrier.S3B or flight.actype == AIRBOSS.AircraftCarrier.S3BTANKER then Speed = UTILS.KnotsToKmph( 140 ) end -- Carrier position. local Carrier = self:GetCoordinate() -- Carrier heading. local hdg = self:GetHeading() -- Waypoints array. local wp = {} local CurrentSpeed = flight.group:GetVelocityKMH() -- Current positon. wp[#wp + 1] = flight.group:GetCoordinate():WaypointAirTurningPoint( nil, CurrentSpeed, {}, "Current position" ) -- Altitude 800 ft. Looks like this works best. local alt = UTILS.FeetToMeters( 800 ) -- Landing waypoint 5 NM behind carrier at 2000 ft = 610 meters ASL. wp[#wp + 1] = Carrier:Translate( UTILS.NMToMeters( 4 ), hdg - 160 ):SetAltitude( alt ):WaypointAirLanding( Speed, self.airbase, nil, "Landing" ) -- wp[#wp+1]=Carrier:Translate(UTILS.NMToMeters(4), hdg-160):SetAltitude(alt):WaypointAirLandingReFu(Speed, self.airbase, nil, "Landing") -- wp[#wp+1]=self:GetCoordinate():Translate(UTILS.NMToMeters(3), hdg-160):SetAltitude(alt):WaypointAirTurningPoint(nil,Speed, {}, "Before Initial") ---WaypointAirLanding(Speed, self.airbase, nil, "Landing") -- wp[#wp+1]=self:GetCoordinate():WaypointAirLanding(Speed, self.airbase, nil, "Landing") -- Reinit waypoints. flight.group:WayPointInitialize( wp ) -- Route group. flight.group:Route( wp, 0 ) end --- Get marshal altitude and two positions of a counter-clockwise race track pattern. -- @param #AIRBOSS self -- @param #number stack Assigned stack number. Counting starts at one, i.e. stack=1 is the first stack. -- @param #number case Recovery case. Default is self.case. -- @return #number Holding altitude in meters. -- @return Core.Point#COORDINATE First race track coordinate. -- @return Core.Point#COORDINATE Second race track coordinate. function AIRBOSS:_GetMarshalAltitude( stack, case ) -- Stack <= 0. if stack <= 0 then return 0, nil, nil end -- Recovery case. case = case or self.case -- Carrier position. local Carrier = self:GetCoordinate() -- Altitude of first stack. Depends on recovery case. local angels0 local Dist local p1 = nil -- Core.Point#COORDINATE local p2 = nil -- Core.Point#COORDINATE -- Stack number. local nstack = stack - 1 if case == 1 then -- CASE I: Holding at 2000 ft on a circular pattern port of the carrier. Interval +1000 ft for next stack. angels0 = 2 -- Get true heading of carrier. local hdg = self.carrier:GetHeading() -- For CCW pattern: First point astern, second ahead of the carrier. -- First point over carrier. p1 = Carrier -- Second point 1.5 NM ahead. p2 = Carrier:Translate( UTILS.NMToMeters( 1.5 ), hdg ) -- Tarawa,LHA,LHD Delta patterns. if self.carriertype == AIRBOSS.CarrierType.INVINCIBLE or self.carriertype == AIRBOSS.CarrierType.HERMES or self.carriertype == AIRBOSS.CarrierType.TARAWA or self.carriertype == AIRBOSS.CarrierType.AMERICA or self.carriertype == AIRBOSS.CarrierType.JCARLOS or self.carriertype == AIRBOSS.CarrierType.CANBERRA then -- Pattern is directly overhead the carrier. p1 = Carrier:Translate( UTILS.NMToMeters( 1.0 ), hdg + 90 ) p2 = p1:Translate( 2.5, hdg ) end else -- CASE II/III: Holding at 6000 ft on a racetrack pattern astern the carrier. angels0 = 6 -- Distance: d=n*angels0+15 NM, so first stack is at 15+6=21 NM Dist = UTILS.NMToMeters( nstack + angels0 + 15 ) -- Get correct radial depending on recovery case including offset. local radial = self:GetRadial( case, false, true ) -- For CCW pattern: p1 further astern than p2. -- Length of the race track pattern. local l = UTILS.NMToMeters( 10 ) -- First point of race track pattern. p1 = Carrier:Translate( Dist + l, radial ) -- Second point. p2 = Carrier:Translate( Dist, radial ) end -- Pattern altitude. local altitude = UTILS.FeetToMeters( (nstack + angels0) * 1000 ) -- Set altitude of coordinate. p1:SetAltitude( altitude, true ) p2:SetAltitude( altitude, true ) return altitude, p1, p2 end --- Calculate an estimate of the charlie time of the player based on how many other aircraft are in the marshal or pattern queue before him. -- @param #AIRBOSS self -- @param #AIRBOSS.FlightGroup flightgroup Flight data. -- @return #number Charlie (abs) time in seconds. Or nil, if stack<0 or no recovery window will open. function AIRBOSS:_GetCharlieTime( flightgroup ) -- Get current stack of player. local stack = flightgroup.flag -- Flight is not in marshal stack. if stack <= 0 then return nil end -- Current abs time. local Tnow = timer.getAbsTime() -- Time the player has to spend in marshal stack until all lower stacks are emptied. local Tcharlie = 0 local Trecovery = 0 if self.recoverywindow then -- Time in seconds until the next recovery starts or 0 if window is already open. Trecovery = math.max( self.recoverywindow.START - Tnow, 0 ) else -- Set ~7 min if no future recovery window is defined. Otherwise radio call function crashes. Trecovery = 7 * 60 end -- Loop over flights currently in the marshal queue. for _, _flight in pairs( self.Qmarshal ) do local flight = _flight -- #AIRBOSS.FlightGroup -- Stack of marshal flight. local mstack = flight.flag -- Time to get to the marshal stack if not holding already. local Tarrive = 0 -- Minimum holding time per stack. local Tholding = 3 * 60 if stack > 0 and mstack > 0 and mstack <= stack then -- Check if flight is already holding or just on its way. if flight.holding == nil then -- Flight is on its way to the marshal stack. -- Coordinate of the holding zone. local holdingzone = self:_GetZoneHolding( flight.case, 1 ):GetCoordinate() -- Distance to holding zone. local d0 = holdingzone:Get2DDistance( flight.group:GetCoordinate() ) -- Current velocity. local v0 = flight.group:GetVelocityMPS() -- Time to get to the carrier. Tarrive = d0 / v0 self:T3( self.lid .. string.format( "Tarrive=%.1f seconds, Clock %s", Tarrive, UTILS.SecondsToClock( Tnow + Tarrive ) ) ) else -- Flight is already holding. -- Next in line. if mstack == 1 then -- Current holding time. flight.time stamp should be when entering holding or last time the stack collapsed. local tholding = timer.getAbsTime() - flight.time -- Deduce current holding time. Ensure that is >=0. Tholding = math.max( 3 * 60 - tholding, 0 ) end end -- This is the approx time needed to get to the pattern. If we are already there, it is the time until the recovery window opens or 0 if it is already open. local Tmin = math.max( Tarrive, Trecovery ) -- Charlie time + 2 min holding in stack 1. Tcharlie = math.max( Tmin, Tcharlie ) + Tholding end end -- Convert to abs time. Tcharlie = Tcharlie + Tnow -- Debug info. local text = string.format( "Charlie time for flight %s (%s) %s", flightgroup.onboard, flightgroup.groupname, UTILS.SecondsToClock( Tcharlie ) ) MESSAGE:New( text, 10, "DEBUG" ):ToAllIf( self.Debug ) self:T( self.lid .. text ) return Tcharlie end --- Add a flight group to the Marshal queue at a specific stack. Flight is informed via message. This fixes the recovery case to the current case ops in progress self.case). -- @param #AIRBOSS self -- @param #AIRBOSS.FlightGroup flight Flight group. -- @param #number stack Marshal stack. This (re-)sets the flag value. function AIRBOSS:_AddMarshalGroup( flight, stack ) -- Set flag value. This corresponds to the stack number which starts at 1. flight.flag = stack -- Set recovery case. flight.case = self.case -- Add to marshal queue. table.insert( self.Qmarshal, flight ) -- Pressure. local P = UTILS.hPa2inHg( self:GetCoordinate():GetPressure() ) -- Stack altitude. -- local alt=UTILS.MetersToFeet(self:_GetMarshalAltitude(stack, flight.case)) local alt = self:_GetMarshalAltitude( stack, flight.case ) -- Current BRC. local brc = self:GetBRC() -- If the carrier is supposed to turn into the wind, we take the wind coordinate. if self.recoverywindow and self.recoverywindow.WIND then brc = self:GetBRCintoWind(self.recoverywindow.SPEED) end -- Get charlie time estimate. flight.Tcharlie = self:_GetCharlieTime( flight ) -- Convert to clock string. local Ccharlie = UTILS.SecondsToClock( flight.Tcharlie ) -- Combined marshal call. self:_MarshalCallArrived( flight.onboard, flight.case, brc, alt, Ccharlie, P ) -- Hint about TACAN bearing. if self.TACANon and (not flight.ai) and flight.difficulty == AIRBOSS.Difficulty.EASY then -- Get inverse magnetic radial potential offset. local radial = self:GetRadial( flight.case, true, true, true ) if flight.case == 1 then -- For case 1 we want the BRC but above routine return FB. radial = self:GetBRC() end local text = string.format( "Select TACAN %03d°, channel %d%s (%s)", radial, self.TACANchannel, self.TACANmode, self.TACANmorse ) self:MessageToPlayer( flight, text, nil, "" ) end end --- Collapse marshal stack. -- @param #AIRBOSS self -- @param #AIRBOSS.FlightGroup flight Flight that left the marshal stack. -- @param #boolean nopattern If true, flight does not go to pattern. function AIRBOSS:_CollapseMarshalStack( flight, nopattern ) self:F2( { flight = flight, nopattern = nopattern } ) -- Recovery case of flight. local case = flight.case -- Stack of flight. local stack = flight.flag -- Check that stack > 0. if stack <= 0 then self:E( self.lid .. string.format( "ERROR: Flight %s is has stack value %d<0. Cannot collapse stack!", flight.groupname, stack ) ) return end -- Memorize time when stack collapsed. Should better depend on case but for now we assume there are no two different stacks Case I or II/III. self.Tcollapse = timer.getTime() -- Decrease flag values of all flight groups in marshal stack. for _, _flight in pairs( self.Qmarshal ) do local mflight = _flight -- #AIRBOSS.PlayerData -- Only collapse stack of which the flight left. CASE II/III stacks are not collapsed. if (case == 1 and mflight.case == 1) then -- or (case>1 and mflight.case>1) then -- Get current flag/stack value. local mstack = mflight.flag -- Only collapse stacks above the new pattern flight. if mstack > stack then -- TODO: Is this now right as we allow more flights per stack? -- Question is, does the stack collapse if the lower stack is completely empty or do aircraft descent if just one flight leaves. -- For now, assuming that the stack must be completely empty before the next higher AC are allowed to descent. local newstack = self:_GetFreeStack( mflight.ai, mflight.case, true ) -- Free stack has to be below. if newstack and newstack < mstack then -- Debug info. self:T( self.lid .. string.format( "Collapse Marshal: Flight %s (case %d) is changing marshal stack %d --> %d.", mflight.groupname, mflight.case, mstack, newstack ) ) if mflight.ai then -- Command AI to decrease stack. Flag is set in the routine. self:_MarshalAI( mflight, newstack ) else -- Decrease stack/flag. Human player needs to take care himself. mflight.flag = newstack -- Angels of new stack. local angels = self:_GetAngels( self:_GetMarshalAltitude( newstack, case ) ) -- Inform players. if mflight.difficulty ~= AIRBOSS.Difficulty.HARD then -- Send message to all non-pros that they can descent. local text = string.format( "descent to stack at Angels %d.", angels ) self:MessageToPlayer( mflight, text, "MARSHAL" ) end -- Set time stamp. mflight.time = timer.getAbsTime() -- Loop over section members. for _, _sec in pairs( mflight.section ) do local sec = _sec -- #AIRBOSS.PlayerData -- Also decrease flag for section members of flight. sec.flag = newstack -- Set new time stamp. sec.time = timer.getAbsTime() -- Inform section member. if sec.difficulty ~= AIRBOSS.Difficulty.HARD then local text = string.format( "descent to stack at Angels %d.", angels ) self:MessageToPlayer( sec, text, "MARSHAL" ) end end end end end end end if nopattern then -- Debug message. self:T( self.lid .. string.format( "Flight %s is leaving stack but not going to pattern.", flight.groupname ) ) else -- Debug message. local Tmarshal = UTILS.SecondsToClock( timer.getAbsTime() - flight.time ) self:T( self.lid .. string.format( "Flight %s is leaving marshal after %s and going pattern.", flight.groupname, Tmarshal ) ) -- Add flight to pattern queue. self:_AddFlightToPatternQueue( flight ) end -- Set flag to -1 (-1 is rather arbitrary but it should not be positive or -100 or -42). flight.flag = -1 -- New time stamp for time in pattern. flight.time = timer.getAbsTime() end --- Get next free Marshal stack. Depending on AI/human and recovery case. -- @param #AIRBOSS self -- @param #boolean ai If true, get a free stack for an AI flight group. -- @param #number case Recovery case. Default current (self) case in progress. -- @param #boolean empty Return lowest stack that is completely empty. -- @return #number Lowest free stack available for the given case or nil if all Case I stacks are taken. function AIRBOSS:_GetFreeStack( ai, case, empty ) -- Recovery case. case = case or self.case if case == 1 then return self:_GetFreeStack_Old( ai, case, empty ) end -- Max number of stacks available. local nmaxstacks = 100 if case == 1 then nmaxstacks = self.Nmaxmarshal end -- Assume up to two (human) flights per stack. All are free. local stack = {} for i = 1, nmaxstacks do stack[i] = self.NmaxStack -- Number of human flights per stack. end local nmax = 1 -- Loop over all flights in marshal stack. for _, _flight in pairs( self.Qmarshal ) do local flight = _flight -- #AIRBOSS.FlightGroup -- Check that the case is right. if flight.case == case then -- Get stack of flight. local n = flight.flag if n > nmax then nmax = n end if n > 0 then if flight.ai or flight.case > 1 then stack[n] = 0 -- AI get one stack on their own. Also CASE II/III get one stack each. else stack[n] = stack[n] - 1 end else self:E( string.format( "ERROR: Flight %s in marshal stack has stack value <= 0. Stack value is %d.", flight.groupname, n ) ) end end end local nfree = nil if stack[nmax] == 0 then -- Max occupied stack is completely full! if case == 1 then if nmax >= nmaxstacks then -- Already all Case I stacks are occupied ==> wait outside 10 NM zone. nfree = nil else -- Return next free stack. nfree = nmax + 1 end else -- Case II/III return next stack nfree = nmax + 1 end elseif stack[nmax] == self.NmaxStack then -- Max occupied stack is completely empty! This should happen only when there is no other flight in the marshal queue. self:E( self.lid .. string.format( "ERROR: Max occupied stack is empty. Should not happen! Nmax=%d, stack[nmax]=%d", nmax, stack[nmax] ) ) nfree = nmax else -- Max occupied stack is partly full. if ai or empty or case > 1 then nfree = nmax + 1 else nfree = nmax end end self:T( self.lid .. string.format( "Returning free stack %s", tostring( nfree ) ) ) return nfree end --- Get next free Marshal stack. Depending on AI/human and recovery case. -- @param #AIRBOSS self -- @param #boolean ai If true, get a free stack for an AI flight group. -- @param #number case Recovery case. Default current (self) case in progress. -- @param #boolean empty Return lowest stack that is completely empty. -- @return #number Lowest free stack available for the given case or nil if all Case I stacks are taken. function AIRBOSS:_GetFreeStack_Old( ai, case, empty ) -- Recovery case. case = case or self.case -- Max number of stacks available. local nmaxstacks = 100 if case == 1 then nmaxstacks = self.Nmaxmarshal end -- Assume up to two (human) flights per stack. All are free. local stack = {} for i = 1, nmaxstacks do stack[i] = self.NmaxStack -- Number of human flights per stack. end -- Loop over all flights in marshal stack. for _, _flight in pairs( self.Qmarshal ) do local flight = _flight -- #AIRBOSS.FlightGroup -- Check that the case is right. if flight.case == case then -- Get stack of flight. local n = flight.flag if n > 0 then if flight.ai or flight.case > 1 then stack[n] = 0 -- AI get one stack on their own. Also CASE II/III get one stack each. else stack[n] = stack[n] - 1 end else self:E( string.format( "ERROR: Flight %s in marshal stack has stack value <= 0. Stack value is %d.", flight.groupname, n ) ) end end end -- Loop over stacks and check which one has a place left. local nfree = nil for i = 1, nmaxstacks do self:T2( self.lid .. string.format( "FF Stack[%d]=%d", i, stack[i] ) ) if ai or empty or case > 1 then -- AI need the whole stack. if stack[i] == self.NmaxStack then nfree = i return i end else -- Human players only need one free spot. if stack[i] > 0 then nfree = i return i end end end return nfree end --- Get number of (airborne) units in a flight. -- @param #AIRBOSS self -- @param #AIRBOSS.FlightGroup flight The flight group. -- @param #boolean onground If true, include units on the ground. By default only airborne units are counted. -- @return #number Number of units in flight including section members. -- @return #number Number of units in flight excluding section members. -- @return #number Number of section members. function AIRBOSS:_GetFlightUnits( flight, onground ) -- Default is only airborne. local inair = true if onground == true then inair = false end --- Count units of a group which are alive and in the air. local function countunits( _group, inair ) local group = _group -- Wrapper.Group#GROUP local units = group:GetUnits() local n = 0 if units then for _, _unit in pairs( units ) do local unit = _unit -- Wrapper.Unit#UNIT if unit and unit:IsAlive() then if inair then -- Only count units in air. if unit:InAir() then self:T2( self.lid .. string.format( "Unit %s is in AIR", unit:GetName() ) ) n = n + 1 end else -- Count units in air or on the ground. n = n + 1 end end end end return n end -- Count units of the group itself (alive units in air). local nunits = countunits( flight.group, inair ) -- Count section members. local nsection = 0 for _, sec in pairs( flight.section ) do local secflight = sec -- #AIRBOSS.PlayerData -- Count alive units in air. nsection = nsection + countunits( secflight.group, inair ) end return nunits + nsection, nunits, nsection end --- Get number of groups and units in queue, which are alive and airborne. In units we count the section members as well. -- @param #AIRBOSS self -- @param #table queue The queue. Can be self.flights, self.Qmarshal or self.Qpattern. -- @param #number case (Optional) Only count flights, which are in a specific recovery case. Note that you can use case=23 for flights that are either in Case II or III. By default all groups/units regardless of case are counted. -- @return #number Total number of flight groups in queue. -- @return #number Total number of aircraft in queue since each flight group can contain multiple aircraft. function AIRBOSS:_GetQueueInfo( queue, case ) local ngroup = 0 local Nunits = 0 -- Loop over flight groups. for _, _flight in pairs( queue ) do local flight = _flight -- #AIRBOSS.FlightGroup -- Check if a specific case was requested. if case then ------------------------------------------------------------------------ -- Only count specific case with special 23 = CASE II and III combined. ------------------------------------------------------------------------ if (flight.case == case) or (case == 23 and (flight.case == 2 or flight.case == 3)) then -- Number of total units, units in flight and section members ALIVE and AIRBORNE. local ntot, nunits, nsection = self:_GetFlightUnits( flight ) -- Add up total unit number. Nunits = Nunits + ntot -- Increase group count. if ntot > 0 then ngroup = ngroup + 1 end end else --------------------------------------------------------------------------- -- No specific case requested. Count all groups & units in selected queue. --------------------------------------------------------------------------- -- Number of total units, units in flight and section members ALIVE and AIRBORNE. local ntot, nunits, nsection = self:_GetFlightUnits( flight ) -- Add up total unit number. Nunits = Nunits + ntot -- Increase group count. if ntot > 0 then ngroup = ngroup + 1 end end end return ngroup, Nunits end --- Print holding queue. -- @param #AIRBOSS self -- @param #table queue Queue to print. -- @param #string name Queue name. function AIRBOSS:_PrintQueue( queue, name ) -- local nqueue=#queue local Nqueue, nqueue = self:_GetQueueInfo( queue ) local text = string.format( "%s Queue N=%d (#%d), n=%d:", name, Nqueue, #queue, nqueue ) if #queue == 0 then text = text .. " empty." else for i, _flight in pairs( queue ) do local flight = _flight -- #AIRBOSS.FlightGroup local clock = UTILS.SecondsToClock( timer.getAbsTime() - flight.time ) local case = flight.case local stack = flight.flag local fuel = flight.group:GetFuelMin() * 100 local ai = tostring( flight.ai ) local lead = flight.seclead local Nsec = #flight.section local actype = self:_GetACNickname( flight.actype ) local onboard = flight.onboard local holding = tostring( flight.holding ) -- Airborne units. local _, nunits, nsec = self:_GetFlightUnits( flight, false ) -- Text. text = text .. string.format( "\n[%d] %s*%d (%s): lead=%s (%d/%d), onboard=%s, flag=%d, case=%d, time=%s, fuel=%d, ai=%s, holding=%s", i, flight.groupname, nunits, actype, lead, nsec, Nsec, onboard, stack, case, clock, fuel, ai, holding ) if stack > 0 then local alt = UTILS.MetersToFeet( self:_GetMarshalAltitude( stack, case ) ) text = text .. string.format( " stackalt=%d ft", alt ) end for j, _element in pairs( flight.elements ) do local element = _element -- #AIRBOSS.FlightElement text = text .. string.format( "\n (%d) %s (%s): ai=%s, ballcall=%s, recovered=%s", j, element.onboard, element.unitname, tostring( element.ai ), tostring( element.ballcall ), tostring( element.recovered ) ) end end end self:T( self.lid .. text ) end ---------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- -- FLIGHT & PLAYER functions ---------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- --- Create a new flight group. Usually when a flight appears in the CCA. -- @param #AIRBOSS self -- @param Wrapper.Group#GROUP group Aircraft group. -- @return #AIRBOSS.FlightGroup Flight group. function AIRBOSS:_CreateFlightGroup( group ) -- Debug info. self:T( self.lid .. string.format( "Creating new flight for group %s of aircraft type %s.", group:GetName(), group:GetTypeName() ) ) -- New flight. local flight = {} -- #AIRBOSS.FlightGroup -- Check if not already in flights if not self:_InQueue( self.flights, group ) then -- Flight group name local groupname = group:GetName() local human, playername = self:_IsHuman( group ) -- Queue table item. flight.group = group flight.groupname = group:GetName() flight.nunits = #group:GetUnits() flight.time = timer.getAbsTime() flight.dist0 = group:GetCoordinate():Get2DDistance( self:GetCoordinate() ) flight.flag = -100 flight.ai = not human flight.actype = group:GetTypeName() flight.onboardnumbers = self:_GetOnboardNumbers( group ) flight.seclead = flight.group:GetUnit( 1 ):GetName() -- Sec lead is first unitname of group but player name for players. flight.section = {} flight.ballcall = false flight.refueling = false flight.holding = nil flight.name = flight.group:GetUnit( 1 ):GetName() -- Will be overwritten in _Newplayer with player name if human player in the group. -- Note, this should be re-set elsewhere! flight.case = self.case -- Flight elements. local text = string.format( "Flight elements of group %s:", flight.groupname ) flight.elements = {} local units = group:GetUnits() for i, _unit in pairs( units ) do local unit = _unit -- Wrapper.Unit#UNIT local element = {} -- #AIRBOSS.FlightElement element.unit = unit element.unitname = unit:GetName() element.onboard = flight.onboardnumbers[element.unitname] element.ballcall = false element.ai = not self:_IsHumanUnit( unit ) element.recovered = nil text = text .. string.format( "\n[%d] %s onboard #%s, AI=%s", i, element.unitname, tostring( element.onboard ), tostring( element.ai ) ) table.insert( flight.elements, element ) end self:T( self.lid .. text ) -- Onboard if flight.ai then local onboard = flight.onboardnumbers[flight.seclead] flight.onboard = onboard else flight.onboard = self:_GetOnboardNumberPlayer( group ) end -- Add to known flights. table.insert( self.flights, flight ) else self:E( self.lid .. string.format( "ERROR: Flight group %s already exists in self.flights!", group:GetName() ) ) return nil end return flight end --- Initialize player data after birth event of player unit. -- @param #AIRBOSS self -- @param #string unitname Name of the player unit. -- @return #AIRBOSS.PlayerData Player data. function AIRBOSS:_NewPlayer( unitname ) -- Get player unit and name. local playerunit, playername = self:_GetPlayerUnitAndName( unitname ) if playerunit and playername then -- Get group. local group = playerunit:GetGroup() -- Player data. local playerData -- #AIRBOSS.PlayerData -- Create a flight group for the player. playerData = self:_CreateFlightGroup( group ) -- Nil check. if playerData then -- Player unit, client and callsign. playerData.unit = playerunit playerData.unitname = unitname playerData.name = playername playerData.callsign = playerData.unit:GetCallsign() playerData.client = CLIENT:FindByName( unitname, nil, true ) playerData.seclead = playername -- Number of passes done by player in this slot. playerData.passes = 0 -- playerData.passes or 0 -- Messages for player. playerData.messages = {} -- Debriefing tables. playerData.lastdebrief = playerData.lastdebrief or {} -- Attitude monitor. playerData.attitudemonitor = false -- Trap sheet save. if playerData.trapon == nil then playerData.trapon = self.trapsheet end -- Set difficulty level. playerData.difficulty = playerData.difficulty or self.defaultskill -- Subtitles of player. if playerData.subtitles == nil then playerData.subtitles = true end -- Show step hints. if playerData.showhints == nil then if playerData.difficulty == AIRBOSS.Difficulty.HARD then playerData.showhints = false else playerData.showhints = true end end -- Points rewarded. playerData.points = {} -- Init stuff for this round. playerData = self:_InitPlayer( playerData ) -- Init player data. self.players[playername] = playerData -- Init player grades table if necessary. self.playerscores[playername] = self.playerscores[playername] or {} -- Welcome player message. if self.welcome then self:MessageToPlayer( playerData, string.format( "Welcome, %s %s!", playerData.difficulty, playerData.name ), string.format( "AIRBOSS %s", self.alias ), "", 5 ) end end -- Return player data table. return playerData end return nil end --- Initialize player data by (re-)setting parmeters to initial values. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data. -- @param #string step (Optional) New player step. Default UNDEFINED. -- @return #AIRBOSS.PlayerData Initialized player data. function AIRBOSS:_InitPlayer( playerData, step ) self:T( self.lid .. string.format( "Initializing player data for %s callsign %s.", playerData.name, playerData.callsign ) ) playerData.step = step or AIRBOSS.PatternStep.UNDEFINED playerData.groove = {} playerData.debrief = {} playerData.trapsheet = {} playerData.warning = nil playerData.holding = nil playerData.refueling = false playerData.valid = false playerData.lig = false playerData.wop = false playerData.waveoff = false playerData.wofd = false playerData.owo = false playerData.boltered = false playerData.hover = false playerData.stable = false playerData.landed = false playerData.Tlso = timer.getTime() playerData.Tgroove = nil playerData.TIG0 = nil playerData.wire = nil playerData.flag = -100 playerData.debriefschedulerID = nil -- Set us up on final if group name contains "Groove". But only for the first pass. if playerData.group:GetName():match( "Groove" ) and playerData.passes == 0 then self:MessageToPlayer( playerData, "Group name contains \"Groove\". Happy groove testing." ) playerData.attitudemonitor = true playerData.step = AIRBOSS.PatternStep.FINAL self:_AddFlightToPatternQueue( playerData ) self.dTstatus = 0.1 end return playerData end --- Get flight from group in a queue. -- @param #AIRBOSS self -- @param Wrapper.Group#GROUP group Group that will be removed from queue. -- @param #table queue The queue from which the group will be removed. -- @return #AIRBOSS.FlightGroup Flight group or nil. -- @return #number Queue index or nil. function AIRBOSS:_GetFlightFromGroupInQueue( group, queue ) if group then -- Group name local name = group:GetName() -- Loop over all flight groups in queue for i, _flight in pairs( queue ) do local flight = _flight -- #AIRBOSS.FlightGroup if flight.groupname == name then return flight, i end end self:T2( self.lid .. string.format( "WARNING: Flight group %s could not be found in queue.", name ) ) end self:T2( self.lid .. string.format( "WARNING: Flight group could not be found in queue. Group is nil!" ) ) return nil, nil end --- Get element in flight. -- @param #AIRBOSS self -- @param #string unitname Name of the unit. -- @return #AIRBOSS.FlightElement Element of the flight or nil. -- @return #number Element index or nil. -- @return #AIRBOSS.FlightGroup The Flight group or nil function AIRBOSS:_GetFlightElement( unitname ) -- Get the unit. local unit = UNIT:FindByName( unitname ) -- Check if unit exists. if unit then -- Get flight element from all flights. local flight = self:_GetFlightFromGroupInQueue( unit:GetGroup(), self.flights ) -- Check if fight exists. if flight then -- Loop over all elements in flight group. for i, _element in pairs( flight.elements ) do local element = _element -- #AIRBOSS.FlightElement if element.unit:GetName() == unitname then return element, i, flight end end self:T2( self.lid .. string.format( "WARNING: Flight element %s could not be found in flight group.", unitname, flight.groupname ) ) end end return nil, nil, nil end --- Get element in flight. -- @param #AIRBOSS self -- @param #string unitname Name of the unit. -- @return #boolean If true, element could be removed or nil otherwise. function AIRBOSS:_RemoveFlightElement( unitname ) -- Get table index. local element, idx, flight = self:_GetFlightElement( unitname ) if idx then table.remove( flight.elements, idx ) return true else self:T( "WARNING: Flight element could not be removed from flight group. Index=nil!" ) return nil end end --- Check if a group is in a queue. -- @param #AIRBOSS self -- @param #table queue The queue to check. -- @param Wrapper.Group#GROUP group The group to be checked. -- @return #boolean If true, group is in the queue. False otherwise. function AIRBOSS:_InQueue( queue, group ) local name = group:GetName() for _, _flight in pairs( queue ) do local flight = _flight -- #AIRBOSS.FlightGroup if name == flight.groupname then return true end end return false end --- Remove dead flight groups from all queues. -- @param #AIRBOSS self -- @param Wrapper.Group#GROUP group Aircraft group. -- @return #AIRBOSS.FlightGroup Flight group. function AIRBOSS:_RemoveDeadFlightGroups() -- Remove dead flights from all flights table. for i = #self.flight, 1, -1 do local flight = self.flights[i] -- #AIRBOSS.FlightGroup if not flight.group:IsAlive() then self:T( string.format( "Removing dead flight group %s from ALL flights table.", flight.groupname ) ) table.remove( self.flights, i ) end end -- Remove dead flights from Marhal queue table. for i = #self.Qmarshal, 1, -1 do local flight = self.Qmarshal[i] -- #AIRBOSS.FlightGroup if not flight.group:IsAlive() then self:T( string.format( "Removing dead flight group %s from Marshal Queue table.", flight.groupname ) ) table.remove( self.Qmarshal, i ) end end -- Remove dead flights from Pattern queue table. for i = #self.Qpattern, 1, -1 do local flight = self.Qpattern[i] -- #AIRBOSS.FlightGroup if not flight.group:IsAlive() then self:T( string.format( "Removing dead flight group %s from Pattern Queue table.", flight.groupname ) ) table.remove( self.Qpattern, i ) end end end --- Get the lead flight group of a flight group. -- @param #AIRBOSS self -- @param #AIRBOSS.FlightGroup flight Flight group to check. -- @return #AIRBOSS.FlightGroup Flight group of the leader or flight itself if no other leader. function AIRBOSS:_GetLeadFlight( flight ) -- Init. local lead = flight -- Only human players can be section leads of other players. if flight.name ~= flight.seclead then lead = self.players[flight.seclead] end return lead end --- Check if all elements of a flight were recovered. This also checks potential section members. -- If so, flight is removed from the queue. -- @param #AIRBOSS self -- @param #AIRBOSS.FlightGroup flight Flight group to check. -- @return #boolean If true, all elements landed. function AIRBOSS:_CheckSectionRecovered( flight ) -- Nil check. if flight == nil then return true end -- Get the lead flight first, so that we can also check all section members. local lead = self:_GetLeadFlight( flight ) -- Check all elements of the lead flight group. for _, _element in pairs( lead.elements ) do local element = _element -- #AIRBOSS.FlightElement if not element.recovered then return false end end -- Now check all section members, if any. for _, _section in pairs( lead.section ) do local sectionmember = _section -- #AIRBOSS.FlightGroup -- Check all elements of the secmember flight group. for _, _element in pairs( sectionmember.elements ) do local element = _element -- #AIRBOSS.FlightElement if not element.recovered then return false end end end -- Remove lead flight from pattern queue. It is this flight who is added to the queue. self:_RemoveFlightFromQueue( self.Qpattern, lead ) -- Just for now, check if it is in other queues as well. if self:_InQueue( self.Qmarshal, lead.group ) then self:E( self.lid .. string.format( "ERROR: lead flight group %s should not be in marshal queue", lead.groupname ) ) self:_RemoveFlightFromMarshalQueue( lead, true ) end -- Just for now, check if it is in other queues as well. if self:_InQueue( self.Qwaiting, lead.group ) then self:E( self.lid .. string.format( "ERROR: lead flight group %s should not be in pattern queue", lead.groupname ) ) self:_RemoveFlightFromQueue( self.Qwaiting, lead ) end return true end --- Add flight to pattern queue and set recoverd to false for all elements of the flight and its section members. -- @param #AIRBOSS self -- @param #AIRBOSS.FlightGroup Flight group of element. function AIRBOSS:_AddFlightToPatternQueue( flight ) -- Add flight to table. table.insert( self.Qpattern, flight ) -- Set flag to -1 (-1 is rather arbitrary but it should not be positive or -100 or -42). flight.flag = -1 -- New time stamp for time in pattern. flight.time = timer.getAbsTime() -- Init recovered switch. flight.recovered = false for _, elem in pairs( flight.elements ) do elem.recoverd = false end -- Set recovered for all section members. for _, sec in pairs( flight.section ) do -- Set flag and timestamp for section members sec.flag = -1 sec.time = timer.getAbsTime() for _, elem in pairs( sec.elements ) do elem.recoverd = false end end end --- Sets flag recovered=true for a flight element, which was successfully recovered (landed). -- @param #AIRBOSS self -- @param Wrapper.Unit#UNIT unit The aircraft unit that was recovered. -- @return #AIRBOSS.FlightGroup Flight group of element. function AIRBOSS:_RecoveredElement( unit ) -- Get element of flight. local element, idx, flight = self:_GetFlightElement( unit:GetName() ) -- #AIRBOSS.FlightElement -- Nil check. Could be if a helo landed or something else we dont know! if element then element.recovered = true end return flight end --- Remove a flight group from the Marshal queue. Marshal stack is collapsed, too, if flight was in the queue. Waiting flights are send to marshal. -- @param #AIRBOSS self -- @param #AIRBOSS.FlightGroup flight Flight group that will be removed from queue. -- @param #boolean nopattern If true, flight is NOT going to landing pattern. -- @return #boolean True, flight was removed or false otherwise. -- @return #number Table index of the flight in the Marshal queue. function AIRBOSS:_RemoveFlightFromMarshalQueue( flight, nopattern ) -- Remove flight from marshal queue if it is in. local removed, idx = self:_RemoveFlightFromQueue( self.Qmarshal, flight ) -- Collapse marshal stack if flight was removed. if removed then -- Flight is not holding any more. flight.holding = nil -- Collapse marshal stack if flight was removed. self:_CollapseMarshalStack( flight, nopattern ) -- Stacks are only limited for Case I. if flight.case == 1 and #self.Qwaiting > 0 then -- Next flight in line waiting. local nextflight = self.Qwaiting[1] -- #AIRBOSS.FlightGroup -- Get free stack. local freestack = self:_GetFreeStack( nextflight.ai ) -- Send next flight to marshal stack. if nextflight.ai then -- Send AI to Marshal Stack. self:_MarshalAI( nextflight, freestack ) else -- Send player to Marshal stack. self:_MarshalPlayer( nextflight, freestack ) end -- Remove flight from waiting queue. self:_RemoveFlightFromQueue( self.Qwaiting, nextflight ) end end return removed, idx end --- Remove a flight group from a queue. -- @param #AIRBOSS self -- @param #table queue The queue from which the group will be removed. -- @param #AIRBOSS.FlightGroup flight Flight group that will be removed from queue. -- @return #boolean True, flight was in Queue and removed. False otherwise. -- @return #number Table index of removed queue element or nil. function AIRBOSS:_RemoveFlightFromQueue( queue, flight ) -- Loop over all flights in group. for i, _flight in pairs( queue ) do local qflight = _flight -- #AIRBOSS.FlightGroup -- Check for name. if qflight.groupname == flight.groupname then self:T( self.lid .. string.format( "Removing flight group %s from queue.", flight.groupname ) ) table.remove( queue, i ) return true, i end end return false, nil end --- Remove a unit and its element from a flight group (e.g. when landed) and update all queues if the whole flight group is gone. -- @param #AIRBOSS self -- @param Wrapper.Unit#UNIT unit The unit to be removed. function AIRBOSS:_RemoveUnitFromFlight( unit ) -- Check if unit exists. if unit and unit:IsInstanceOf( "UNIT" ) then -- Get group. local group = unit:GetGroup() -- Check if group exists. if group then -- Get flight. local flight = self:_GetFlightFromGroupInQueue( group, self.flights ) -- Check if flight exists. if flight then -- Remove element from flight group. local removed = self:_RemoveFlightElement( unit:GetName() ) if removed then -- Get number of units (excluding section members). For AI only those that are still in air as we assume once they landed, they are out of the game. local _, nunits = self:_GetFlightUnits( flight, not flight.ai ) -- Number of flight elements still left. local nelements = #flight.elements -- Debug info. self:T( self.lid .. string.format( "Removed unit %s: nunits=%d, nelements=%d", unit:GetName(), nunits, nelements ) ) -- Check if no units are left. if nunits == 0 or nelements == 0 then -- Remove flight from all queues. self:_RemoveFlight( flight ) end end end end end end --- Remove a flight, which is a member of a section, from this section. -- @param #AIRBOSS self -- @param #AIRBOSS.FlightGroup flight The flight to be removed from the section function AIRBOSS:_RemoveFlightFromSection( flight ) -- First check if player is not the lead. if flight.name ~= flight.seclead then -- Remove this flight group from the section of the leader. local lead = self.players[flight.seclead] -- #AIRBOSS.FlightGroup if lead then for i, sec in pairs( lead.section ) do local sectionmember = sec -- #AIRBOSS.FlightGroup if sectionmember.name == flight.name then table.remove( lead.section, i ) break end end end end end --- Update section if a flight is removed. -- If removed flight is member of a section, he is removed for the leaders section. -- If removed flight is the section lead, we try to find a new leader. -- @param #AIRBOSS self -- @param #AIRBOSS.FlightGroup flight The flight to be removed. function AIRBOSS:_UpdateFlightSection( flight ) -- Check if this player is the leader of a section. if flight.seclead == flight.name then -------------------- -- Section Leader -- -------------------- -- This player is the leader ==> We need a new one. if #flight.section >= 1 then -- New leader. local newlead = flight.section[1] -- #AIRBOSS.FlightGroup newlead.seclead = newlead.name -- Adjust new section members. for i = 2, #flight.section do local member = flight.section[i] -- #AIRBOSS.FlightGroup -- Add remaining members new leaders table. table.insert( newlead.section, member ) -- Set new section lead of member. member.seclead = newlead.name end end -- Flight section empty flight.section = {} else -------------------- -- Section Member -- -------------------- -- Remove flight from its leaders section. self:_RemoveFlightFromSection( flight ) end end --- Remove a flight from Marshal, Pattern and Waiting queues. If flight is in Marhal queue, the above stack is collapsed. -- Also set player step to undefined if applicable or remove human flight if option *completely* is true. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData flight The flight to be removed. -- @param #boolean completely If true, also remove human flight from all flights table. function AIRBOSS:_RemoveFlight( flight, completely ) self:F( self.lid .. string.format( "Removing flight %s, ai=%s completely=%s.", tostring( flight.groupname ), tostring( flight.ai ), tostring( completely ) ) ) -- Remove flight from all queues. self:_RemoveFlightFromMarshalQueue( flight, true ) self:_RemoveFlightFromQueue( self.Qpattern, flight ) self:_RemoveFlightFromQueue( self.Qwaiting, flight ) self:_RemoveFlightFromQueue( self.Qspinning, flight ) -- Check if player or AI if flight.ai then -- Remove AI flight completely. Pure AI flights have no sections and cannot be members. self:_RemoveFlightFromQueue( self.flights, flight ) else -- Remove all grades until a final grade is reached. local grades = self.playerscores[flight.name] if grades and #grades > 0 then while #grades > 0 and grades[#grades].finalscore == nil do table.remove( grades, #grades ) end end -- Check if flight should be completely removed, e.g. after the player died or simply left the slot. if completely then -- Update flight section. Remove flight from section or find new section leader if flight was the lead. self:_UpdateFlightSection( flight ) -- Remove completely. self:_RemoveFlightFromQueue( self.flights, flight ) -- Remove player from players table. local playerdata = self.players[flight.name] if playerdata then self:T( self.lid .. string.format( "Removing player %s completely.", flight.name ) ) self.players[flight.name] = nil end -- Remove flight. flight = nil else -- Set player step to undefined. self:_SetPlayerStep( flight, AIRBOSS.PatternStep.UNDEFINED ) -- Also set this for the section members as they are in the same boat. for _, sectionmember in pairs( flight.section ) do self:_SetPlayerStep( sectionmember, AIRBOSS.PatternStep.UNDEFINED ) -- Also remove section member in case they are in the spinning queue. self:_RemoveFlightFromQueue( self.Qspinning, sectionmember ) end -- What if flight is member of a section. His status is now undefined. Should he be removed from the section? -- I think yes, if he pulls the trigger. self:_RemoveFlightFromSection( flight ) end end end ---------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- -- Player Status ---------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- --- Check current player status. -- @param #AIRBOSS self function AIRBOSS:_CheckPlayerStatus() -- Loop over all players. for _playerName, _playerData in pairs( self.players ) do local playerData = _playerData -- #AIRBOSS.PlayerData if playerData then -- Player unit. local unit = playerData.unit -- Check if unit is alive. if unit and unit:IsAlive() then -- Check if player is in carrier controlled area (zone with R=50 NM around the carrier). -- TODO: This might cause problems if the CCA is set to be very small! if unit:IsInZone( self.zoneCCA ) then -- Display aircraft attitude and other parameters as message text. if playerData.attitudemonitor then self:_AttitudeMonitor( playerData ) end -- Check distance to other flights. self:_CheckPlayerPatternDistance( playerData ) -- Foul deck check. self:_CheckFoulDeck( playerData ) -- Check current step. if playerData.step == AIRBOSS.PatternStep.UNDEFINED then -- Status undefined. -- local time=timer.getAbsTime() -- local clock=UTILS.SecondsToClock(time) -- self:T3(string.format("Player status undefined. Waiting for next step. Time %s", clock)) elseif playerData.step == AIRBOSS.PatternStep.REFUELING then -- Nothing to do here at the moment. elseif playerData.step == AIRBOSS.PatternStep.SPINNING then -- Player is spinning. self:_Spinning( playerData ) elseif playerData.step == AIRBOSS.PatternStep.HOLDING then -- CASE I/II/III: In holding pattern. self:_Holding( playerData ) elseif playerData.step == AIRBOSS.PatternStep.WAITING then -- CASE I: Waiting outside 10 NM zone for next free Marshal stack. self:_Waiting( playerData ) elseif playerData.step == AIRBOSS.PatternStep.COMMENCING then -- CASE I/II/III: New approach. self:_Commencing( playerData, true ) elseif playerData.step == AIRBOSS.PatternStep.BOLTER then -- CASE I/II/III: Bolter pattern. self:_BolterPattern( playerData ) elseif playerData.step == AIRBOSS.PatternStep.PLATFORM then -- CASE II/III: Player has reached 5k "Platform". self:_Platform( playerData ) elseif playerData.step == AIRBOSS.PatternStep.ARCIN then -- Case II/III if offset. self:_ArcInTurn( playerData ) elseif playerData.step == AIRBOSS.PatternStep.ARCOUT then -- Case II/III if offset. self:_ArcOutTurn( playerData ) elseif playerData.step == AIRBOSS.PatternStep.DIRTYUP then -- CASE III: Player has descended to 1200 ft and is going level from now on. self:_DirtyUp( playerData ) elseif playerData.step == AIRBOSS.PatternStep.BULLSEYE then -- CASE III: Player has intercepted the glide slope and should follow "Bullseye" (ICLS). self:_Bullseye( playerData ) elseif playerData.step == AIRBOSS.PatternStep.INITIAL then -- CASE I/II: Player is at the initial position entering the landing pattern. self:_Initial( playerData ) elseif playerData.step == AIRBOSS.PatternStep.BREAKENTRY then -- CASE I/II: Break entry. self:_BreakEntry( playerData ) elseif playerData.step == AIRBOSS.PatternStep.EARLYBREAK then -- CASE I/II: Early break. self:_Break( playerData, AIRBOSS.PatternStep.EARLYBREAK ) elseif playerData.step == AIRBOSS.PatternStep.LATEBREAK then -- CASE I/II: Late break. self:_Break( playerData, AIRBOSS.PatternStep.LATEBREAK ) elseif playerData.step == AIRBOSS.PatternStep.ABEAM then -- CASE I/II: Abeam position. self:_Abeam( playerData ) elseif playerData.step == AIRBOSS.PatternStep.NINETY then -- CASE:I/II: Check long down wind leg. self:_CheckForLongDownwind( playerData ) -- At the ninety. self:_Ninety( playerData ) elseif playerData.step == AIRBOSS.PatternStep.WAKE then -- CASE I/II: In the wake. self:_Wake( playerData ) elseif playerData.step == AIRBOSS.PatternStep.EMERGENCY then -- Emergency landing. Player pos is not checked. self:_Final( playerData, true ) elseif playerData.step == AIRBOSS.PatternStep.FINAL then -- CASE I/II: Turn to final and enter the groove. self:_Final( playerData ) elseif playerData.step == AIRBOSS.PatternStep.GROOVE_XX or playerData.step == AIRBOSS.PatternStep.GROOVE_IM or playerData.step == AIRBOSS.PatternStep.GROOVE_IC or playerData.step == AIRBOSS.PatternStep.GROOVE_AR or playerData.step == AIRBOSS.PatternStep.GROOVE_AL or playerData.step == AIRBOSS.PatternStep.GROOVE_LC or playerData.step == AIRBOSS.PatternStep.GROOVE_IW then -- CASE I/II: In the groove. self:_Groove( playerData ) elseif playerData.step == AIRBOSS.PatternStep.DEBRIEF then -- Debriefing in 5 seconds. -- SCHEDULER:New(nil, self._Debrief, {self, playerData}, 5) playerData.debriefschedulerID = self:ScheduleOnce( 5, self._Debrief, self, playerData ) -- Undefined status. playerData.step = AIRBOSS.PatternStep.UNDEFINED else -- Error, unknown step! self:E( self.lid .. string.format( "ERROR: Unknown player step %s. Please report!", tostring( playerData.step ) ) ) end -- Check if player missed a step during Case II/III and allow him to enter the landing pattern. self:_CheckMissedStepOnEntry( playerData ) else self:T2( self.lid .. "WARNING: Player unit not inside the CCA!" ) end else -- Unit not alive. self:T( self.lid .. "WARNING: Player unit is not alive!" ) end end end end --- Checks if a player is in the pattern queue and has missed a step in Case II/III approach. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data. function AIRBOSS:_CheckMissedStepOnEntry( playerData ) -- Conditions to be met: Case II/III, in pattern queue, flag!=42 (will be set to 42 at the end if player missed a step). local rightcase = playerData.case > 1 local rightqueue = self:_InQueue( self.Qpattern, playerData.group ) local rightflag = playerData.flag ~= -42 -- Steps that the player could have missed during Case II/III. local step = playerData.step local missedstep = step == AIRBOSS.PatternStep.PLATFORM or step == AIRBOSS.PatternStep.ARCIN or step == AIRBOSS.PatternStep.ARCOUT or step == AIRBOSS.PatternStep.DIRTYUP -- Check if player is about to enter the initial or bullseye zones and maybe has missed a step in the pattern. if rightcase and rightqueue and rightflag then -- Get right zone. local zone = nil if playerData.case == 2 and missedstep then zone = self:_GetZoneInitial( playerData.case ) elseif playerData.case == 3 and missedstep then zone = self:_GetZoneBullseye( playerData.case ) end -- Zone only exists if player is not at the initial or bullseye step. if zone then -- Check if player is in initial or bullseye zone. local inzone = playerData.unit:IsInZone( zone ) -- Relative heading to carrier direction. local relheading = self:_GetRelativeHeading( playerData.unit, false ) -- Check if player is in zone and flying roughly in the right direction. if inzone and math.abs( relheading ) < 60 then -- Player is in one of the initial zones short before the landing pattern. local text = string.format( "you missed an important step in the pattern!\nYour next step would have been %s.", playerData.step ) self:MessageToPlayer( playerData, text, "AIRBOSS", nil, 5 ) if playerData.case == 2 then -- Set next step to initial. playerData.step = AIRBOSS.PatternStep.INITIAL elseif playerData.case == 3 then -- Set next step to bullseye. playerData.step = AIRBOSS.PatternStep.BULLSEYE end -- Set flag value to -42. This is the value to ensure that this routine is not called again! playerData.flag = -42 end end end end --- Set time in the groove for player. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data. function AIRBOSS:_SetTimeInGroove( playerData ) -- Set time in the groove if playerData.TIG0 then playerData.Tgroove = timer.getTime() - playerData.TIG0 else playerData.Tgroove = 999 end end --- Get time in the groove of player. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data. -- @return #number Player's time in groove in seconds. function AIRBOSS:_GetTimeInGroove( playerData ) local Tgroove = 999 -- Get time in the groove. if playerData.TIG0 then Tgroove = timer.getTime() - playerData.TIG0 end return Tgroove end ------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- -- EVENT functions ------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- --- Airboss event handler for event birth. -- @param #AIRBOSS self -- @param Core.Event#EVENTDATA EventData function AIRBOSS:OnEventBirth( EventData ) self:F3( { eventbirth = EventData } ) -- Nil checks. if EventData == nil then self:E( self.lid .. "ERROR: EventData=nil in event BIRTH!" ) self:E( EventData ) return end if EventData.IniUnit == nil and (not EventData.IniObjectCategory == Object.Category.STATIC) then self:E( self.lid .. "ERROR: EventData.IniUnit=nil in event BIRTH!" ) self:E( EventData ) return end if EventData.IniObjectCategory ~= Object.Category.UNIT then return end local _unitName = EventData.IniUnitName local _unit, _playername = self:_GetPlayerUnitAndName( _unitName ) self:T( self.lid .. "BIRTH: unit = " .. tostring( EventData.IniUnitName ) ) self:T( self.lid .. "BIRTH: group = " .. tostring( EventData.IniGroupName ) ) self:T( self.lid .. "BIRTH: player = " .. tostring( _playername ) ) if _unit and _playername then local _uid = _unit:GetID() local _group = _unit:GetGroup() local _callsign = _unit:GetCallsign() -- Debug output. local text = string.format( "Pilot %s, callsign %s entered unit %s of group %s.", _playername, _callsign, _unitName, _group:GetName() ) self:T( self.lid .. text ) MESSAGE:New( text, 5 ):ToAllIf( self.Debug ) -- Check if aircraft type the player occupies is carrier capable. local rightaircraft = self:_IsCarrierAircraft( _unit ) if rightaircraft == false then local text = string.format( "Player aircraft type %s not supported by AIRBOSS class.", _unit:GetTypeName() ) MESSAGE:New( text, 30 ):ToAllIf( self.Debug ) self:T2( self.lid .. text ) return end -- Check that coalition of the carrier and aircraft match. if self:GetCoalition() ~= _unit:GetCoalition() then local text = string.format( "Player entered aircraft of other coalition." ) MESSAGE:New( text, 30 ):ToAllIf( self.Debug ) self:T( self.lid .. text ) return end -- Add Menu commands. self:_AddF10Commands( _unitName ) -- Delaying the new player for a second, because AI units of the flight would not be registered correctly. -- SCHEDULER:New(nil, self._NewPlayer, {self, _unitName}, 1) self:ScheduleOnce( 1, self._NewPlayer, self, _unitName ) end end --- Airboss event handler for event land. -- @param #AIRBOSS self -- @param Core.Event#EVENTDATA EventData function AIRBOSS:OnEventRunwayTouch( EventData ) self:F3( { eventland = EventData } ) -- Nil checks. if EventData == nil then self:E( self.lid .. "ERROR: EventData=nil in event LAND!" ) self:E( EventData ) return end if EventData.IniUnit == nil then self:E( self.lid .. "ERROR: EventData.IniUnit=nil in event LAND!" ) self:E( EventData ) return end -- Get unit name that landed. local _unitName = EventData.IniUnitName -- Check if this was a player. local _unit, _playername = self:_GetPlayerUnitAndName( _unitName ) -- Debug output. self:T( self.lid .. "LAND: unit = " .. tostring( EventData.IniUnitName ) ) self:T( self.lid .. "LAND: group = " .. tostring( EventData.IniGroupName ) ) self:T( self.lid .. "LAND: player = " .. tostring( _playername ) ) -- This would be the closest airbase. local airbase = EventData.Place -- Nil check for airbase. Crashed as player gave me no airbase. if airbase == nil then return end -- Get airbase name. local airbasename = tostring( airbase:GetName() ) -- Check if aircraft landed on the right airbase. if airbasename == self.airbase:GetName() then -- Stern coordinate at the rundown. local stern = self:_GetSternCoord() -- Polygon zone close around the carrier. local zoneCarrier = self:_GetZoneCarrierBox() -- Check if player or AI landed. if _unit and _playername then ------------------------- -- Human Player landed -- ------------------------- -- Get info. local _uid = _unit:GetID() local _group = _unit:GetGroup() local _callsign = _unit:GetCallsign() -- Debug output. local text = string.format( "Player %s, callsign %s unit %s (ID=%d) of group %s landed at airbase %s", _playername, _callsign, _unitName, _uid, _group:GetName(), airbasename ) self:T( self.lid .. text ) MESSAGE:New( text, 5, "DEBUG" ):ToAllIf( self.Debug ) -- Player data. local playerData = self.players[_playername] -- #AIRBOSS.PlayerData -- Check if playerData is okay. if playerData == nil then self:E( self.lid .. string.format( "ERROR: playerData nil in landing event. unit=%s player=%s", tostring( _unitName ), tostring( _playername ) ) ) return end -- Check that player landed on the carrier. if _unit:IsInZone( zoneCarrier ) then -- Check if this was a valid approach. if not playerData.valid then -- Player missed at least one step in the pattern. local text = string.format( "you missed at least one important step in the pattern!\nYour next step would have been %s.\nThis pass is INVALID.", playerData.step ) self:MessageToPlayer( playerData, text, "AIRBOSS", nil, 30, true, 5 ) -- Clear queues just in case. self:_RemoveFlightFromMarshalQueue( playerData, true ) self:_RemoveFlightFromQueue( self.Qpattern, playerData ) self:_RemoveFlightFromQueue( self.Qwaiting, playerData ) self:_RemoveFlightFromQueue( self.Qspinning, playerData ) -- Reinitialize player data. self:_InitPlayer( playerData ) return end -- Check if player already landed. We dont need a second time. if playerData.landed then self:E( self.lid .. string.format( "Player %s just landed a second time.", _playername ) ) else -- We did land. playerData.landed = true -- Switch attitude monitor off if on. playerData.attitudemonitor = false -- Coordinate at landing event. local coord = playerData.unit:GetCoordinate() -- Get distances relative to local X, Z, rho, phi = self:_GetDistances( _unit ) -- Landing distance wrt to stern position. local dist = coord:Get2DDistance( stern ) -- Debug mark of player landing coord. if self.Debug and false then -- Debug mark of player landing coord. local lp = coord:MarkToAll( "Landing coord." ) coord:SmokeGreen() end -- Set time in the groove of player. self:_SetTimeInGroove( playerData ) -- Debug text. local text = string.format( "Player %s AC type %s landed at dist=%.1f m. Tgroove=%.1f sec.", playerData.name, playerData.actype, dist, self:_GetTimeInGroove( playerData ) ) text = text .. string.format( " X=%.1f m, Z=%.1f m, rho=%.1f m.", X, Z, rho ) self:T( self.lid .. text ) -- Check carrier type. if self.carriertype == AIRBOSS.CarrierType.INVINCIBLE or self.carriertype == AIRBOSS.CarrierType.HERMES or self.carriertype == AIRBOSS.CarrierType.TARAWA or self.carriertype == AIRBOSS.CarrierType.AMERICA or self.carriertype == AIRBOSS.CarrierType.JCARLOS or self.carriertype == AIRBOSS.CarrierType.CANBERRA then -- Power "Idle". self:RadioTransmission( self.LSORadio, self.LSOCall.IDLE, false, 1, nil, true ) -- Next step debrief. self:_SetPlayerStep( playerData, AIRBOSS.PatternStep.DEBRIEF ) else -- Next step undefined until we know more. self:_SetPlayerStep( playerData, AIRBOSS.PatternStep.UNDEFINED ) -- Call trapped function in 1 second to make sure we did not bolter. -- SCHEDULER:New(nil, self._Trapped, {self, playerData}, 1) self:ScheduleOnce( 1, self._Trapped, self, playerData ) end end else -- Handle case where player did not land on the carrier. -- Well, I guess, he leaves the slot or ejects. Both should be handled. if playerData then self:E( self.lid .. string.format( "Player %s did not land in carrier box zone. Maybe in the water near the carrier?", playerData.name ) ) end end else -------------------- -- AI unit landed -- -------------------- if self.carriertype ~= AIRBOSS.CarrierType.INVINCIBLE or self.carriertype ~= AIRBOSS.CarrierType.HERMES or self.carriertype ~= AIRBOSS.CarrierType.TARAWA or self.carriertype ~= AIRBOSS.CarrierType.AMERICA or self.carriertype ~= AIRBOSS.CarrierType.JCARLOS or self.carriertype ~= AIRBOSS.CarrierType.CANBERRA then -- Coordinate at landing event local coord = EventData.IniUnit:GetCoordinate() -- Debug mark of player landing coord. local dist = coord:Get2DDistance( self:GetCoordinate() ) -- Get wire local wire = self:_GetWire( coord, 0 ) -- Aircraft type. local _type = EventData.IniUnit:GetTypeName() -- Debug text. local text = string.format( "AI unit %s of type %s landed at dist=%.1f m. Trapped wire=%d.", _unitName, _type, dist, wire ) self:T( self.lid .. text ) end -- AI always lands ==> remove unit from flight group and queues. local flight = self:_RecoveredElement( EventData.IniUnit ) -- Check if all were recovered. If so update pattern queue. self:_CheckSectionRecovered( flight ) end end end --- Airboss event handler for event that a unit shuts down its engines. -- @param #AIRBOSS self -- @param Core.Event#EVENTDATA EventData function AIRBOSS:OnEventEngineShutdown( EventData ) self:F3( { eventengineshutdown = EventData } ) -- Nil checks. if EventData == nil then self:E( self.lid .. "ERROR: EventData=nil in event ENGINESHUTDOWN!" ) self:E( EventData ) return end if EventData.IniUnit == nil then self:E( self.lid .. "ERROR: EventData.IniUnit=nil in event ENGINESHUTDOWN!" ) self:E( EventData ) return end local _unitName = EventData.IniUnitName local _unit, _playername = self:_GetPlayerUnitAndName( _unitName ) self:T3( self.lid .. "ENGINESHUTDOWN: unit = " .. tostring( EventData.IniUnitName ) ) self:T3( self.lid .. "ENGINESHUTDOWN: group = " .. tostring( EventData.IniGroupName ) ) self:T3( self.lid .. "ENGINESHUTDOWN: player = " .. tostring( _playername ) ) if _unit and _playername then -- Debug message. self:T( self.lid .. string.format( "Player %s shut down its engines!", _playername ) ) else -- Debug message. self:T( self.lid .. string.format( "AI unit %s shut down its engines!", _unitName ) ) -- Get flight. local flight = self:_GetFlightFromGroupInQueue( EventData.IniGroup, self.flights ) -- Only AI flights. if flight and flight.ai then -- Check if all elements were recovered. local recovered = self:_CheckSectionRecovered( flight ) -- Despawn group and completely remove flight. if recovered then self:T( self.lid .. string.format( "AI group %s completely recovered. Despawning group after engine shutdown event as requested in 5 seconds.", tostring( EventData.IniGroupName ) ) ) -- Remove flight. self:_RemoveFlight( flight ) -- Check if this is a tanker or AWACS associated with the carrier. local istanker = self.tanker and self.tanker.tanker:GetName() == EventData.IniGroupName local isawacs = self.awacs and self.awacs.tanker:GetName() == EventData.IniGroupName -- Destroy group if desired. Recovery tankers have their own logic for despawning. if self.despawnshutdown and not (istanker or isawacs) then EventData.IniGroup:Destroy( nil, 5 ) end end end end end --- Airboss event handler for event that a unit takes off. -- @param #AIRBOSS self -- @param Core.Event#EVENTDATA EventData function AIRBOSS:OnEventTakeoff( EventData ) self:F3( { eventtakeoff = EventData } ) -- Nil checks. if EventData == nil then self:E( self.lid .. "ERROR: EventData=nil in event TAKEOFF!" ) self:E( EventData ) return end if EventData.IniUnit == nil then self:E( self.lid .. "ERROR: EventData.IniUnit=nil in event TAKEOFF!" ) self:E( EventData ) return end local _unitName = EventData.IniUnitName local _unit, _playername = self:_GetPlayerUnitAndName( _unitName ) self:T3( self.lid .. "TAKEOFF: unit = " .. tostring( EventData.IniUnitName ) ) self:T3( self.lid .. "TAKEOFF: group = " .. tostring( EventData.IniGroupName ) ) self:T3( self.lid .. "TAKEOFF: player = " .. tostring( _playername ) ) -- Airbase. local airbase = EventData.Place -- Airbase name. local airbasename = "unknown" if airbase then airbasename = airbase:GetName() end -- Check right airbase. if airbasename == self.airbase:GetName() then if _unit and _playername then -- Debug message. self:T( self.lid .. string.format( "Player %s took off at %s!", _playername, airbasename ) ) else -- Debug message. self:T2( self.lid .. string.format( "AI unit %s took off at %s!", _unitName, airbasename ) ) -- Get flight. local flight = self:_GetFlightFromGroupInQueue( EventData.IniGroup, self.flights ) if flight then -- Set ballcall and recoverd status. for _, elem in pairs( flight.elements ) do local element = elem -- #AIRBOSS.FlightElement element.ballcall = false element.recovered = nil end end end end end --- Airboss event handler for event crash. -- @param #AIRBOSS self -- @param Core.Event#EVENTDATA EventData function AIRBOSS:OnEventCrash( EventData ) self:F3( { eventcrash = EventData } ) -- Nil checks. if EventData == nil then self:E( self.lid .. "ERROR: EventData=nil in event CRASH!" ) self:E( EventData ) return end if EventData.IniUnit == nil then self:E( self.lid .. "ERROR: EventData.IniUnit=nil in event CRASH!" ) self:E( EventData ) return end local _unitName = EventData.IniUnitName local _unit, _playername = self:_GetPlayerUnitAndName( _unitName ) self:T3( self.lid .. "CRASH: unit = " .. tostring( EventData.IniUnitName ) ) self:T3( self.lid .. "CRASH: group = " .. tostring( EventData.IniGroupName ) ) self:T3( self.lid .. "CARSH: player = " .. tostring( _playername ) ) if _unit and _playername then -- Debug message. self:T( self.lid .. string.format( "Player %s crashed!", _playername ) ) -- Get player flight. local flight = self.players[_playername] -- Remove flight completely from all queues and collapse marshal if necessary. -- This also updates the section, if any and removes any unfinished gradings of the player. if flight then self:_RemoveFlight( flight, true ) end else -- Debug message. self:T2( self.lid .. string.format( "AI unit %s crashed!", EventData.IniUnitName ) ) -- Remove unit from flight and queues. self:_RemoveUnitFromFlight( EventData.IniUnit ) end end --- Airboss event handler for event Ejection. -- @param #AIRBOSS self -- @param Core.Event#EVENTDATA EventData function AIRBOSS:OnEventEjection( EventData ) self:F3( { eventland = EventData } ) -- Nil checks. if EventData == nil then self:E( self.lid .. "ERROR: EventData=nil in event EJECTION!" ) self:E( EventData ) return end if EventData.IniUnit == nil then self:E( self.lid .. "ERROR: EventData.IniUnit=nil in event EJECTION!" ) self:E( EventData ) return end local _unitName = EventData.IniUnitName local _unit, _playername = self:_GetPlayerUnitAndName( _unitName ) self:T3( self.lid .. "EJECT: unit = " .. tostring( EventData.IniUnitName ) ) self:T3( self.lid .. "EJECT: group = " .. tostring( EventData.IniGroupName ) ) self:T3( self.lid .. "EJECT: player = " .. tostring( _playername ) ) if _unit and _playername then self:T( self.lid .. string.format( "Player %s ejected!", _playername ) ) -- Get player flight. local flight = self.players[_playername] -- Remove flight completely from all queues and collapse marshal if necessary. if flight then self:_RemoveFlight( flight, true ) end else -- Debug message. self:T( self.lid .. string.format( "AI unit %s ejected!", EventData.IniUnitName ) ) -- Remove element/unit from flight group and from all queues if no elements alive. self:_RemoveUnitFromFlight( EventData.IniUnit ) -- What could happen is, that another element has landed (recovered) already and this one crashes. -- This would mean that the flight would not be deleted from the queue ==> Check if section recovered. local flight = self:_GetFlightFromGroupInQueue( EventData.IniGroup, self.flights ) self:_CheckSectionRecovered( flight ) end end --- Airboss event handler for event REMOVEUNIT. -- @param #AIRBOSS self -- @param Core.Event#EVENTDATA EventData function AIRBOSS:OnEventRemoveUnit( EventData ) self:F3( { eventland = EventData } ) -- Nil checks. if EventData == nil then self:E( self.lid .. "ERROR: EventData=nil in event REMOVEUNIT!" ) self:E( EventData ) return end if EventData.IniUnit == nil then self:E( self.lid .. "ERROR: EventData.IniUnit=nil in event REMOVEUNIT!" ) self:E( EventData ) return end local _unitName = EventData.IniUnitName local _unit, _playername = self:_GetPlayerUnitAndName( _unitName ) self:T3( self.lid .. "EJECT: unit = " .. tostring( EventData.IniUnitName ) ) self:T3( self.lid .. "EJECT: group = " .. tostring( EventData.IniGroupName ) ) self:T3( self.lid .. "EJECT: player = " .. tostring( _playername ) ) if _unit and _playername then self:T( self.lid .. string.format( "Player %s removed!", _playername ) ) -- Get player flight. local flight = self.players[_playername] -- Remove flight completely from all queues and collapse marshal if necessary. if flight then self:_RemoveFlight( flight, true ) end else -- Debug message. self:T( self.lid .. string.format( "AI unit %s removed!", EventData.IniUnitName ) ) -- Remove element/unit from flight group and from all queues if no elements alive. self:_RemoveUnitFromFlight( EventData.IniUnit ) -- What could happen is, that another element has landed (recovered) already and this one crashes. -- This would mean that the flight would not be deleted from the queue ==> Check if section recovered. local flight = self:_GetFlightFromGroupInQueue( EventData.IniGroup, self.flights ) self:_CheckSectionRecovered( flight ) end end --- Airboss event handler for event player leave unit. -- @param #AIRBOSS self -- @param Core.Event#EVENTDATA EventData -- function AIRBOSS:OnEventPlayerLeaveUnit(EventData) function AIRBOSS:_PlayerLeft( EventData ) self:F3( { eventleave = EventData } ) -- Nil checks. if EventData == nil then self:E( self.lid .. "ERROR: EventData=nil in event PLAYERLEFTUNIT!" ) self:E( EventData ) return end if EventData.IniUnit == nil then self:E( self.lid .. "ERROR: EventData.IniUnit=nil in event PLAYERLEFTUNIT!" ) self:E( EventData ) return end local _unitName = EventData.IniUnitName local _unit, _playername = self:_GetPlayerUnitAndName( _unitName ) self:T3( self.lid .. "PLAYERLEAVEUNIT: unit = " .. tostring( EventData.IniUnitName ) ) self:T3( self.lid .. "PLAYERLEAVEUNIT: group = " .. tostring( EventData.IniGroupName ) ) self:T3( self.lid .. "PLAYERLEAVEUNIT: player = " .. tostring( _playername ) ) if _unit and _playername then -- Debug info. self:T( self.lid .. string.format( "Player %s left unit %s!", _playername, _unitName ) ) -- Get player flight. local flight = self.players[_playername] -- Remove flight completely from all queues and collapse marshal if necessary. if flight then self:_RemoveFlight( flight, true ) end end end --- Airboss event function handling the mission end event. -- Handles the case when the mission is ended. -- @param #AIRBOSS self -- @param Core.Event#EVENTDATA EventData Event data. function AIRBOSS:OnEventMissionEnd( EventData ) self:T3( self.lid .. "Mission Ended" ) end ------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- -- PATTERN functions ------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- --- Spinning -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data. function AIRBOSS:_Spinning( playerData ) -- Early break. local SpinIt = {} SpinIt.name = "Spinning" SpinIt.Xmin = -UTILS.NMToMeters( 6 ) -- Not more than 5 NM behind the boat. SpinIt.Xmax = UTILS.NMToMeters( 5 ) -- Not more than 5 NM in front of the boat. SpinIt.Zmin = -UTILS.NMToMeters( 6 ) -- Not more than 5 NM port. SpinIt.Zmax = UTILS.NMToMeters( 2 ) -- Not more than 3 NM starboard. SpinIt.LimitXmin = -100 -- 100 meters behind the boat SpinIt.LimitXmax = nil SpinIt.LimitZmin = -UTILS.NMToMeters( 1 ) -- 1 NM port SpinIt.LimitZmax = nil -- Get distances between carrier and player unit (parallel and perpendicular to direction of movement of carrier) local X, Z, rho, phi = self:_GetDistances( playerData.unit ) -- Check if we are in front of the boat (diffX > 0). if self:_CheckLimits( X, Z, SpinIt ) then -- Player is "de-spinned". Should go to initial again. self:_SetPlayerStep( playerData, AIRBOSS.PatternStep.INITIAL ) -- Remove player from spinning queue. self:_RemoveFlightFromQueue( self.Qspinning, playerData ) end end --- Waiting outside 10 NM zone for free Marshal stack. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data. function AIRBOSS:_Waiting( playerData ) -- Create 10 NM zone around the carrier. local radius = UTILS.NMToMeters( 10 ) local zone = ZONE_RADIUS:New( "Carrier 10 NM Zone", self.carrier:GetVec2(), radius ) -- Check if player is inside 10 NM radius of the carrier. local inzone = playerData.unit:IsInZone( zone ) -- Time player is waiting. local Twaiting = timer.getAbsTime() - playerData.time -- Warning if player is inside the zone. if inzone and Twaiting > 3 * 60 and not playerData.warning then local text = string.format( "You are supposed to wait outside the 10 NM zone." ) self:MessageToPlayer( playerData, text, "AIRBOSS" ) playerData.warning = true end -- Reset warning. if inzone == false and playerData.warning == true then playerData.warning = nil end end --- Holding. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data. function AIRBOSS:_Holding( playerData ) -- Player unit and flight. local unit = playerData.unit -- Current stack. local stack = playerData.flag -- Check for reported error. if stack <= 0 then local text = string.format( "ERROR: player %s in step %s is holding but has stack=%s (<=0)", playerData.name, playerData.step, tostring( stack ) ) self:E( self.lid .. text ) end --------------------------- -- Holding Pattern Check -- --------------------------- -- Pattern altitude. local patternalt = self:_GetMarshalAltitude( stack, playerData.case ) -- Player altitude. local playeralt = unit:GetAltitude() -- Get holding zone of player. local zoneHolding = self:_GetZoneHolding( playerData.case, stack ) -- Nil check. if zoneHolding == nil then self:E( self.lid .. "ERROR: zoneHolding is nil!" ) self:E( { playerData = playerData } ) return end -- Check if player is in holding zone. local inholdingzone = unit:IsInZone( zoneHolding ) -- Altitude difference between player and assigned stack. local altdiff = playeralt - patternalt -- Acceptable altitude depending on player skill. local altgood = UTILS.FeetToMeters( 500 ) if playerData.difficulty == AIRBOSS.Difficulty.HARD then -- Pros can be expected to be within +-200 ft. altgood = UTILS.FeetToMeters( 200 ) elseif playerData.difficulty == AIRBOSS.Difficulty.NORMAL then -- Normal guys should be within +-350 ft. altgood = UTILS.FeetToMeters( 350 ) elseif playerData.difficulty == AIRBOSS.Difficulty.EASY then -- Students should be within +-500 ft. altgood = UTILS.FeetToMeters( 500 ) end -- When back to good altitude = 50%. local altback = altgood * 0.5 -- Check if stack just collapsed and give the player one minute to change the altitude. local justcollapsed = false if self.Tcollapse then -- Time since last stack change. local dT = timer.getTime() - self.Tcollapse -- TODO: check if this works. -- local dT=timer.getAbsTime()-playerData.time -- Check if less then 90 seconds. if dT <= 90 then justcollapsed = true end end -- Check if altitude is acceptable. local goodalt = math.abs( altdiff ) < altgood -- Angels. local angels = self:_GetAngels( patternalt ) -- XXX: Check if player is flying counter clockwise. AOB<0. -- Message text. local text = "" -- Different cases if playerData.holding == true then -- Player was in holding zone last time we checked. if inholdingzone then -- Player is still in holding zone. self:T3( "Player is still in the holding zone. Good job." ) else -- Player left the holding zone. text = text .. string.format( "You just left the holding zone. Watch your numbers!" ) playerData.holding = false end -- Altitude check if stack not just collapsed. if not justcollapsed then if altdiff > altgood then -- Issue warning for being too high. if not playerData.warning then text = text .. string.format( "You left your assigned altitude. Descent to angels %d.", angels ) playerData.warning = true end elseif altdiff < -altgood then -- Issue warning for being too low. if not playerData.warning then text = text .. string.format( "You left your assigned altitude. Climb to angels %d.", angels ) playerData.warning = true end end end -- Back to assigned altitude. if playerData.warning and math.abs( altdiff ) <= altback then text = text .. string.format( "Altitude is looking good again." ) playerData.warning = nil end elseif playerData.holding == false then -- Player left holding zone if inholdingzone then -- Player is back in the holding zone. text = text .. string.format( "You are back in the holding zone. Now stay there!" ) playerData.holding = true else -- Player is still outside the holding zone. self:T3( "Player still outside the holding zone. What are you doing man?!" ) end elseif playerData.holding == nil then -- Player did not entered the holding zone yet. if inholdingzone then -- Player arrived in holding zone. playerData.holding = true -- Inform player. text = text .. string.format( "You arrived at the holding zone." ) -- Feedback on altitude. if goodalt then text = text .. string.format( " Altitude is good." ) else if altdiff < 0 then text = text .. string.format( " But you're too low." ) else text = text .. string.format( " But you're too high." ) end text = text .. string.format( "\nCurrently assigned altitude is %d ft.", UTILS.MetersToFeet( patternalt ) ) playerData.warning = true end else -- Player did not yet arrive in holding zone. self:T3( "Waiting for player to arrive in the holding zone." ) end end -- Send message. if playerData.showhints then self:MessageToPlayer( playerData, text, "MARSHAL" ) end end --- Commence approach. This step initializes the player data. Section members are also set to commence. Next step depends on recovery case: -- -- * Case 1: Initial -- * Case 2/3: Platform -- -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data. -- @param #boolean zonecheck If true, zone is checked before player is released. function AIRBOSS:_Commencing( playerData, zonecheck ) -- Check for auto commence if zonecheck then -- Get auto commence zone. local zoneCommence = self:_GetZoneCommence( playerData.case, playerData.flag ) -- Check if unit is in the zone. local inzone = playerData.unit:IsInZone( zoneCommence ) -- Skip the rest if not in the zone yet. if not inzone then -- Friendly reminder. if timer.getAbsTime() - playerData.time > 180 then self:_MarshalCallClearedForRecovery( playerData.onboard, playerData.case ) playerData.time = timer.getAbsTime() end -- Skip the rest. return end end -- Remove flight from Marshal queue. If flight was in queue, stack is collapsed and flight added to the pattern queue. self:_RemoveFlightFromMarshalQueue( playerData ) -- Initialize player data for new approach. self:_InitPlayer( playerData ) -- Commencing message to player only. if playerData.difficulty ~= AIRBOSS.Difficulty.HARD then -- Text local text = "" -- Positive response. if playerData.case == 1 then text = text .. "Proceed to initial." else text = text .. "Descent to platform." if playerData.difficulty == AIRBOSS.Difficulty.EASY and playerData.showhints then text = text .. " VSI 4000 ft/min until you reach 5000 ft." end end -- Message to player. self:MessageToPlayer( playerData, text, "MARSHAL" ) end -- Next step: depends on case recovery. local nextstep if playerData.case == 1 then -- CASE I: Player has to fly to the initial which is 3 NM DME astern of the boat. nextstep = AIRBOSS.PatternStep.INITIAL else -- CASE II/III: Player has to start the descent at 4000 ft/min to the platform at 5k ft. nextstep = AIRBOSS.PatternStep.PLATFORM end -- Next step hint. self:_SetPlayerStep( playerData, nextstep ) -- Commence section members as well but dont check the zone. for i, _flight in pairs( playerData.section ) do local flight = _flight -- #AIRBOSS.PlayerData self:_Commencing( flight, false ) end end --- Start pattern when player enters the initial zone in case I/II recoveries. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data table. -- @return #boolean True if player is in the initial zone. function AIRBOSS:_Initial( playerData ) -- Check if player is in initial zone and entering the CASE I pattern. local inzone = playerData.unit:IsInZone( self:_GetZoneInitial( playerData.case ) ) -- Relative heading to carrier direction. local relheading = self:_GetRelativeHeading( playerData.unit, false ) -- altitude of player in feet. local altitude = playerData.unit:GetAltitude() -- Check if player is in zone and flying roughly in the right direction. if inzone and math.abs( relheading ) < 60 and altitude <= self.initialmaxalt then -- Send message for normal and easy difficulty. if playerData.showhints then -- Inform player. local hint = string.format( "Initial" ) -- Hook down for students. if playerData.difficulty == AIRBOSS.Difficulty.EASY and playerData.actype ~= AIRBOSS.AircraftCarrier.AV8B then if playerData.actype == AIRBOSS.AircraftCarrier.F14A or playerData.actype == AIRBOSS.AircraftCarrier.F14B then hint = hint .. " - Hook down, SAS on, Wing Sweep 68°!" else hint = hint .. " - Hook down!" end end self:MessageToPlayer( playerData, hint, "MARSHAL" ) end -- Next step: Break entry. self:_SetPlayerStep( playerData, AIRBOSS.PatternStep.BREAKENTRY ) return true end return false end --- Check if player is in CASE II/III approach corridor. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data table. function AIRBOSS:_CheckCorridor( playerData ) -- Check if player is in valid zone local validzone = self:_GetZoneCorridor( playerData.case ) -- Check if we are inside the moving zone. local invalid = playerData.unit:IsNotInZone( validzone ) -- Issue warning. if invalid and (not playerData.warning) then self:MessageToPlayer( playerData, "you left the approach corridor!", "AIRBOSS" ) playerData.warning = true end -- Back in zone. if (not invalid) and playerData.warning then self:MessageToPlayer( playerData, "you're back in the approach corridor.", "AIRBOSS" ) playerData.warning = false end end --- Platform at 5k ft for case II/III recoveries. Descent at 2000 ft/min. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data table. function AIRBOSS:_Platform( playerData ) -- Check if player left or got back to the approach corridor. self:_CheckCorridor( playerData ) -- Check if we are inside the moving zone. local inzone = playerData.unit:IsInZone( self:_GetZonePlatform( playerData.case ) ) -- Check if we are in zone. if inzone then -- Hint for player about altitude, AoA etc. self:_PlayerHint( playerData ) -- Next step: depends. local nextstep if math.abs( self.holdingoffset ) > 0 and playerData.case > 1 then -- Turn to BRC (case II) or FB (case III). nextstep = AIRBOSS.PatternStep.ARCIN else if playerData.case == 2 then -- Case II: Initial zone then Case I recovery. nextstep = AIRBOSS.PatternStep.INITIAL elseif playerData.case == 3 then -- CASE III: Dirty up. nextstep = AIRBOSS.PatternStep.DIRTYUP end end -- Next step hint. self:_SetPlayerStep( playerData, nextstep ) end end --- Arc in turn for case II/III recoveries. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data table. function AIRBOSS:_ArcInTurn( playerData ) -- Check if player left or got back to the approach corridor. self:_CheckCorridor( playerData ) -- Check if we are inside the moving zone. local inzone = playerData.unit:IsInZone( self:_GetZoneArcIn( playerData.case ) ) if inzone then -- Hint for player about altitude, AoA etc. self:_PlayerHint( playerData ) -- Next step: Arc Out Turn. self:_SetPlayerStep( playerData, AIRBOSS.PatternStep.ARCOUT ) end end --- Arc out turn for case II/III recoveries. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data table. function AIRBOSS:_ArcOutTurn( playerData ) -- Check if player left or got back to the approach corridor. self:_CheckCorridor( playerData ) -- Check if we are inside the moving zone. local inzone = playerData.unit:IsInZone( self:_GetZoneArcOut( playerData.case ) ) if inzone then -- Hint for player about altitude, AoA etc. self:_PlayerHint( playerData ) -- Next step: local nextstep if playerData.case == 3 then -- Case III: Dirty up. nextstep = AIRBOSS.PatternStep.DIRTYUP else -- Case II: Initial. nextstep = AIRBOSS.PatternStep.INITIAL end -- Next step hint. self:_SetPlayerStep( playerData, nextstep ) end end --- Dirty up and level out at 1200 ft for case III recovery. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data table. function AIRBOSS:_DirtyUp( playerData ) -- Check if player left or got back to the approach corridor. self:_CheckCorridor( playerData ) -- Check if we are inside the moving zone. local inzone = playerData.unit:IsInZone( self:_GetZoneDirtyUp( playerData.case ) ) if inzone then -- Hint for player about altitude, AoA etc. self:_PlayerHint( playerData ) -- Radio call "Say/Fly needles". Delayed by 10/15 seconds. if playerData.actype == AIRBOSS.AircraftCarrier.HORNET or playerData.actype == AIRBOSS.AircraftCarrier.F14A or playerData.actype == AIRBOSS.AircraftCarrier.F14B or playerData.actype == AIRBOSS.AircraftCarrier.RHINOE or playerData.actype == AIRBOSS.AircraftCarrier.RHINOF or playerData.actype == AIRBOSS.AircraftCarrier.GROWLER then local callsay = self:_NewRadioCall( self.MarshalCall.SAYNEEDLES, nil, nil, 5, playerData.onboard ) local callfly = self:_NewRadioCall( self.MarshalCall.FLYNEEDLES, nil, nil, 5, playerData.onboard ) self:RadioTransmission( self.MarshalRadio, callsay, false, 55, nil, true ) self:RadioTransmission( self.MarshalRadio, callfly, false, 60, nil, true ) end -- TODO: Make Fly Bullseye call if no automatic ICLS is active. -- Next step: CASE III: Intercept glide slope and follow bullseye (ICLS). self:_SetPlayerStep( playerData, AIRBOSS.PatternStep.BULLSEYE ) end end --- Intercept glide slop and follow ICLS, aka Bullseye for case III recovery. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data table. -- @return #boolean If true, player is in bullseye zone. function AIRBOSS:_Bullseye( playerData ) -- Check if player left or got back to the approach corridor. self:_CheckCorridor( playerData ) -- Check if we are inside the moving zone. local inzone = playerData.unit:IsInZone( self:_GetZoneBullseye( playerData.case ) ) -- Relative heading to carrier direction of the runway. local relheading = self:_GetRelativeHeading( playerData.unit, true ) -- Check if player is in zone and flying roughly in the right direction. if inzone and math.abs( relheading ) < 60 then -- Hint for player about altitude, AoA etc. self:_PlayerHint( playerData ) -- LSO expect spot 5 or 7.5 call if playerData.actype == AIRBOSS.AircraftCarrier.AV8B and self.carriertype == AIRBOSS.CarrierType.JCARLOS then self:RadioTransmission( self.LSORadio, self.LSOCall.EXPECTSPOT5, nil, nil, nil, true ) elseif playerData.actype == AIRBOSS.AircraftCarrier.AV8B and self.carriertype == AIRBOSS.CarrierType.CANBERRA then self:RadioTransmission( self.LSORadio, self.LSOCall.EXPECTSPOT5, nil, nil, nil, true ) elseif playerData.actype == AIRBOSS.AircraftCarrier.AV8B then self:RadioTransmission( self.LSORadio, self.LSOCall.EXPECTSPOT75, nil, nil, nil, true ) end -- Next step: Groove Call the ball. self:_SetPlayerStep( playerData, AIRBOSS.PatternStep.GROOVE_XX ) end end --- Bolter pattern. Sends player to abeam for Case I/II or Bullseye for Case III ops. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data table. function AIRBOSS:_BolterPattern( playerData ) -- Get distances between carrier and player unit (parallel and perpendicular to direction of movement of carrier) local X, Z, rho, phi = self:_GetDistances( playerData.unit ) -- Bolter Pattern thresholds. local Bolter = {} Bolter.name = "Bolter Pattern" Bolter.Xmin = -UTILS.NMToMeters( 5 ) -- Not more then 5 NM astern of boat. Bolter.Xmax = UTILS.NMToMeters( 3 ) -- Not more then 3 NM ahead of boat. Bolter.Zmin = -UTILS.NMToMeters( 5 ) -- Not more than 2 NM port. Bolter.Zmax = UTILS.NMToMeters( 1 ) -- Not more than 1 NM starboard. Bolter.LimitXmin = 100 -- Check that 100 meter ahead and port Bolter.LimitXmax = nil Bolter.LimitZmin = nil Bolter.LimitZmax = nil -- Check if we are in front of the boat (diffX > 0). if self:_CheckLimits( X, Z, Bolter ) then local nextstep if playerData.case < 3 then nextstep = AIRBOSS.PatternStep.ABEAM else nextstep = AIRBOSS.PatternStep.BULLSEYE end self:_SetPlayerStep( playerData, nextstep ) end end --- Break entry for case I/II recoveries. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data table. function AIRBOSS:_BreakEntry( playerData ) -- Get distances between carrier and player unit (parallel and perpendicular to direction of movement of carrier) local X, Z = self:_GetDistances( playerData.unit ) -- Abort condition check. if self:_CheckAbort( X, Z, self.BreakEntry ) then self:_AbortPattern( playerData, X, Z, self.BreakEntry, true ) return end -- Check if we are in front of the boat (diffX > 0). if self:_CheckLimits( X, Z, self.BreakEntry ) then -- Hint for player about altitude, AoA etc. self:_PlayerHint( playerData ) -- Next step: Early Break. self:_SetPlayerStep( playerData, AIRBOSS.PatternStep.EARLYBREAK ) end end --- Break. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data table. -- @param #string part Part of the break. function AIRBOSS:_Break( playerData, part ) -- Get distances between carrier and player unit (parallel and perpendicular to direction of movement of carrier) local X, Z = self:_GetDistances( playerData.unit ) -- Early or late break. local breakpoint = self.BreakEarly if part == AIRBOSS.PatternStep.LATEBREAK then breakpoint = self.BreakLate end -- Check abort conditions. if self:_CheckAbort( X, Z, breakpoint ) then self:_AbortPattern( playerData, X, Z, breakpoint, true ) return end -- Player made a very tight turn and did not trigger the latebreak threshold at 0.8 NM. local tooclose = false if part == AIRBOSS.PatternStep.LATEBREAK then local close = 0.8 if playerData.actype == AIRBOSS.AircraftCarrier.AV8B then close = 0.5 end if X < 0 and Z < UTILS.NMToMeters( close ) then if playerData.difficulty == AIRBOSS.Difficulty.EASY and playerData.showhints then self:MessageToPlayer( playerData, "your turn was too tight! Allow for more distance to the boat next time.", "LSO" ) end tooclose = true end end -- Check limits. if self:_CheckLimits( X, Z, breakpoint ) or tooclose then -- Hint for player about altitude, AoA etc. self:_PlayerHint( playerData ) -- Next step: Late Break or Abeam. local nextstep if part == AIRBOSS.PatternStep.EARLYBREAK then nextstep = AIRBOSS.PatternStep.LATEBREAK else nextstep = AIRBOSS.PatternStep.ABEAM end self:_SetPlayerStep( playerData, nextstep ) end end --- Long downwind leg check. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data table. function AIRBOSS:_CheckForLongDownwind( playerData ) -- Get distances between carrier and player unit (parallel and perpendicular to direction of movement of carrier) local X, Z = self:_GetDistances( playerData.unit ) -- 1.6 NM from carrier is too far. local limit = UTILS.NMToMeters( -1.6 ) -- For the tarawa, other LHA and LHD we give a bit more space. if self.carriertype == AIRBOSS.CarrierType.INVINCIBLE or self.carriertype == AIRBOSS.CarrierType.HERMES or self.carriertype == AIRBOSS.CarrierType.TARAWA or self.carriertype == AIRBOSS.CarrierType.AMERICA or self.carriertype == AIRBOSS.CarrierType.JCARLOS or self.carriertype == AIRBOSS.CarrierType.CANBERRA then limit = UTILS.NMToMeters( -2.0 ) end -- Check we are not too far out w.r.t back of the boat. if X < limit then -- and relhead<45 then -- Sound output. self:RadioTransmission( self.LSORadio, self.LSOCall.LONGINGROOVE ) self:RadioTransmission( self.LSORadio, self.LSOCall.DEPARTANDREENTER, nil, nil, nil, true ) -- Debrief. self:_AddToDebrief( playerData, "Long in the groove - Pattern Waveoff!" ) -- grade="LIG PATTERN WAVE OFF - CUT 1 PT" playerData.lig = true playerData.wop = true -- Next step: Debriefing. self:_SetPlayerStep( playerData, AIRBOSS.PatternStep.DEBRIEF ) end end --- Abeam position. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data table. function AIRBOSS:_Abeam( playerData ) -- Get distances between carrier and player unit (parallel and perpendicular to direction of movement of carrier) local X, Z = self:_GetDistances( playerData.unit ) -- Check abort conditions. if self:_CheckAbort( X, Z, self.Abeam ) then self:_AbortPattern( playerData, X, Z, self.Abeam, true ) return end -- Check nest step threshold. if self:_CheckLimits( X, Z, self.Abeam ) then -- Paddles contact. self:RadioTransmission( self.LSORadio, self.LSOCall.PADDLESCONTACT, nil, nil, nil, true ) -- LSO expect spot 5 or 7.5 call if playerData.actype == AIRBOSS.AircraftCarrier.AV8B and self.carriertype == AIRBOSS.CarrierType.JCARLOS then self:RadioTransmission( self.LSORadio, self.LSOCall.EXPECTSPOT5, false, 5, nil, true ) elseif playerData.actype == AIRBOSS.AircraftCarrier.AV8B and self.carriertype == AIRBOSS.CarrierType.CANBERRA then self:RadioTransmission( self.LSORadio, self.LSOCall.EXPECTSPOT5, false, 5, nil, true ) elseif playerData.actype == AIRBOSS.AircraftCarrier.AV8B then self:RadioTransmission( self.LSORadio, self.LSOCall.EXPECTSPOT75, false, 5, nil, true ) end -- Hint for player about altitude, AoA etc. self:_PlayerHint( playerData, 3 ) -- Next step: ninety. self:_SetPlayerStep( playerData, AIRBOSS.PatternStep.NINETY ) end end --- At the Ninety. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data table. function AIRBOSS:_Ninety( playerData ) -- Get distances between carrier and player unit (parallel and perpendicular to direction of movement of carrier) local X, Z = self:_GetDistances( playerData.unit ) -- Check abort conditions. if self:_CheckAbort( X, Z, self.Ninety ) then self:_AbortPattern( playerData, X, Z, self.Ninety, true ) return end -- Get Realtive heading player to carrier. local relheading = self:_GetRelativeHeading( playerData.unit, false ) -- At the 90, i.e. 90 degrees between player heading and BRC of carrier. if relheading <= 90 then -- Hint for player about altitude, AoA etc. self:_PlayerHint( playerData ) -- Next step: wake. if self.carriertype == AIRBOSS.CarrierType.INVINCIBLE or self.carriertype == AIRBOSS.CarrierType.HERMES or self.carriertype == AIRBOSS.CarrierType.TARAWA or self.carriertype == AIRBOSS.CarrierType.AMERICA or self.carriertype == AIRBOSS.CarrierType.JCARLOS or self.carriertype == AIRBOSS.CarrierType.CANBERRA then -- Harrier has no wake stop. It stays port of the boat. self:_SetPlayerStep( playerData, AIRBOSS.PatternStep.FINAL ) else self:_SetPlayerStep( playerData, AIRBOSS.PatternStep.WAKE ) end elseif relheading > 90 and self:_CheckLimits( X, Z, self.Wake ) then -- Message to player. self:MessageToPlayer( playerData, "you are already at the wake and have not passed the 90. Turn faster next time!", "LSO" ) self:RadioTransmission( self.LSORadio, self.LSOCall.DEPARTANDREENTER, nil, nil, nil, true ) playerData.wop = true -- Debrief. self:_AddToDebrief( playerData, "Overshoot at wake - Pattern Waveoff!" ) self:_SetPlayerStep( playerData, AIRBOSS.PatternStep.DEBRIEF ) end end --- At the Wake. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data table. function AIRBOSS:_Wake( playerData ) -- Get distances between carrier and player unit (parallel and perpendicular to direction of movement of carrier) local X, Z = self:_GetDistances( playerData.unit ) -- Check abort conditions. if self:_CheckAbort( X, Z, self.Wake ) then self:_AbortPattern( playerData, X, Z, self.Wake, true ) return end -- Right behind the wake of the carrier dZ>0. if self:_CheckLimits( X, Z, self.Wake ) then -- Hint for player about altitude, AoA etc. self:_PlayerHint( playerData ) -- Next step: Final. self:_SetPlayerStep( playerData, AIRBOSS.PatternStep.FINAL ) end end --- Get groove data. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data table. -- @return #AIRBOSS.GrooveData Groove data table. function AIRBOSS:_GetGrooveData( playerData ) -- Get distances between carrier and player unit (parallel and perpendicular to direction of movement of carrier). local X, Z = self:_GetDistances( playerData.unit ) -- Stern position at the rundown. local stern = self:_GetSternCoord() -- Distance from rundown to player aircraft. local rho = stern:Get2DDistance( playerData.unit:GetCoordinate() ) -- Aircraft is behind the carrier. local astern = X < self.carrierparam.sterndist -- Correct sign. Negative if passed rundown. if astern == false then rho = -rho end -- Velocity vector. local vel = playerData.unit:GetVelocityVec3() -- Grade, points, details local Gg, Gp, Gd = self:_LSOgrade( playerData ) -- Gather pilot data. local groovedata = {} -- #AIRBOSS.GrooveData groovedata.Step = playerData.step groovedata.Time = timer.getTime() groovedata.Rho = rho groovedata.X = X groovedata.Z = Z groovedata.Alt = self:_GetAltCarrier( playerData.unit ) groovedata.AoA = playerData.unit:GetAoA() groovedata.GSE = self:_Glideslope( playerData.unit ) groovedata.LUE = self:_Lineup( playerData.unit, true ) groovedata.Roll = playerData.unit:GetRoll() groovedata.Pitch = playerData.unit:GetPitch() groovedata.Yaw = playerData.unit:GetYaw() groovedata.Vel = UTILS.VecNorm( vel ) groovedata.Vy = vel.y groovedata.Gamma = self:_GetRelativeHeading( playerData.unit, true ) groovedata.Grade = Gg groovedata.GradePoints = Gp groovedata.GradeDetail = Gd -- env.info(string.format(", %.6f, %.6f, %.6f, %.6f, %.6f, %.6f, %.6f", groovedata.Time, groovedata.Rho, groovedata.X, groovedata.Alt, groovedata.GSE, groovedata.LUE, groovedata.AoA)) return groovedata end --- Turn to final. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data table. -- @param #boolean nocheck If true, player is not checked to be in the right position. function AIRBOSS:_Final( playerData, nocheck ) -- Get distances between carrier and player unit (parallel and perpendicular to direction of movement of carrier) local X, Z, rho, phi = self:_GetDistances( playerData.unit ) -- In front of carrier or more than 4 km behind carrier. if not nocheck then if self:_CheckAbort( X, Z, self.Final ) then self:_AbortPattern( playerData, X, Z, self.Final, true ) return end end -- Get Groove data local groovedata = self:_GetGrooveData( playerData ) -- Trap sheet data. table.insert( playerData.trapsheet, groovedata ) -- Get groove zone. local zone = self:_GetZoneGroove() -- Check if player is in zone. local inzone = playerData.unit:IsInZone( zone ) -- Check. if inzone then -- and math.abs(groovedata.Roll)<5 then -- Hint for player about altitude, AoA etc. Sound is off. self:_PlayerHint( playerData, nil, true ) -- Init FlyThrough. groovedata.FlyThrough = nil -- TODO: could add angled approach if lineup<5 and relhead>5. This would mean the player has not turned in correctly! -- Groove data. playerData.groove.X0 = UTILS.DeepCopy( groovedata ) -- Set time stamp. Next call in 4 seconds. playerData.Tlso = timer.getTime() -- Next step: X start. self:_SetPlayerStep( playerData, AIRBOSS.PatternStep.GROOVE_XX ) end -- Groovedata step. groovedata.Step = playerData.step end --- In the groove. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data table. function AIRBOSS:_Groove( playerData ) -- Ranges in the groove. local RX0 = UTILS.NMToMeters( 1.000 ) -- Everything before X 1.00 = 1852 m local RXX = UTILS.NMToMeters( 0.750 ) -- Start of groove. 0.75 = 1389 m local RIM = UTILS.NMToMeters( 0.500 ) -- In the Middle 0.50 = 926 m (middle one third of the glideslope) local RIC = UTILS.NMToMeters( 0.250 ) -- In Close 0.25 = 463 m (last one third of the glideslope) local RAR = UTILS.NMToMeters( 0.040 ) -- At the Ramp. 0.04 = 75 m -- Groove data. local groovedata = self:_GetGrooveData( playerData ) -- Add data to trapsheet. table.insert( playerData.trapsheet, groovedata ) -- Coords. local X = groovedata.X local Z = groovedata.Z -- Check abort conditions. if self:_CheckAbort( groovedata.X, groovedata.Z, self.Groove ) then self:_AbortPattern( playerData, groovedata.X, groovedata.Z, self.Groove, true ) return end -- Shortcuts. local rho = groovedata.Rho local lineupError = groovedata.LUE local glideslopeError = groovedata.GSE local AoA = groovedata.AoA if rho <= RXX and playerData.step == AIRBOSS.PatternStep.GROOVE_XX and (math.abs( groovedata.Roll ) <= 4.0 and playerData.unit:IsInZone( self:_GetZoneLineup() )) then -- Start time in groove playerData.TIG0 = timer.getTime() -- LSO "Call the ball" call. self:RadioTransmission( self.LSORadio, self.LSOCall.CALLTHEBALL, nil, nil, nil, true ) playerData.Tlso = timer.getTime() -- Pilot "405, Hornet Ball, 3.2". -- LSO "Roger ball" call in three seconds. self:RadioTransmission( self.LSORadio, self.LSOCall.ROGERBALL, false, nil, 2, true ) -- Store data. playerData.groove.XX = UTILS.DeepCopy( groovedata ) -- This is a valid approach and player did not miss any important steps in the pattern. playerData.valid = true -- Next step: in the middle. self:_SetPlayerStep( playerData, AIRBOSS.PatternStep.GROOVE_IM ) elseif rho <= RIM and playerData.step == AIRBOSS.PatternStep.GROOVE_IM then -- Store data. playerData.groove.IM = UTILS.DeepCopy( groovedata ) -- Next step: in close. self:_SetPlayerStep( playerData, AIRBOSS.PatternStep.GROOVE_IC ) elseif rho <= RIC and playerData.step == AIRBOSS.PatternStep.GROOVE_IC then -- Store data. playerData.groove.IC = UTILS.DeepCopy( groovedata ) -- Next step: AR at the ramp. self:_SetPlayerStep( playerData, AIRBOSS.PatternStep.GROOVE_AR ) elseif rho <= RAR and playerData.step == AIRBOSS.PatternStep.GROOVE_AR then -- Store data. playerData.groove.AR = UTILS.DeepCopy( groovedata ) -- Next step: in the wires. if playerData.actype == AIRBOSS.AircraftCarrier.AV8B then self:_SetPlayerStep( playerData, AIRBOSS.PatternStep.GROOVE_AL ) else self:_SetPlayerStep( playerData, AIRBOSS.PatternStep.GROOVE_IW ) end elseif rho <= RAR and playerData.step == AIRBOSS.PatternStep.GROOVE_AL then -- Store data. playerData.groove.AL = UTILS.DeepCopy( groovedata ) -- Get zone abeam LDG spot. local ZoneALS = self:_GetZoneAbeamLandingSpot() -- Get player velocity in km/h. local vplayer = playerData.unit:GetVelocityKMH() -- Get carrier velocity in km/h. local vcarrier = self.carrier:GetVelocityKMH() -- Speed difference. local dv = math.abs( vplayer - vcarrier ) -- Stable when speed difference < 30 km/h.(16 Kts)Pene Testing local stable=dv<30 -- Check if player is inside the zone. if playerData.unit:IsInZone( ZoneALS ) and stable then -- Radio Transmission "Cleared to land" once the aircraft is inside the zone. self:RadioTransmission( self.LSORadio, self.LSOCall.CLEAREDTOLAND, nil, nil, nil, true ) -- Next step: Level cross. self:_SetPlayerStep( playerData, AIRBOSS.PatternStep.GROOVE_LC ) -- Set Stable Hover playerData.stable = true playerData.hover = true end elseif rho <= RAR and playerData.step == AIRBOSS.PatternStep.GROOVE_LC then -- Store data. playerData.groove.LC = UTILS.DeepCopy( groovedata ) -- Get zone primary LDG spot. local ZoneLS = self:_GetZoneLandingSpot() -- Get player velocity in km/h. local vplayer = playerData.unit:GetVelocityKMH() -- Get carrier velocity in km/h. local vcarrier = self.carrier:GetVelocityKMH() -- Speed difference. local dv = math.abs( vplayer - vcarrier ) -- Stable when v<15 km/h. local stable=dv<15 -- Radio Transmission "Stabilized" once the aircraft has been cleared to cross and is over the Landing Spot and stable. if playerData.unit:IsInZone( ZoneLS ) and stable and playerData.stable == true then self:RadioTransmission( self.LSORadio, self.LSOCall.STABILIZED, nil, nil, nil, false ) playerData.stable = false playerData.warning = true end -- We keep it in this step until landed. end -------------- -- Wave Off -- -------------- -- Between IC and AR check for wave off. if rho >= RAR and rho <= RIC and not playerData.waveoff then -- Check if player should wave off. local waveoff = self:_CheckWaveOff( glideslopeError, lineupError, AoA, playerData ) -- Let's see.. if waveoff then -- Debug info. self:T3( self.lid .. string.format( "Waveoff distance rho=%.1f m", rho ) ) -- LSO Wave off! self:RadioTransmission( self.LSORadio, self.LSOCall.WAVEOFF, nil, nil, nil, true ) playerData.Tlso = timer.getTime() -- Player was waved off! playerData.waveoff = true -- Nothing else necessary. return end end -- Long V/STOL groove time Wave Off over 75 seconds to IC - TOPGUN level Only. --pene testing (WIP)--- Need to think more about this. --if rho>=RAR and rho<=RIC and not playerData.waveoff and playerData.difficulty==AIRBOSS.Difficulty.HARD and playerData.actype== AIRBOSS.AircraftCarrier.AV8B then -- Get groove time --local vSlow=groovedata.time -- If too slow wave off. --if vSlow >75 then -- LSO Wave off! --self:RadioTransmission(self.LSORadio, self.LSOCall.WAVEOFF, nil, nil, nil, true) --playerData.Tlso=timer.getTime() -- Player was waved Off --playerData.waveoff=true --return --end --end -- Groovedata step. groovedata.Step = playerData.step ----------------- -- Groove Data -- ----------------- -- Check if we are beween 3/4 NM and end of ship. if rho >= RAR and rho < RX0 and playerData.waveoff == false then -- Get groove step short hand of the previous step. local gs = self:_GS( playerData.step, -1 ) -- Get current groove data. local gd = playerData.groove[gs] -- #AIRBOSS.GrooveData if gd then self:T3( gd ) -- Distance in NM. local d = UTILS.MetersToNM( rho ) -- Drift on lineup. if rho >= RAR and rho <= RIM then if gd.LUE > 0.22 and lineupError < -0.22 then env.info " Drift Right across centre ==> DR-" gd.Drift = " DR" self:T( self.lid .. string.format( "Got Drift Right across centre step %s, d=%.3f: Max LUE=%.3f, lower LUE=%.3f", gs, d, gd.LUE, lineupError ) ) elseif gd.LUE < -0.22 and lineupError > 0.22 then env.info " Drift Left ==> DL-" gd.Drift = " DL" self:T( self.lid .. string.format( "Got Drift Left across centre at step %s, d=%.3f: Min LUE=%.3f, lower LUE=%.3f", gs, d, gd.LUE, lineupError ) ) elseif gd.LUE > 0.13 and lineupError < -0.14 then env.info " Little Drift Right across centre ==> (DR-)" gd.Drift = " (DR)" self:T( self.lid .. string.format( "Got Little Drift Right across centre at step %s, d=%.3f: Max LUE=%.3f, lower LUE=%.3f", gs, d, gd.LUE, lineupError ) ) elseif gd.LUE < -0.13 and lineupError > 0.14 then env.info " Little Drift Left across centre ==> (DL-)" gd.Drift = " (DL)" self:E( self.lid .. string.format( "Got Little Drift Left across centre at step %s, d=%.3f: Min LUE=%.3f, lower LUE=%.3f", gs, d, gd.LUE, lineupError ) ) end end -- Update max deviation of line up error. if math.abs( lineupError ) > math.abs( gd.LUE ) then self:T( self.lid .. string.format( "Got bigger LUE at step %s, d=%.3f: LUE %.3f>%.3f", gs, d, lineupError, gd.LUE ) ) gd.LUE = lineupError end -- Fly through good window of glideslope. if gd.GSE > 0.4 and glideslopeError < -0.3 then -- Fly through down ==> "\" gd.FlyThrough = "\\" self:T( self.lid .. string.format( "Got Fly through DOWN at step %s, d=%.3f: Max GSE=%.3f, lower GSE=%.3f", gs, d, gd.GSE, glideslopeError ) ) elseif gd.GSE < -0.3 and glideslopeError > 0.4 then -- Fly through up ==> "/" gd.FlyThrough = "/" self:E( self.lid .. string.format( "Got Fly through UP at step %s, d=%.3f: Min GSE=%.3f, lower GSE=%.3f", gs, d, gd.GSE, glideslopeError ) ) end -- Update max deviation of glideslope error. if math.abs( glideslopeError ) > math.abs( gd.GSE ) then self:T( self.lid .. string.format( "Got bigger GSE at step %s, d=%.3f: GSE |%.3f|>|%.3f|", gs, d, glideslopeError, gd.GSE ) ) gd.GSE = glideslopeError end -- Get aircraft AoA parameters. local aircraftaoa = self:_GetAircraftAoA( playerData ) -- On Speed AoA. local aoaopt = aircraftaoa.OnSpeed -- Compare AoAs wrt on speed AoA and update max deviation. if math.abs( AoA - aoaopt ) > math.abs( gd.AoA - aoaopt ) then self:T( self.lid .. string.format( "Got bigger AoA error at step %s, d=%.3f: AoA %.3f>%.3f.", gs, d, AoA, gd.AoA ) ) gd.AoA = AoA end -- local gs2=self:_GS(groovedata.Step, -1) -- env.info(string.format("groovestep %s %s d=%.3f NM: GSE=%.3f %.3f, LUE=%.3f %.3f, AoA=%.3f %.3f", gs, gs2, d, groovedata.GSE, gd.GSE, groovedata.LUE, gd.LUE, groovedata.AoA, gd.AoA)) end --------------- -- LSO Calls -- --------------- -- Time since last LSO call. local deltaT = timer.getTime() - playerData.Tlso -- Wait until player passed the 0.75 NM distance. local _advice = true if playerData.TIG0 == nil and playerData.difficulty ~= AIRBOSS.Difficulty.EASY then -- rho>RXX _advice = false end -- LSO call if necessary. if deltaT >= self.LSOdT and _advice then self:_LSOadvice( playerData, glideslopeError, lineupError ) end end ---------------------------------------------------------- --- Some time here the landing event MIGHT be triggered -- ---------------------------------------------------------- -- Player infront of the carrier X>~77 m. if X > self.carrierparam.totlength + self.carrierparam.sterndist then if playerData.waveoff then if playerData.landed then -- This should not happen because landing event was triggered. self:_AddToDebrief( playerData, "You were waved off but landed anyway. Airboss wants to talk to you!" ) else self:_AddToDebrief( playerData, "You were waved off." ) end elseif playerData.boltered then -- This should not happen because landing event was triggered. self:_AddToDebrief( playerData, "You boltered." ) else -- This should not happen. self:T( "Player was not waved off but flew past the carrier without landing ==> Own wave off!" ) -- We count this as OWO. self:_AddToDebrief( playerData, "Own waveoff." ) -- Set Owo playerData.owo = true end -- Next step: debrief. self:_SetPlayerStep( playerData, AIRBOSS.PatternStep.DEBRIEF ) end end --- LSO check if player needs to wave off. -- Wave off conditions are: -- -- * Glideslope error <1.2 or >1.8 degrees. -- * |Line up error| > 3 degrees. -- * AoA check but only for TOPGUN graduates. -- @param #AIRBOSS self -- @param #number glideslopeError Glideslope error in degrees. -- @param #number lineupError Line up error in degrees. -- @param #number AoA Angle of attack of player aircraft. -- @param #AIRBOSS.PlayerData playerData Player data. -- @return #boolean If true, player should wave off! function AIRBOSS:_CheckWaveOff( glideslopeError, lineupError, AoA, playerData ) -- Assume we're all good. local waveoff = false -- Parameters local glMax = 1.8 local glMin = -1.2 local luAbs = 3.0 -- For the harrier, we allow a bit more room. if playerData.actype == AIRBOSS.AircraftCarrier.AV8B then glMax = 2.6 glMin = -2.2 -- Testing, @Engines may be just dragging it in on Hermes, or the carrier parameters need adjusting. luAbs = 4.1 -- Testing Pene. end -- Too high or too low? if glideslopeError > glMax then local text = string.format( "\n- Waveoff due to glideslope error %.2f > %.1f degrees!", glideslopeError, glMax ) self:T( self.lid .. string.format( "%s: %s", playerData.name, text ) ) self:_AddToDebrief( playerData, text ) waveoff = true elseif glideslopeError < glMin then local text = string.format( "\n- Waveoff due to glideslope error %.2f < %.1f degrees!", glideslopeError, glMin ) self:T( self.lid .. string.format( "%s: %s", playerData.name, text ) ) self:_AddToDebrief( playerData, text ) waveoff = true end -- Too far from centerline? if math.abs( lineupError ) > luAbs then local text = string.format( "\n- Waveoff due to line up error |%.1f| > %.1f degrees!", lineupError, luAbs ) self:T( self.lid .. string.format( "%s: %s", playerData.name, text ) ) self:_AddToDebrief( playerData, text ) waveoff = true end -- Too slow or too fast? Only for pros. if playerData.difficulty == AIRBOSS.Difficulty.HARD and playerData.actype ~= AIRBOSS.AircraftCarrier.AV8B then -- Get aircraft specific AoA values. Not for AV-8B due to transition to Stable Hover. local aoaac = self:_GetAircraftAoA( playerData ) -- Check too slow or too fast. if AoA < aoaac.FAST then local text = string.format( "\n- Waveoff due to AoA %.1f < %.1f!", AoA, aoaac.FAST ) self:T( self.lid .. string.format( "%s: %s", playerData.name, text ) ) self:_AddToDebrief( playerData, text ) waveoff = true elseif AoA > aoaac.SLOW then local text = string.format( "\n- Waveoff due to AoA %.1f > %.1f!", AoA, aoaac.SLOW ) self:T( self.lid .. string.format( "%s: %s", playerData.name, text ) ) self:_AddToDebrief( playerData, text ) waveoff = true end end return waveoff end --- Check if other aircraft are currently on the landing runway. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data. -- @return boolean If true, we have a foul deck. function AIRBOSS:_CheckFoulDeck( playerData ) -- Assume no check necessary. local check = false -- CVN: Check at IM and IC. if playerData.step == AIRBOSS.PatternStep.GROOVE_IM or playerData.step == AIRBOSS.PatternStep.GROOVE_IC then check = true end -- AV-8B check until if playerData.actype == AIRBOSS.AircraftCarrier.AV8B then if playerData.step == AIRBOSS.PatternStep.GROOVE_AR or playerData.step == AIRBOSS.PatternStep.GROOVE_AL then check = true end end -- Check if player was already waved off. Should not be necessary as player step is set to debrief afterwards! if playerData.wofd == true or check == false then -- Player was already waved off. return end -- Landing runway zone. local runway = self:_GetZoneRunwayBox() -- For AB-8B we just check the primary landing spot. if playerData.actype == AIRBOSS.AircraftCarrier.AV8B then runway = self:_GetZoneLandingSpot() end -- Scan radius. local R = 250 -- Debug info. self:T( self.lid .. string.format( "Foul deck check: Scanning Carrier Runway Area. Radius=%.1f m.", R ) ) -- Scan units in carrier zone. local _, _, _, unitscan = self:GetCoordinate():ScanObjects( R, true, false, false ) -- Loop over all scanned units and check if they are on the runway. local fouldeck = false local foulunit = nil -- Wrapper.Unit#UNIT for _, _unit in pairs( unitscan ) do local unit = _unit -- Wrapper.Unit#UNIT -- Check if unit is in zone. local inzone = unit:IsInZone( runway ) -- Check if aircraft and in air. local isaircraft = unit:IsAir() local isairborn = unit:InAir() if inzone and isaircraft and not isairborn then local text = string.format( "Unit %s on landing runway ==> Foul deck!", unit:GetName() ) self:T( self.lid .. text ) MESSAGE:New( text, 10 ):ToAllIf( self.Debug ) if self.Debug then runway:FlareZone( FLARECOLOR.Red, 30 ) end fouldeck = true foulunit = unit end end -- Add to debrief and if playerData and fouldeck then -- Debrief text. local text = string.format( "Foul deck waveoff due to aircraft %s!", foulunit:GetName() ) self:T( self.lid .. string.format( "%s: %s", playerData.name, text ) ) self:_AddToDebrief( playerData, text ) -- Foul deck + wave off radio message. self:RadioTransmission( self.LSORadio, self.LSOCall.FOULDECK, false, 1 ) self:RadioTransmission( self.LSORadio, self.LSOCall.WAVEOFF, false, 1.2, nil, true ) -- Player hint for flight students. if playerData.showhints then local text = string.format( "overfly landing area and enter bolter pattern." ) self:MessageToPlayer( playerData, text, "LSO", nil, nil, false, 3 ) end -- Set player parameters for foul deck. playerData.wofd = true -- Debrief. playerData.step = AIRBOSS.PatternStep.DEBRIEF playerData.warning = nil -- Pass would be invalid if the player lands. playerData.valid = false -- Send a message to the player that blocks the runway. if foulunit then local foulflight = self:_GetFlightFromGroupInQueue( foulunit:GetGroup(), self.flights ) if foulflight and not foulflight.ai then self:MessageToPlayer( foulflight, "move your ass from my runway. NOW!", "AIRBOSS" ) end end end return fouldeck end --- Get "stern" coordinate. -- @param #AIRBOSS self -- @return Core.Point#COORDINATE Coordinate at the rundown of the carrier. function AIRBOSS:_GetSternCoord() -- Heading of carrier (true). local hdg = self.carrier:GetHeading() -- Final bearing (true). local FB=self:GetFinalBearing() local case=self.case -- Stern coordinate (sterndist<0). Also translate 10 meters starboard wrt Final bearing. self.sterncoord:UpdateFromCoordinate( self:GetCoordinate() ) -- local stern=self:GetCoordinate() -- Stern coordinate (sterndist<0). --Pene testing Case III if self.carriertype==AIRBOSS.CarrierType.INVINCIBLE or self.carriertype==AIRBOSS.CarrierType.HERMES or self.carriertype==AIRBOSS.CarrierType.TARAWA or self.carriertype==AIRBOSS.CarrierType.AMERICA or self.carriertype==AIRBOSS.CarrierType.JCARLOS or self.carriertype==AIRBOSS.CarrierType.CANBERRA then if case==3 then -- CASE III V/STOL translation Due over deck approach if needed. self.sterncoord:Translate(self.carrierparam.sterndist, hdg, true, true):Translate(8, FB-90, true, true) elseif case==2 or case==1 then -- V/Stol: Translate 8 meters port. self.sterncoord:Translate(self.carrierparam.sterndist, hdg, true, true):Translate(8, FB-90, true, true) end elseif self.carriertype==AIRBOSS.CarrierType.STENNIS then -- Stennis: translate 7 meters starboard wrt Final bearing. self.sterncoord:Translate( self.carrierparam.sterndist, hdg, true, true ):Translate( 7, FB + 90, true, true ) elseif self.carriertype == AIRBOSS.CarrierType.FORRESTAL then -- Forrestal self.sterncoord:Translate( self.carrierparam.sterndist, hdg, true, true ):Translate( 7.5, FB + 90, true, true ) else -- Nimitz SC: translate 8 meters starboard wrt Final bearing. self.sterncoord:Translate( self.carrierparam.sterndist, hdg, true, true ):Translate( 9.5, FB + 90, true, true ) end -- Set altitude. self.sterncoord:SetAltitude( self.carrierparam.deckheight ) return self.sterncoord end --- Get wire from draw argument. -- @param #AIRBOSS self -- @param Core.Point#COORDINATE Lcoord Landing position. -- @return #number Trapped wire (1-4) or 99 if no wire was trapped. function AIRBOSS:_GetWireFromDrawArg() local wireArgs={} wireArgs[1]=141 wireArgs[2]=142 wireArgs[3]=143 wireArgs[4]=144 for wire,drawArg in pairs(wireArgs) do local value=self.carrier:GetDrawArgumentValue(drawArg) if math.abs(value)>0.001 then return wire end end return 99 end --- Get wire from landing position. -- @param #AIRBOSS self -- @param Core.Point#COORDINATE Lcoord Landing position. -- @param #number dc Distance correction. Shift the landing coord back if dc>0 and forward if dc<0. -- @return #number Trapped wire (1-4) or 99 if no wire was trapped. function AIRBOSS:_GetWire( Lcoord, dc ) -- Final bearing (true). local FB = self:GetFinalBearing() -- Stern coordinate (sterndist<0). Also translate 10 meters starboard wrt Final bearing. local Scoord = self:_GetSternCoord() -- Distance to landing coord. local Ldist = Lcoord:Get2DDistance( Scoord ) -- For human (not AI) the lading event is delayed unfortunately. Therefore, we need another correction factor. dc = dc or 65 -- Corrected landing distance wrt to stern. Landing distance needs to be reduced due to delayed landing event for human players. local d = Ldist - dc -- Multiplayer wire correction. if self.mpWireCorrection then d = d - self.mpWireCorrection end -- Shift wires from stern to their correct position. local w1 = self.carrierparam.wire1 local w2 = self.carrierparam.wire2 local w3 = self.carrierparam.wire3 local w4 = self.carrierparam.wire4 -- Which wire was caught? local wire if d < w1 then -- 46 wire = 1 elseif d < w2 then -- 46+12 wire = 2 elseif d < w3 then -- 46+24 wire = 3 elseif d < w4 then -- 46+35 wire = 4 else wire = 99 end if self.Debug and false then -- Wire position coordinates. local wp1 = Scoord:Translate( w1, FB ) local wp2 = Scoord:Translate( w2, FB ) local wp3 = Scoord:Translate( w3, FB ) local wp4 = Scoord:Translate( w4, FB ) -- Debug marks. wp1:MarkToAll( "Wire 1" ) wp2:MarkToAll( "Wire 2" ) wp3:MarkToAll( "Wire 3" ) wp4:MarkToAll( "Wire 4" ) -- Mark stern. Scoord:MarkToAll( "Stern" ) -- Mark at landing position. Lcoord:MarkToAll( string.format( "Landing Point wire=%s", wire ) ) -- Smoke landing position. Lcoord:SmokeGreen() -- Corrected landing position. local Dcoord = Lcoord:Translate( -dc, FB ) -- Smoke corrected landing pos red. Dcoord:SmokeRed() end -- Debug output. self:T( string.format( "GetWire: L=%.1f, L-dc=%.1f ==> wire=%d (dc=%.1f)", Ldist, Ldist - dc, wire, dc ) ) return wire end --- Trapped? Check if in air or not after landing event. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data table. function AIRBOSS:_Trapped( playerData ) if playerData.unit:InAir() == false then -- Seems we have successfully landed. -- Lets see if we can get a good wire. local unit = playerData.unit -- Coordinate of player aircraft. local coord = unit:GetCoordinate() -- Get velocity in km/h. We need to substrackt the carrier velocity. local v = unit:GetVelocityKMH() - self.carrier:GetVelocityKMH() -- Stern coordinate. local stern = self:_GetSternCoord() -- Distance to stern pos. local s = stern:Get2DDistance( coord ) -- Get current wire (estimate). This now based on the position where the player comes to a standstill which should reflect the trapped wire better. local dcorr = 100 if playerData.actype == AIRBOSS.AircraftCarrier.HORNET or playerData.actype == AIRBOSS.AircraftCarrier.RHINOE or playerData.actype == AIRBOSS.AircraftCarrier.RHINOF or playerData.actype == AIRBOSS.AircraftCarrier.GROWLER then dcorr = 100 elseif playerData.actype == AIRBOSS.AircraftCarrier.F14A or playerData.actype == AIRBOSS.AircraftCarrier.F14B then -- TODO: Check Tomcat. dcorr = 100 elseif playerData.actype == AIRBOSS.AircraftCarrier.A4EC then -- A-4E gets slowed down much faster the the F/A-18C! dcorr = 56 elseif playerData.actype == AIRBOSS.AircraftCarrier.T45C then -- T-45 also gets slowed down much faster the the F/A-18C. dcorr = 56 end -- Get wire. local wire = self:_GetWire( coord, dcorr ) -- Debug. local text = string.format( "Player %s _Trapped: v=%.1f km/h, s-dcorr=%.1f m ==> wire=%d (dcorr=%d)", playerData.name, v, s - dcorr, wire, dcorr ) self:T( self.lid .. text ) -- Call this function again until v < threshold. Player comes to a standstill ==> Get wire! if v > 5 then -- Check if we passed all wires. if wire > 4 and v > 10 and not playerData.warning then -- Looks like we missed the wires ==> Bolter! self:RadioTransmission( self.LSORadio, self.LSOCall.BOLTER, nil, nil, nil, true ) playerData.warning = true end -- Call function again and check if converged or back in air. -- SCHEDULER:New(nil, self._Trapped, {self, playerData}, 0.1) self:ScheduleOnce( 0.1, self._Trapped, self, playerData ) return end ---------------------------------------- --- Form this point on we have converged ---------------------------------------- -- Put some smoke and a mark. if self.Debug then coord:SmokeBlue() coord:MarkToAll( text ) stern:MarkToAll( "Stern" ) end -- Set player wire. playerData.wire = wire -- Message to player. local text = string.format( "Trapped %d-wire.", wire ) if wire == 3 then text = text .. " Well done!" elseif wire == 2 then text = text .. " Not bad, maybe you even get the 3rd next time." elseif wire == 4 then text = text .. " That was scary. You can do better than this!" elseif wire == 1 then text = text .. " Try harder next time!" end -- Message to player. self:MessageToPlayer( playerData, text, "LSO", "" ) -- Debrief. local hint = string.format( "Trapped %d-wire.", wire ) self:_AddToDebrief( playerData, hint, "Groove: IW" ) else -- Again in air ==> Boltered! local text = string.format( "Player %s boltered in trapped function.", playerData.name ) self:T( self.lid .. text ) MESSAGE:New( text, 5, "DEBUG" ):ToAllIf( self.debug ) -- Bolter switch on. playerData.boltered = true end -- Next step: debriefing. playerData.step = AIRBOSS.PatternStep.DEBRIEF playerData.warning = nil end ---------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- -- ZONE functions ---------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- --- Get Initial zone for Case I or II. -- @param #AIRBOSS self -- @param #number case Recovery Case. -- @return Core.Zone#ZONE_POLYGON_BASE Initial zone. function AIRBOSS:_GetZoneInitial( case ) self.zoneInitial = self.zoneInitial or ZONE_POLYGON_BASE:New( "Zone CASE I/II Initial" ) -- Get radial, i.e. inverse of BRC. local radial = self:GetRadial( 2, false, false ) -- Carrier coordinate. local cv = self:GetCoordinate() -- Vec2 array. local vec2 = {} if case == 1 then -- Case I local c1 = cv:Translate( UTILS.NMToMeters( 0.5 ), radial - 90 ) -- 0.0 0.5 starboard local c2 = cv:Translate( UTILS.NMToMeters( 1.3 ), radial - 90 ):Translate( UTILS.NMToMeters( 3 ), radial ) -- -3.0 1.3 starboard, astern local c3 = cv:Translate( UTILS.NMToMeters( 0.4 ), radial + 90 ):Translate( UTILS.NMToMeters( 3 ), radial ) -- -3.0 -0.4 port, astern local c4 = cv:Translate( UTILS.NMToMeters( 1.0 ), radial ) local c5 = cv -- Vec2 array. vec2 = { c1:GetVec2(), c2:GetVec2(), c3:GetVec2(), c4:GetVec2(), c5:GetVec2() } else -- Case II -- Funnel. local c1 = cv:Translate( UTILS.NMToMeters( 0.5 ), radial - 90 ) -- 0.0, 0.5 local c2 = c1:Translate( UTILS.NMToMeters( 0.5 ), radial ) -- 0.5, 0.5 local c3 = cv:Translate( UTILS.NMToMeters( 1.2 ), radial - 90 ):Translate( UTILS.NMToMeters( 3 ), radial ) -- 3.0, 1.2 local c4 = cv:Translate( UTILS.NMToMeters( 1.2 ), radial + 90 ):Translate( UTILS.NMToMeters( 3 ), radial ) -- 3.0,-1.2 local c5 = cv:Translate( UTILS.NMToMeters( 0.5 ), radial ) local c6 = cv -- Vec2 array. vec2 = { c1:GetVec2(), c2:GetVec2(), c3:GetVec2(), c4:GetVec2(), c5:GetVec2(), c6:GetVec2() } end -- Polygon zone. -- local zone=ZONE_POLYGON_BASE:New("Zone CASE I/II Initial", vec2) self.zoneInitial:UpdateFromVec2( vec2 ) -- return zone return self.zoneInitial end --- Get lineup groove zone. -- @param #AIRBOSS self -- @return Core.Zone#ZONE_POLYGON_BASE Lineup zone. function AIRBOSS:_GetZoneLineup() self.zoneLineup = self.zoneLineup or ZONE_POLYGON_BASE:New( "Zone Lineup" ) -- Get radial, i.e. inverse of BRC. local fbi = self:GetRadial( 1, false, false ) -- Stern coordinate. local st = self:_GetOptLandingCoordinate() -- Zone points. local c1 = st local c2 = st:Translate( UTILS.NMToMeters( 0.50 ), fbi + 15 ) local c3 = st:Translate( UTILS.NMToMeters( 0.50 ), fbi + self.lue._max - 0.05 ) local c4 = st:Translate( UTILS.NMToMeters( 0.77 ), fbi + self.lue._max - 0.05 ) local c5 = c4:Translate( UTILS.NMToMeters( 0.25 ), fbi - 90 ) -- Vec2 array. local vec2 = { c1:GetVec2(), c2:GetVec2(), c3:GetVec2(), c4:GetVec2(), c5:GetVec2() } self.zoneLineup:UpdateFromVec2( vec2 ) -- Polygon zone. -- local zone=ZONE_POLYGON_BASE:New("Zone Lineup", vec2) -- return zone return self.zoneLineup end --- Get groove zone. -- @param #AIRBOSS self -- @param #number l Length of the groove in NM. Default 1.5 NM. -- @param #number w Width of the groove in NM. Default 0.25 NM. -- @param #number b Width of the beginning in NM. Default 0.10 NM. -- @return Core.Zone#ZONE_POLYGON_BASE Groove zone. function AIRBOSS:_GetZoneGroove( l, w, b ) self.zoneGroove = self.zoneGroove or ZONE_POLYGON_BASE:New( "Zone Groove" ) l = l or 1.50 w = w or 0.25 b = b or 0.10 -- Get radial, i.e. inverse of BRC. local fbi = self:GetRadial( 1, false, false ) -- Stern coordinate. local st = self:_GetSternCoord() -- Zone points. local c1 = st:Translate( self.carrierparam.totwidthstarboard, fbi - 90 ) local c2 = st:Translate( UTILS.NMToMeters( 0.10 ), fbi - 90 ):Translate( UTILS.NMToMeters( 0.3 ), fbi ) local c3 = st:Translate( UTILS.NMToMeters( 0.25 ), fbi - 90 ):Translate( UTILS.NMToMeters( l ), fbi ) local c4 = st:Translate( UTILS.NMToMeters( w / 2 ), fbi + 90 ):Translate( UTILS.NMToMeters( l ), fbi ) local c5 = st:Translate( UTILS.NMToMeters( b ), fbi + 90 ):Translate( UTILS.NMToMeters( 0.3 ), fbi ) local c6 = st:Translate( self.carrierparam.totwidthport, fbi + 90 ) -- Vec2 array. local vec2 = { c1:GetVec2(), c2:GetVec2(), c3:GetVec2(), c4:GetVec2(), c5:GetVec2(), c6:GetVec2() } self.zoneGroove:UpdateFromVec2( vec2 ) -- Polygon zone. -- local zone=ZONE_POLYGON_BASE:New("Zone Groove", vec2) -- return zone return self.zoneGroove end --- Get Bullseye zone with radius 1 NM and DME 3 NM from the carrier. Radial depends on recovery case. -- @param #AIRBOSS self -- @param #number case Recovery case. -- @return Core.Zone#ZONE_RADIUS Arc in zone. function AIRBOSS:_GetZoneBullseye( case ) -- Radius = 1 NM. local radius = UTILS.NMToMeters( 1 ) -- Distance = 3 NM local distance = UTILS.NMToMeters( 3 ) -- Zone depends on Case recovery. local radial = self:GetRadial( case, false, false ) -- Get coordinate and vec2. local coord = self:GetCoordinate():Translate( distance, radial ) local vec2 = coord:GetVec2() -- Create zone. local zone = ZONE_RADIUS:New( "Zone Bullseye", vec2, radius ) return zone -- self.zoneBullseye=self.zoneBullseye or ZONE_RADIUS:New("Zone Bullseye", vec2, radius) end --- Get dirty up zone with radius 1 NM and DME 9 NM from the carrier. Radial depends on recovery case. -- @param #AIRBOSS self -- @param #number case Recovery case. -- @return Core.Zone#ZONE_RADIUS Dirty up zone. function AIRBOSS:_GetZoneDirtyUp( case ) -- Radius = 1 NM. local radius = UTILS.NMToMeters( 1 ) -- Distance = 9 NM local distance = UTILS.NMToMeters( 9 ) -- Zone depends on Case recovery. local radial = self:GetRadial( case, false, false ) -- Get coordinate and vec2. local coord = self:GetCoordinate():Translate( distance, radial ) local vec2 = coord:GetVec2() -- Create zone. local zone = ZONE_RADIUS:New( "Zone Dirty Up", vec2, radius ) return zone end --- Get arc out zone with radius 1 NM and DME 12 NM from the carrier. Radial depends on recovery case. -- @param #AIRBOSS self -- @param #number case Recovery case. -- @return Core.Zone#ZONE_RADIUS Arc in zone. function AIRBOSS:_GetZoneArcOut( case ) -- Radius = 1.25 NM. local radius = UTILS.NMToMeters( 1.25 ) -- Distance = 12 NM local distance = UTILS.NMToMeters( 11.75 ) -- Zone depends on Case recovery. local radial = self:GetRadial( case, false, false ) -- Get coordinate of carrier and translate. local coord = self:GetCoordinate():Translate( distance, radial ) -- Create zone. local zone = ZONE_RADIUS:New( "Zone Arc Out", coord:GetVec2(), radius ) return zone end --- Get arc in zone with radius 1 NM and DME 14 NM from the carrier. Radial depends on recovery case. -- @param #AIRBOSS self -- @param #number case Recovery case. -- @return Core.Zone#ZONE_RADIUS Arc in zone. function AIRBOSS:_GetZoneArcIn( case ) -- Radius = 1.25 NM. local radius = UTILS.NMToMeters( 1.25 ) -- Zone depends on Case recovery. local radial = self:GetRadial( case, false, true ) -- Angle between FB/BRC and holding zone. local alpha = math.rad( self.holdingoffset ) -- 14+x NM from carrier local x = 14 -- /math.cos(alpha) -- Distance = 14 NM local distance = UTILS.NMToMeters( x ) -- Get coordinate. local coord = self:GetCoordinate():Translate( distance, radial ) -- Create zone. local zone = ZONE_RADIUS:New( "Zone Arc In", coord:GetVec2(), radius ) return zone end --- Get platform zone with radius 1 NM and DME 19 NM from the carrier. Radial depends on recovery case. -- @param #AIRBOSS self -- @param #number case Recovery case. -- @return Core.Zone#ZONE_RADIUS Circular platform zone. function AIRBOSS:_GetZonePlatform( case ) -- Radius = 1 NM. local radius = UTILS.NMToMeters( 1 ) -- Zone depends on Case recovery. local radial = self:GetRadial( case, false, true ) -- Angle between FB/BRC and holding zone. local alpha = math.rad( self.holdingoffset ) -- Distance = 19 NM local distance = UTILS.NMToMeters( 19 ) -- /math.cos(alpha) -- Get coordinate. local coord = self:GetCoordinate():Translate( distance, radial ) -- Create zone. local zone = ZONE_RADIUS:New( "Zone Platform", coord:GetVec2(), radius ) return zone end --- Get approach corridor zone. Shape depends on recovery case. -- @param #AIRBOSS self -- @param #number case Recovery case. -- @param #number l Length of the zone in NM. Default 31 (=21+10) NM. -- @return Core.Zone#ZONE_POLYGON_BASE Box zone. function AIRBOSS:_GetZoneCorridor( case, l ) -- Total length. l = l or 31 -- Radial and offset. local radial = self:GetRadial( case, false, false ) local offset = self:GetRadial( case, false, true ) -- Distance shift ahead of carrier to allow for some space to bolter. local dx = 5 -- Width of the box in NM. local w = 2 local w2 = w / 2 -- Distance from carrier to arc out zone. local d = 12 -- Carrier position. local cv = self:GetCoordinate() -- Polygon points. local c = {} -- First point. Carrier coordinate translated 5 NM in direction of travel to allow for bolter space. c[1] = cv:Translate( -UTILS.NMToMeters( dx ), radial ) if math.abs( self.holdingoffset ) >= 5 then ----------------- -- Angled Case -- ----------------- c[2] = c[1]:Translate( UTILS.NMToMeters( w2 ), radial - 90 ) -- 1 Right of carrier, dx ahead. c[3] = c[2]:Translate( UTILS.NMToMeters( d + dx + w2 ), radial ) -- 13 "south" @ 1 right c[4] = cv:Translate( UTILS.NMToMeters( 15 ), offset ):Translate( UTILS.NMToMeters( 1 ), offset - 90 ) c[5] = cv:Translate( UTILS.NMToMeters( l ), offset ):Translate( UTILS.NMToMeters( 1 ), offset - 90 ) c[6] = cv:Translate( UTILS.NMToMeters( l ), offset ):Translate( UTILS.NMToMeters( 1 ), offset + 90 ) c[7] = cv:Translate( UTILS.NMToMeters( 13 ), offset ):Translate( UTILS.NMToMeters( 1 ), offset + 90 ) c[8] = cv:Translate( UTILS.NMToMeters( 11 ), radial ):Translate( UTILS.NMToMeters( 1 ), radial + 90 ) c[9] = c[1]:Translate( UTILS.NMToMeters( w2 ), radial + 90 ) else ----------------------------- -- Easy case of a long box -- ----------------------------- c[2] = c[1]:Translate( UTILS.NMToMeters( w2 ), radial - 90 ) c[3] = c[2]:Translate( UTILS.NMToMeters( dx + l ), radial ) -- Stack 1 starts at 21 and is 7 NM. c[4] = c[3]:Translate( UTILS.NMToMeters( w ), radial + 90 ) c[5] = c[1]:Translate( UTILS.NMToMeters( w2 ), radial + 90 ) end -- Create an array of a square! local p = {} for _i, _c in ipairs( c ) do if self.Debug then -- _c:SmokeBlue() end p[_i] = _c:GetVec2() end -- Square zone length=10NM width=6 NM behind the carrier starting at angels+15 NM behind the carrier. -- So stay 0-5 NM (+1 NM error margin) port of carrier. local zone = ZONE_POLYGON_BASE:New( "CASE II/III Approach Corridor", p ) return zone end --- Get zone of carrier. Carrier is approximated as rectangle. -- @param #AIRBOSS self -- @return Core.Zone#ZONE Zone surrounding the carrier. function AIRBOSS:_GetZoneCarrierBox() self.zoneCarrierbox = self.zoneCarrierbox or ZONE_POLYGON_BASE:New( "Carrier Box Zone" ) -- Stern coordinate. local S = self:_GetSternCoord() -- Current carrier heading. local hdg = self:GetHeading( false ) -- Coordinate array. local p = {} -- Starboard stern point. p[1] = S:Translate( self.carrierparam.totwidthstarboard, hdg + 90 ) -- Starboard bow point. p[2] = p[1]:Translate( self.carrierparam.totlength, hdg ) -- Port bow point. p[3] = p[2]:Translate( self.carrierparam.totwidthstarboard + self.carrierparam.totwidthport, hdg - 90 ) -- Port stern point. p[4] = p[3]:Translate( self.carrierparam.totlength, hdg - 180 ) -- Convert to vec2. local vec2 = {} for _, coord in ipairs( p ) do table.insert( vec2, coord:GetVec2() ) end -- Create polygon zone. -- local zone=ZONE_POLYGON_BASE:New("Carrier Box Zone", vec2) -- return zone self.zoneCarrierbox:UpdateFromVec2( vec2 ) return self.zoneCarrierbox end --- Get zone of landing runway. -- @param #AIRBOSS self -- @return Core.Zone#ZONE_POLYGON Zone surrounding landing runway. function AIRBOSS:_GetZoneRunwayBox() self.zoneRunwaybox = self.zoneRunwaybox or ZONE_POLYGON_BASE:New( "Landing Runway Zone" ) -- Stern coordinate. local S = self:_GetSternCoord() -- Current carrier heading. local FB = self:GetFinalBearing( false ) -- Coordinate array. local p = {} -- Points. p[1] = S:Translate( self.carrierparam.rwywidth * 0.5, FB + 90 ) p[2] = p[1]:Translate( self.carrierparam.rwylength, FB ) p[3] = p[2]:Translate( self.carrierparam.rwywidth, FB - 90 ) p[4] = p[3]:Translate( self.carrierparam.rwylength, FB - 180 ) -- Convert to vec2. local vec2 = {} for _, coord in ipairs( p ) do table.insert( vec2, coord:GetVec2() ) end -- Create polygon zone. -- local zone=ZONE_POLYGON_BASE:New("Landing Runway Zone", vec2) -- return zone self.zoneRunwaybox:UpdateFromVec2( vec2 ) return self.zoneRunwaybox end --- Get zone of primary abeam landing position of HMS Hermes, HMS Invincible, USS Tarawa, USS America and Juan Carlos. Box length 50 meters and width 30 meters. --- Allow for Clear to land call from LSO approaching abeam the landing spot if stable as per NATOPS 00-80T -- @param #AIRBOSS self -- @return Core.Zone#ZONE_POLYGON Zone surrounding landing runway. function AIRBOSS:_GetZoneAbeamLandingSpot() -- Primary landing Spot coordinate. local S = self:_GetOptLandingCoordinate() -- Current carrier heading. local FB = self:GetFinalBearing( false ) -- Coordinate array. Pene Testing extended Abeam landing spot V/STOL. local p={} -- Points. p[1] = S:Translate( 15, FB ):Translate( 15, FB + 90 ) -- Top-Right p[2] = S:Translate( -45, FB ):Translate( 15, FB + 90 ) -- Bottom-Right p[3] = S:Translate( -45, FB ):Translate( 15, FB - 90 ) -- Bottom-Left p[4] = S:Translate( 15, FB ):Translate( 15, FB - 90 ) -- Top-Left -- Convert to vec2. local vec2 = {} for _, coord in ipairs( p ) do table.insert( vec2, coord:GetVec2() ) end -- Create polygon zone. local zone = ZONE_POLYGON_BASE:New( "Abeam Landing Spot Zone", vec2 ) return zone end --- Get zone of the primary landing spot of the USS Tarawa. -- @param #AIRBOSS self -- @return Core.Zone#ZONE_POLYGON Zone surrounding landing runway. function AIRBOSS:_GetZoneLandingSpot() -- Primary landing Spot coordinate. local S = self:_GetLandingSpotCoordinate() -- Current carrier heading. local FB = self:GetFinalBearing( false ) -- Coordinate array. local p = {} -- Points. p[1] = S:Translate( 10, FB ):Translate( 10, FB + 90 ) -- Top-Right p[2] = S:Translate( -10, FB ):Translate( 10, FB + 90 ) -- Bottom-Right p[3] = S:Translate( -10, FB ):Translate( 10, FB - 90 ) -- Bottom-Left p[4] = S:Translate( 10, FB ):Translate( 10, FB - 90 ) -- Top-left -- Convert to vec2. local vec2 = {} for _, coord in ipairs( p ) do table.insert( vec2, coord:GetVec2() ) end -- Create polygon zone. local zone = ZONE_POLYGON_BASE:New( "Landing Spot Zone", vec2 ) return zone end --- Get holding zone of player. -- @param #AIRBOSS self -- @param #number case Recovery case. -- @param #number stack Marshal stack number. -- @return Core.Zone#ZONE Holding zone. function AIRBOSS:_GetZoneHolding( case, stack ) -- Holding zone. local zoneHolding = nil -- Core.Zone#ZONE -- Stack is <= 0 ==> no marshal zone. if stack <= 0 then self:E( self.lid .. "ERROR: Stack <= 0 in _GetZoneHolding!" ) self:E( { case = case, stack = stack } ) return nil end -- Pattern altitude. local patternalt, c1, c2 = self:_GetMarshalAltitude( stack, case ) -- Select case. if case == 1 then -- CASE I -- Get current carrier heading. local hdg = self:GetHeading() -- Distance to the post. local D = UTILS.NMToMeters( 2.5 ) -- Post 2.5 NM port of carrier. local Post = self:GetCoordinate():Translate( D, hdg + 270 ) -- TODO: update zone not creating a new one. -- Create holding zone. self.zoneHolding = ZONE_RADIUS:New( "CASE I Holding Zone", Post:GetVec2(), self.marshalradius ) -- Delta pattern. if self.carriertype == AIRBOSS.CarrierType.INVINCIBLE or self.carriertype == AIRBOSS.CarrierType.HERMES or self.carriertype == AIRBOSS.CarrierType.TARAWA or self.carriertype == AIRBOSS.CarrierType.AMERICA or self.carriertype == AIRBOSS.CarrierType.JCARLOS or self.carriertype == AIRBOSS.CarrierType.CANBERRA then self.zoneHolding = ZONE_RADIUS:New( "CASE I Holding Zone", self.carrier:GetVec2(), UTILS.NMToMeters( 5 ) ) end else -- CASE II/II -- Get radial. local radial = self:GetRadial( case, false, true ) -- Create an array of a rectangle. Length is 7 NM, width is 8 NM. One NM starboard to line up with the approach corridor. local p = {} p[1] = c2:Translate( UTILS.NMToMeters( 1 ), radial - 90 ):GetVec2() -- c2 is at (angels+15) NM directly behind the carrier. We translate it 1 NM starboard. p[2] = c1:Translate( UTILS.NMToMeters( 1 ), radial - 90 ):GetVec2() -- c1 is 7 NM further behind. Also translated 1 NM starboard. p[3] = c1:Translate( UTILS.NMToMeters( 7 ), radial + 90 ):GetVec2() -- p3 7 NM port of carrier. p[4] = c2:Translate( UTILS.NMToMeters( 7 ), radial + 90 ):GetVec2() -- p4 7 NM port of carrier. -- Square zone length=7NM width=6 NM behind the carrier starting at angels+15 NM behind the carrier. -- So stay 0-5 NM (+1 NM error margin) port of carrier. self.zoneHolding = self.zoneHolding or ZONE_POLYGON_BASE:New( "CASE II/III Holding Zone" ) self.zoneHolding:UpdateFromVec2( p ) end return self.zoneHolding end --- Get zone where player are automatically commence when enter. -- @param #AIRBOSS self -- @param #number case Recovery case. -- @param #number stack Stack for Case II/III as we commence from stack>=1. -- @return Core.Zone#ZONE Holding zone. function AIRBOSS:_GetZoneCommence( case, stack ) -- Commence zone. local zone if case == 1 then -- Case I -- Get current carrier heading. local hdg = self:GetHeading() -- Distance to the zone. local D = UTILS.NMToMeters( 4.75 ) -- Zone radius. local R = UTILS.NMToMeters( 1 ) -- Three position local Three = self:GetCoordinate():Translate( D, hdg + 275 ) if self.carriertype == AIRBOSS.CarrierType.INVINCIBLE or self.carriertype == AIRBOSS.CarrierType.HERMES or self.carriertype == AIRBOSS.CarrierType.TARAWA or self.carriertype == AIRBOSS.CarrierType.AMERICA or self.carriertype == AIRBOSS.CarrierType.JCARLOS or self.carriertype == AIRBOSS.CarrierType.CANBERRA then local Dx = UTILS.NMToMeters( 2.25 ) local Dz = UTILS.NMToMeters( 2.25 ) R = UTILS.NMToMeters( 1 ) Three = self:GetCoordinate():Translate( Dz, hdg - 90 ):Translate( Dx, hdg - 180 ) end -- Create holding zone. self.zoneCommence = self.zoneCommence or ZONE_RADIUS:New( "CASE I Commence Zone" ) self.zoneCommence:UpdateFromVec2( Three:GetVec2(), R ) else -- Case II/III stack = stack or 1 -- Start point at 21 NM for stack=1. local l = 20 + stack -- Offset angle local offset = self:GetRadial( case, false, true ) -- Carrier position. local cv = self:GetCoordinate() -- Polygon points. local c = {} c[1] = cv:Translate( UTILS.NMToMeters( l ), offset ):Translate( UTILS.NMToMeters( 1 ), offset - 90 ) c[2] = cv:Translate( UTILS.NMToMeters( l + 2.5 ), offset ):Translate( UTILS.NMToMeters( 1 ), offset - 90 ) c[3] = cv:Translate( UTILS.NMToMeters( l + 2.5 ), offset ):Translate( UTILS.NMToMeters( 1 ), offset + 90 ) c[4] = cv:Translate( UTILS.NMToMeters( l ), offset ):Translate( UTILS.NMToMeters( 1 ), offset + 90 ) -- Create an array of a square! local p = {} for _i, _c in ipairs( c ) do p[_i] = _c:GetVec2() end -- Zone polygon. self.zoneCommence = self.zoneCommence or ZONE_POLYGON_BASE:New( "CASE II/III Commence Zone" ) self.zoneCommence:UpdateFromVec2( p ) end return self.zoneCommence end ---------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- -- ORIENTATION functions ---------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- --- Provide info about player status on the fly. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data. function AIRBOSS:_AttitudeMonitor( playerData ) -- Player unit. local unit = playerData.unit -- Aircraft attitude. local aoa = unit:GetAoA() local yaw = unit:GetYaw() local roll = unit:GetRoll() local pitch = unit:GetPitch() -- Distance to the boat. local dist = playerData.unit:GetCoordinate():Get2DDistance( self:GetCoordinate() ) local dx, dz, rho, phi = self:_GetDistances( unit ) -- Wind vector. local wind = unit:GetCoordinate():GetWindWithTurbulenceVec3() -- Aircraft veloecity vector. local velo = unit:GetVelocityVec3() local vabs = UTILS.VecNorm( velo ) local rwy = false local step = playerData.step if playerData.step == AIRBOSS.PatternStep.FINAL or playerData.step == AIRBOSS.PatternStep.GROOVE_XX or playerData.step == AIRBOSS.PatternStep.GROOVE_IM or playerData.step == AIRBOSS.PatternStep.GROOVE_IC or playerData.step == AIRBOSS.PatternStep.GROOVE_AR or playerData.step == AIRBOSS.PatternStep.GROOVE_AL or playerData.step == AIRBOSS.PatternStep.GROOVE_LC or playerData.step == AIRBOSS.PatternStep.GROOVE_IW then step = self:_GS( step, -1 ) rwy = true end -- Relative heading Aircraft to Carrier. local relhead = self:_GetRelativeHeading( playerData.unit, rwy ) -- local lc=self:_GetOptLandingCoordinate() -- lc:FlareRed() -- Output local text = string.format( "Pattern step: %s", step ) text = text .. string.format( "\nAoA=%.1f° = %.1f Units | |V|=%.1f knots", aoa, self:_AoADeg2Units( playerData, aoa ), UTILS.MpsToKnots( vabs ) ) if self.Debug then -- Velocity vector. text = text .. string.format( "\nVx=%.1f Vy=%.1f Vz=%.1f m/s", velo.x, velo.y, velo.z ) -- Wind vector. text = text .. string.format( "\nWind Vx=%.1f Vy=%.1f Vz=%.1f m/s", wind.x, wind.y, wind.z ) end text = text .. string.format( "\nPitch=%.1f° | Roll=%.1f° | Yaw=%.1f°", pitch, roll, yaw ) text = text .. string.format( "\nClimb Angle=%.1f° | Rate=%d ft/min", unit:GetClimbAngle(), velo.y * 196.85 ) local dist = self:_GetOptLandingCoordinate():Get3DDistance( playerData.unit:GetVec3() ) -- Get player velocity in km/h. local vplayer = playerData.unit:GetVelocityKMH() -- Get carrier velocity in km/h. local vcarrier = self.carrier:GetVelocityKMH() -- Speed difference. local dv = math.abs( vplayer - vcarrier ) local alt = self:_GetAltCarrier( playerData.unit ) text = text .. string.format( "\nDist=%.1f m Alt=%.1f m delta|V|=%.1f km/h", dist, alt, dv ) -- If in the groove, provide line up and glide slope error. if playerData.step == AIRBOSS.PatternStep.FINAL or playerData.step == AIRBOSS.PatternStep.GROOVE_XX or playerData.step == AIRBOSS.PatternStep.GROOVE_IM or playerData.step == AIRBOSS.PatternStep.GROOVE_IC or playerData.step == AIRBOSS.PatternStep.GROOVE_AR or playerData.step == AIRBOSS.PatternStep.GROOVE_AL or playerData.step == AIRBOSS.PatternStep.GROOVE_LC or playerData.step == AIRBOSS.PatternStep.GROOVE_IW then local lue = self:_Lineup( playerData.unit, true ) local gle = self:_Glideslope( playerData.unit ) text = text .. string.format( "\nGamma=%.1f° | Rho=%.1f°", relhead, phi ) text = text .. string.format( "\nLineUp=%.2f° | GlideSlope=%.2f° | AoA=%.1f Units", lue, gle, self:_AoADeg2Units( playerData, aoa ) ) local grade, points, analysis = self:_LSOgrade( playerData ) text = text .. string.format( "\nTgroove=%.1f sec", self:_GetTimeInGroove( playerData ) ) text = text .. string.format( "\nGrade: %s %.1f PT - %s", grade, points, analysis ) else text = text .. string.format( "\nR=%.2f NM | X=%d Z=%d m", UTILS.MetersToNM( rho ), dx, dz ) text = text .. string.format( "\nGamma=%.1f° | Rho=%.1f°", relhead, phi ) end MESSAGE:New( text, 1, nil, true ):ToClient( playerData.client ) end --- Get glide slope of aircraft unit. -- @param #AIRBOSS self -- @param Wrapper.Unit#UNIT unit Aircraft unit. -- @param #number optangle (Optional) Return glide slope relative to this angle, i.e. the error from the optimal glide slope ~3.5 degrees. -- @return #number Glide slope angle in degrees measured from the deck of the carrier and third wire. function AIRBOSS:_Glideslope( unit, optangle ) if optangle == nil then if unit:GetTypeName() == AIRBOSS.AircraftCarrier.AV8B then optangle = 3.0 else optangle = 3.5 end end -- Landing coordinate local landingcoord = self:_GetOptLandingCoordinate() -- Distance from stern to aircraft. local x = unit:GetCoordinate():Get2DDistance( landingcoord ) -- Altitude of unit corrected by the deck height of the carrier. local h = self:_GetAltCarrier( unit ) -- Harrier should be 40-50 ft above the deck. if unit:GetTypeName() == AIRBOSS.AircraftCarrier.AV8B then h = unit:GetAltitude() - (UTILS.FeetToMeters( 50 ) + self.carrierparam.deckheight + 2) end -- Glide slope. local glideslope = math.atan( h / x ) -- Glide slope (error) in degrees. local gs = math.deg( glideslope ) - optangle return gs end --- Get glide slope of aircraft unit. -- @param #AIRBOSS self -- @param Wrapper.Unit#UNIT unit Aircraft unit. -- @param #number optangle (Optional) Return glide slope relative to this angle, i.e. the error from the optimal glide slope ~3.5 degrees. -- @return #number Glide slope angle in degrees measured from the deck of the carrier and third wire. function AIRBOSS:_Glideslope2( unit, optangle ) if optangle == nil then if unit:GetTypeName() == AIRBOSS.AircraftCarrier.AV8B then optangle = 3.0 else optangle = 3.5 end end -- Landing coordinate local landingcoord = self:_GetOptLandingCoordinate() -- Distance from stern to aircraft. local x = unit:GetCoordinate():Get3DDistance( landingcoord ) -- Altitude of unit corrected by the deck height of the carrier. local h = self:_GetAltCarrier( unit ) -- Harrier should be 40-50 ft above the deck. if unit:GetTypeName() == AIRBOSS.AircraftCarrier.AV8B then h = unit:GetAltitude() - (UTILS.FeetToMeters( 50 ) + self.carrierparam.deckheight + 2) end -- Glide slope. local glideslope = math.asin( h / x ) -- Glide slope (error) in degrees. local gs = math.deg( glideslope ) - optangle -- Debug. self:T3( self.lid .. string.format( "Glide slope error = %.1f, x=%.1f h=%.1f", gs, x, h ) ) return gs end --- Get line up of player wrt to carrier. -- @param #AIRBOSS self -- @param Wrapper.Unit#UNIT unit Aircraft unit. -- @param #boolean runway If true, include angled runway. -- @return #number Line up with runway heading in degrees. 0 degrees = perfect line up. +1 too far left. -1 too far right. function AIRBOSS:_Lineup( unit, runway ) -- Landing coordinate local landingcoord = self:_GetOptLandingCoordinate() -- Vector to landing coord. local A = landingcoord:GetVec3() -- Vector to player. local B = unit:GetVec3() -- Vector from player to carrier. local C = UTILS.VecSubstract( A, B ) -- Only in 2D plane. C.y = 0.0 -- Orientation of carrier. local X = self.carrier:GetOrientationX() X.y = 0.0 -- Rotate orientation to angled runway. if runway then X = UTILS.Rotate2D( X, -self.carrierparam.rwyangle ) end -- Projection of player pos on x component. local x = UTILS.VecDot( X, C ) -- Orientation of carrier. local Z = self.carrier:GetOrientationZ() Z.y = 0.0 -- Rotate orientation to angled runway. if runway then Z = UTILS.Rotate2D( Z, -self.carrierparam.rwyangle ) end -- Projection of player pos on z component. local z = UTILS.VecDot( Z, C ) --- local lineup = math.deg( math.atan2( z, x ) ) return lineup end --- Get altitude of aircraft wrt carrier deck. Should give zero when the aircraft touched down. -- @param #AIRBOSS self -- @param Wrapper.Unit#UNIT unit Aircraft unit. -- @return #number Altitude in meters wrt carrier height. function AIRBOSS:_GetAltCarrier( unit ) -- TODO: Value 4 meters is for the Hornet. Adjust for Harrier, A4E and -- Altitude of unit corrected by the deck height of the carrier. local h = unit:GetAltitude() - self.carrierparam.deckheight - 2 return h end --- Get optimal landing position of the aircraft. Usually between second and third wire. In case of Tarawa, Canberrra, Juan Carlos and America we take the abeam landing spot 120 ft above and 21 ft abeam the 7.5 position, for the Juan Carlos I, HMS Invincible, and HMS Hermes and Invincible it is 120 ft above and 21 ft abeam the 5 position. For CASE III it is 120ft directly above the landing spot. -- @param #AIRBOSS self -- @return Core.Point#COORDINATE Optimal landing coordinate. function AIRBOSS:_GetOptLandingCoordinate() -- Start with stern coordiante. self.landingcoord:UpdateFromCoordinate( self:_GetSternCoord() ) -- Final bearing. local FB=self:GetFinalBearing(false) -- Cse local case=self.case -- set Case III V/STOL abeam landing spot over deck -- Pene Testing if self.carriertype==AIRBOSS.CarrierType.INVINCIBLE or self.carriertype==AIRBOSS.CarrierType.HERMES or self.carriertype==AIRBOSS.CarrierType.TARAWA or self.carriertype==AIRBOSS.CarrierType.AMERICA or self.carriertype==AIRBOSS.CarrierType.JCARLOS or self.carriertype==AIRBOSS.CarrierType.CANBERRA then if case==3 then -- Landing coordinate. self.landingcoord:UpdateFromCoordinate(self:_GetLandingSpotCoordinate()) -- Altitude 120ft -- is this corect for Case III? self.landingcoord:SetAltitude(UTILS.FeetToMeters(120)) elseif case==2 or case==1 then -- Landing 100 ft abeam, 120 ft alt. self.landingcoord:UpdateFromCoordinate(self:_GetLandingSpotCoordinate()):Translate(35, FB-90, true, true) -- Alitude 120 ft. self.landingcoord:SetAltitude(UTILS.FeetToMeters(120)) end else -- Ideally we want to land between 2nd and 3rd wire. if self.carrierparam.wire3 then -- We take the position of the 3rd wire to approximately account for the length of the aircraft. self.landingcoord:Translate( self.carrierparam.wire3, FB, true, true ) end -- Add 2 meters to account for aircraft height. self.landingcoord.y = self.landingcoord.y + 2 end return self.landingcoord end --- Get landing spot on Tarawa and others. -- @param #AIRBOSS self -- @return Core.Point#COORDINATE Primary landing spot coordinate. function AIRBOSS:_GetLandingSpotCoordinate() -- Start at stern coordinate. self.landingspotcoord:UpdateFromCoordinate( self:_GetSternCoord() ) -- Landing 100 ft abeam, 100 alt. local hdg = self:GetHeading() -- Primary landing spot. Different carriers handled via carrier parameter landingspot now. self.landingspotcoord:Translate( self.carrierparam.landingspot, hdg, true, true ):SetAltitude( self.carrierparam.deckheight ) return self.landingspotcoord end --- Get true (or magnetic) heading of carrier. -- @param #AIRBOSS self -- @param #boolean magnetic If true, calculate magnetic heading. By default true heading is returned. -- @return #number Carrier heading in degrees. function AIRBOSS:GetHeading( magnetic ) self:F3( { magnetic = magnetic } ) -- Carrier heading local hdg = self.carrier:GetHeading() -- Include magnetic declination. if magnetic then hdg = hdg - self.magvar end -- Adjust negative values. if hdg < 0 then hdg = hdg + 360 end return hdg end --- Get base recovery course (BRC) of carrier. -- The is the magnetic heading of the carrier. -- @param #AIRBOSS self -- @return #number BRC in degrees. function AIRBOSS:GetBRC() return self:GetHeading( true ) end --- Get wind direction and speed at carrier position. -- @param #AIRBOSS self -- @param #number alt Altitude ASL in meters. Default 18 m. -- @param #boolean magnetic Direction including magnetic declination. -- @param Core.Point#COORDINATE coord (Optional) Coordinate at which to get the wind. Default is current carrier position. -- @return #number Direction the wind is blowing **from** in degrees. -- @return #number Wind speed in m/s. function AIRBOSS:GetWind( alt, magnetic, coord ) -- Current position of the carrier or input. local cv = coord or self:GetCoordinate() -- Wind direction and speed. By default at 18 meters ASL. local Wdir, Wspeed = cv:GetWind( alt or 18 ) -- Include magnetic declination. if magnetic then Wdir = Wdir - self.magvar -- Adjust negative values. if Wdir < 0 then Wdir = Wdir + 360 end end return Wdir, Wspeed end --- Get wind speed on carrier deck parallel and perpendicular to runway. -- @param #AIRBOSS self -- @param #number alt Altitude in meters. Default 18 m. -- @return #number Wind component parallel to runway im m/s. -- @return #number Wind component perpendicular to runway in m/s. -- @return #number Total wind strength in m/s. function AIRBOSS:GetWindOnDeck( alt ) -- Position of carrier. local cv = self:GetCoordinate() -- Velocity vector of carrier. local vc = self.carrier:GetVelocityVec3() -- Carrier orientation X. local xc = self.carrier:GetOrientationX() -- Carrier orientation Z. local zc = self.carrier:GetOrientationZ() -- Rotate back so that angled deck points to wind. xc = UTILS.Rotate2D( xc, -self.carrierparam.rwyangle ) zc = UTILS.Rotate2D( zc, -self.carrierparam.rwyangle ) -- Wind (from) vector local vw = cv:GetWindWithTurbulenceVec3( alt or 18 ) --(change made from 50m to 15m from Discord discussion from Sickdog, next change to 18m due to SC higher deck discord) -- Total wind velocity vector. -- Carrier velocity has to be negative. If carrier drives in the direction the wind is blowing from, we have less wind in total. local vT = UTILS.VecSubstract( vw, vc ) -- || Parallel component. local vpa = UTILS.VecDot( vT, xc ) -- == Perpendicular component. local vpp = UTILS.VecDot( vT, zc ) -- Strength. local vabs = UTILS.VecNorm( vT ) -- We return positive values as head wind and negative values as tail wind. -- TODO: Check minus sign. return -vpa, vpp, vabs end --- Get true (or magnetic) heading of carrier into the wind. This accounts for the angled runway. -- @param #AIRBOSS self -- @param #number vdeck Desired wind velocity over deck in knots. -- @param #boolean magnetic If true, calculate magnetic heading. By default true heading is returned. -- @param Core.Point#COORDINATE coord (Optional) Coordinate from which heading is calculated. Default is current carrier position. -- @return #number Carrier heading in degrees. -- @return #number Carrier speed in knots to reach desired wind speed on deck. function AIRBOSS:GetHeadingIntoWind(vdeck, magnetic, coord ) if self.intowindold then --env.info("FF use OLD into wind") return self:GetHeadingIntoWind_old(vdeck, magnetic, coord) else --env.info("FF use NEW into wind") return self:GetHeadingIntoWind_new(vdeck, magnetic, coord) end end --- Get true (or magnetic) heading of carrier into the wind. This accounts for the angled runway. -- @param #AIRBOSS self -- @param #number vdeck Desired wind velocity over deck in knots. -- @param #boolean magnetic If true, calculate magnetic heading. By default true heading is returned. -- @param Core.Point#COORDINATE coord (Optional) Coordinate from which heading is calculated. Default is current carrier position. -- @return #number Carrier heading in degrees. function AIRBOSS:GetHeadingIntoWind_old( vdeck, magnetic, coord ) local function adjustDegreesForWindSpeed(windSpeed) local degreesAdjustment = 0 -- the windspeeds are in m/s -- +0 degrees at 15m/s = 37kts -- +0 degrees at 14m/s = 35kts -- +0 degrees at 13m/s = 33kts -- +4 degrees at 12m/s = 31kts -- +4 degrees at 11m/s = 29kts -- +4 degrees at 10m/s = 27kts -- +4 degrees at 9m/s = 27kts -- +4 degrees at 8m/s = 27kts -- +8 degrees at 7m/s = 27kts -- +8 degrees at 6m/s = 27kts -- +8 degrees at 5m/s = 26kts -- +20 degrees at 4m/s = 26kts -- +20 degrees at 3m/s = 26kts -- +30 degrees at 2m/s = 26kts 1s if windSpeed > 0 and windSpeed < 3 then degreesAdjustment = 30 elseif windSpeed >= 3 and windSpeed < 5 then degreesAdjustment = 20 elseif windSpeed >= 5 and windSpeed < 8 then degreesAdjustment = 8 elseif windSpeed >= 8 and windSpeed < 13 then degreesAdjustment = 4 elseif windSpeed >= 13 then degreesAdjustment = 0 end return degreesAdjustment end -- Get direction the wind is blowing from. This is where we want to go. local windfrom, vwind = self:GetWind( nil, nil, coord ) -- Actually, we want the runway in the wind. local intowind = windfrom - self.carrierparam.rwyangle + adjustDegreesForWindSpeed(vwind) -- If no wind, take current heading. if vwind < 0.1 then intowind = self:GetHeading() end -- Magnetic heading. if magnetic then intowind = intowind - self.magvar end -- Adjust negative values. if intowind < 0 then intowind = intowind + 360 end -- Wind speed. --local _, vwind = self:GetWind() -- Speed of carrier in m/s but at least 4 knots. local vtot = math.max(vdeck-UTILS.MpsToKnots(vwind), 4) return intowind, vtot end --- Get true (or magnetic) heading of carrier into the wind. This accounts for the angled runway. -- Implementation based on [Mags & Bambi](https://magwo.github.io/carrier-cruise/). -- @param #AIRBOSS self -- @param #number vdeck Desired wind velocity over deck in knots. -- @param #boolean magnetic If true, calculate magnetic heading. By default true heading is returned. -- @param Core.Point#COORDINATE coord (Optional) Coordinate from which heading is calculated. Default is current carrier position. -- @return #number Carrier heading in degrees. -- @return #number Carrier speed in knots to reach desired wind speed on deck. function AIRBOSS:GetHeadingIntoWind_new( vdeck, magnetic, coord ) -- Default offset angle. local Offset=self.carrierparam.rwyangle or 0 -- Get direction the wind is blowing from. local windfrom, vwind=self:GetWind(18, nil ,coord) -- Ships min/max speed. local Vmin=4 local Vmax=UTILS.KmphToKnots(self.carrier:GetSpeedMax()) -- No wind. will stay on current heading. if vwind<0.1 then local h=self:GetHeading(magnetic) return h, math.min(vdeck, Vmax) end -- Convert wind speed to knots. vwind=UTILS.MpsToKnots(vwind) -- Wind to in knots. local windto=(windfrom+180)%360 -- Offset angle in rad. We also define the rotation to be clock-wise, which requires a minus sign. local alpha=math.rad(-Offset) -- Constant. local C = math.sqrt(math.cos(alpha)^2 / math.sin(alpha)^2 + 1) -- Upper limit of desired speed due to max boat speed. local vdeckMax=vwind + math.cos(alpha) * Vmax -- Lower limit of desired speed due to min boat speed. local vdeckMin=vwind + math.cos(alpha) * Vmin -- Speed of ship so it matches the desired speed. local v=0 -- Angle wrt. to wind TO-direction local theta=0 if vdeck>vdeckMax then -- Boat cannot go fast enough -- Set max speed. v=Vmax -- Calculate theta. theta = math.asin(v/(vwind*C)) - math.asin(-1/C) elseif vdeckvwind then -- Too little wind -- Set theta to 90° theta=math.pi/2 -- Set speed. v = math.sqrt(vdeck^2 - vwind^2) else -- Normal case theta = math.asin(vdeck * math.sin(alpha) / vwind) v = vdeck * math.cos(alpha) - vwind * math.cos(theta) end -- Magnetic heading. local magvar= magnetic and self.magvar or 0 -- Ship heading so cross wind is min for the given wind. local intowind = (540 + (windto - magvar + math.deg(theta) )) % 360 return intowind, v end --- Get base recovery course (BRC) when the carrier would head into the wind. -- This includes the current wind direction and accounts for the angled runway. -- @param #AIRBOSS self -- @param #number vdeck Desired wind velocity over deck in knots. -- @return #number BRC into the wind in degrees. function AIRBOSS:GetBRCintoWind(vdeck) -- BRC is the magnetic heading. return self:GetHeadingIntoWind(vdeck, true ) end --- Get final bearing (FB) of carrier. -- By default, the routine returns the magnetic FB depending on the current map (Caucasus, NTTR, Normandy, Persion Gulf etc). -- The true bearing can be obtained by setting the *TrueNorth* parameter to true. -- @param #AIRBOSS self -- @param #boolean magnetic If true, magnetic FB is returned. -- @return #number FB in degrees. function AIRBOSS:GetFinalBearing( magnetic ) -- First get the heading. local fb = self:GetHeading( magnetic ) -- Final baring = BRC including angled deck. fb = fb + self.carrierparam.rwyangle -- Adjust negative values. if fb < 0 then fb = fb + 360 end return fb end --- Get radial with respect to carrier BRC or FB and (optionally) holding offset. -- -- * case=1: radial=FB-180 -- * case=2: radial=HDG-180 (+offset) -- * case=3: radial=FB-180 (+offset) -- -- @param #AIRBOSS self -- @param #number case Recovery case. -- @param #boolean magnetic If true, magnetic radial is returned. Default is true radial. -- @param #boolean offset If true, inlcude holding offset. -- @param #boolean inverse Return inverse, i.e. radial-180 degrees. -- @return #number Radial in degrees. function AIRBOSS:GetRadial( case, magnetic, offset, inverse ) -- Case or current case. case = case or self.case -- Radial. local radial -- Select case. if case == 1 then -- Get radial. radial = self:GetFinalBearing( magnetic ) - 180 elseif case == 2 then -- Radial wrt to heading of carrier. radial = self:GetHeading( magnetic ) - 180 -- Holding offset angle (+-15 or 30 degrees usually) if offset then radial = radial + self.holdingoffset end elseif case == 3 then -- Radial wrt angled runway. radial = self:GetFinalBearing( magnetic ) - 180 -- Holding offset angle (+-15 or 30 degrees usually) if offset then radial = radial + self.holdingoffset end end -- Adjust for negative values. if radial < 0 then radial = radial + 360 end -- Inverse? if inverse then -- Inverse radial radial = radial - 180 -- Adjust for negative values. if radial < 0 then radial = radial + 360 end end return radial end --- Get difference between to headings in degrees taking into accound the [0,360) periodocity. -- @param #AIRBOSS self -- @param #number hdg1 Heading one. -- @param #number hdg2 Heading two. -- @return #number Difference between the two headings in degrees. function AIRBOSS:_GetDeltaHeading( hdg1, hdg2 ) local V = {} -- DCS#Vec3 V.x = math.cos( math.rad( hdg1 ) ) V.y = 0 V.z = math.sin( math.rad( hdg1 ) ) local W = {} -- DCS#Vec3 W.x = math.cos( math.rad( hdg2 ) ) W.y = 0 W.z = math.sin( math.rad( hdg2 ) ) local alpha = UTILS.VecAngle( V, W ) return alpha end --- Get relative heading of player wrt carrier. -- This is the angle between the direction/orientation vector of the carrier and the direction/orientation vector of the provided unit. -- Note that this is calculated in the X-Z plane, i.e. the altitude Y is not taken into account. -- @param #AIRBOSS self -- @param Wrapper.Unit#UNIT unit Player unit. -- @param #boolean runway (Optional) If true, return relative heading of unit wrt to angled runway of the carrier. -- @return #number Relative heading in degrees. An angle of 0 means, unit fly parallel to carrier. An angle of + or - 90 degrees means, unit flies perpendicular to carrier. function AIRBOSS:_GetRelativeHeading( unit, runway ) -- Direction vector of the carrier. local vC = self.carrier:GetOrientationX() -- Include runway angle. if runway then vC = UTILS.Rotate2D( vC, -self.carrierparam.rwyangle ) end -- Direction vector of the unit. local vP = unit:GetOrientationX() -- We only want the X-Z plane. Aircraft could fly parallel but ballistic and we dont want the "pitch" angle. vC.y = 0; vP.y = 0 -- Get angle between the two orientation vectors in degrees. local rhdg = UTILS.VecAngle( vC, vP ) -- Return heading in degrees. return rhdg end --- Get relative velocity of player unit wrt to carrier -- @param #AIRBOSS self -- @param Wrapper.Unit#UNIT unit Player unit. -- @return #number Relative velocity in m/s. function AIRBOSS:_GetRelativeVelocity( unit ) local vC = self.carrier:GetVelocityVec3() local vP = unit:GetVelocityVec3() -- Only X-Z plane is necessary here. vC.y = 0; vP.y = 0 local v = UTILS.VecSubstract( vP, vC ) return UTILS.VecNorm( v ), v end --- Calculate distances between carrier and aircraft unit. -- @param #AIRBOSS self -- @param Wrapper.Unit#UNIT unit Aircraft unit. -- @return #number Distance [m] in the direction of the orientation of the carrier. -- @return #number Distance [m] perpendicular to the orientation of the carrier. -- @return #number Distance [m] to the carrier. -- @return #number Angle [Deg] from carrier to plane. Phi=0 if the plane is directly behind the carrier, phi=90 if the plane is starboard, phi=180 if the plane is in front of the carrier. function AIRBOSS:_GetDistances( unit ) -- Vector to carrier local a = self.carrier:GetVec3() -- Vector to player local b = unit:GetVec3() -- Vector from carrier to player. local c = { x = b.x - a.x, y = 0, z = b.z - a.z } -- Orientation of carrier. local x = self.carrier:GetOrientationX() -- Projection of player pos on x component. local dx = UTILS.VecDot( x, c ) -- Orientation of carrier. local z = self.carrier:GetOrientationZ() -- Projection of player pos on z component. local dz = UTILS.VecDot( z, c ) -- Polar coordinates. local rho = math.sqrt( dx * dx + dz * dz ) -- Not exactly sure any more what I wanted to calculate here. local phi = math.deg( math.atan2( dz, dx ) ) -- Correct for negative values. if phi < 0 then phi = phi + 360 end return dx, dz, rho, phi end --- Check limits for reaching next step. -- @param #AIRBOSS self -- @param #number X X position of player unit. -- @param #number Z Z position of player unit. -- @param #AIRBOSS.Checkpoint check Checkpoint. -- @return #boolean If true, checkpoint condition for next step was reached. function AIRBOSS:_CheckLimits( X, Z, check ) -- Limits local nextXmin = check.LimitXmin == nil or (check.LimitXmin and (check.LimitXmin < 0 and X <= check.LimitXmin or check.LimitXmin >= 0 and X >= check.LimitXmin)) local nextXmax = check.LimitXmax == nil or (check.LimitXmax and (check.LimitXmax < 0 and X >= check.LimitXmax or check.LimitXmax >= 0 and X <= check.LimitXmax)) local nextZmin = check.LimitZmin == nil or (check.LimitZmin and (check.LimitZmin < 0 and Z <= check.LimitZmin or check.LimitZmin >= 0 and Z >= check.LimitZmin)) local nextZmax = check.LimitZmax == nil or (check.LimitZmax and (check.LimitZmax < 0 and Z >= check.LimitZmax or check.LimitZmax >= 0 and Z <= check.LimitZmax)) -- Proceed to next step if all conditions are fullfilled. local next = nextXmin and nextXmax and nextZmin and nextZmax -- Debug info. local text = string.format( "step=%s: next=%s: X=%d Xmin=%s Xmax=%s | Z=%d Zmin=%s Zmax=%s", check.name, tostring( next ), X, tostring( check.LimitXmin ), tostring( check.LimitXmax ), Z, tostring( check.LimitZmin ), tostring( check.LimitZmax ) ) self:T3( self.lid .. text ) return next end ------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- -- LSO functions ------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- --- LSO advice radio call. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data table. -- @param #number glideslopeError Error in degrees. -- @param #number lineupError Error in degrees. function AIRBOSS:_LSOadvice( playerData, glideslopeError, lineupError ) -- Advice time. local advice = 0 -- Glideslope high/low calls. if glideslopeError > self.gle.HIGH then -- 1.5 then -- "You're high!" self:RadioTransmission( self.LSORadio, self.LSOCall.HIGH, true, nil, nil, true ) advice = advice + self.LSOCall.HIGH.duration elseif glideslopeError > self.gle.High then -- 0.8 then -- "You're high." self:RadioTransmission( self.LSORadio, self.LSOCall.HIGH, false, nil, nil, true ) advice = advice + self.LSOCall.HIGH.duration elseif glideslopeError < self.gle.LOW then -- -0.9 then -- "Power!" self:RadioTransmission( self.LSORadio, self.LSOCall.POWER, true, nil, nil, true ) advice = advice + self.LSOCall.POWER.duration elseif glideslopeError < self.gle.Low then -- -0.6 then -- "Power." self:RadioTransmission( self.LSORadio, self.LSOCall.POWER, false, nil, nil, true ) advice = advice + self.LSOCall.POWER.duration else -- "Good altitude." end -- Lineup left/right calls. if lineupError < self.lue.LEFT then -- "Come left!" self:RadioTransmission( self.LSORadio, self.LSOCall.COMELEFT, true, nil, nil, true ) advice = advice + self.LSOCall.COMELEFT.duration elseif lineupError < self.lue.Left then -- "Come left." self:RadioTransmission( self.LSORadio, self.LSOCall.COMELEFT, false, nil, nil, true ) advice = advice + self.LSOCall.COMELEFT.duration elseif lineupError > self.lue.RIGHT then -- 3 then -- "Right for lineup!" self:RadioTransmission( self.LSORadio, self.LSOCall.RIGHTFORLINEUP, true, nil, nil, true ) advice = advice + self.LSOCall.RIGHTFORLINEUP.duration elseif lineupError > self.lue.Right then -- 1 then -- "Right for lineup." self:RadioTransmission( self.LSORadio, self.LSOCall.RIGHTFORLINEUP, false, nil, nil, true ) advice = advice + self.LSOCall.RIGHTFORLINEUP.duration else -- "Good lineup." end -- Get current AoA. local AOA = playerData.unit:GetAoA() -- Get aircraft AoA parameters. local acaoa = self:_GetAircraftAoA( playerData ) -- Speed via AoA - not for the Harrier. if playerData.actype ~= AIRBOSS.AircraftCarrier.AV8B then if AOA > acaoa.SLOW then -- "Your're slow!" self:RadioTransmission( self.LSORadio, self.LSOCall.SLOW, true, nil, nil, true ) advice = advice + self.LSOCall.SLOW.duration -- S=underline("SLO") elseif AOA > acaoa.Slow then -- "Your're slow." self:RadioTransmission( self.LSORadio, self.LSOCall.SLOW, false, nil, nil, true ) advice = advice + self.LSOCall.SLOW.duration -- S="SLO" elseif AOA > acaoa.OnSpeedMax then -- No call. -- S=little("SLO") elseif AOA < acaoa.FAST then -- "You're fast!" self:RadioTransmission( self.LSORadio, self.LSOCall.FAST, true, nil, nil, true ) advice = advice + self.LSOCall.FAST.duration -- S=underline("F") elseif AOA < acaoa.Fast then -- "You're fast." self:RadioTransmission( self.LSORadio, self.LSOCall.FAST, false, nil, nil, true ) advice = advice + self.LSOCall.FAST.duration -- S="F" elseif AOA < acaoa.OnSpeedMin then -- No Call. -- S=little("F") end end -- Set last time. playerData.Tlso = timer.getTime() end --- Grade player time in the groove - from turning to final until touchdown. -- -- If time -- -- * < 9 seconds: No Grade "--" -- * 9-11 seconds: Fair "(OK)" -- * 12-21 seconds: OK (15-18 is ideal) -- * 22-24 seconds: Fair "(OK) -- * > 24 seconds: No Grade "--" -- -- If you manage to be between 16.4 and and 16.6 seconds, you will even get and okay underline "\_OK\_". -- No groove time for Harrier on LHA, LHD set to Tgroove Unicorn as starting point to allow possible _OK_ 5.0. -- -- If time in the AV-8B -- -- * < 55 seconds: Fast V/STOL -- * < 75 seconds: OK V/STOL -- * > 76 Seconds: SLOW V/STOL (Early hover stop selection) -- -- If you manage to be between 60.0 and 65.0 seconds in the AV-8B, you will even get and okay underline "\_OK\_" -- -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data table. -- @return #string LSO grade for time in groove, i.e. \_OK\_, OK, (OK), --. function AIRBOSS:_EvalGrooveTime( playerData ) -- Time in groove. local t = playerData.Tgroove local grade = "" if t < 9 then grade = "_NESA_" elseif t < 15 then grade = "NESA" elseif t < 19 then grade = "OK Groove" elseif t <= 24 then grade = "(LIG)" -- Time in groove for AV-8B elseif playerData.actype == AIRBOSS.AircraftCarrier.AV8B and t < 55 then -- VSTOL Late Hover stop selection too fast to Abeam LDG Spot AV-8B. grade = "FAST V/STOL Groove" elseif playerData.actype == AIRBOSS.AircraftCarrier.AV8B and t < 75 then -- VSTOL Operations with AV-8B. grade = "OK V/STOL Groove" elseif playerData.actype == AIRBOSS.AircraftCarrier.AV8B and t >= 76 then -- VSTOL Early Hover stop selection slow to Abeam LDG Spot AV-8B. grade = "SLOW V/STOL Groove" else grade = "LIG" end -- The unicorn! if t >= 16.4 and t <= 16.6 then grade = "_OK_" end -- V/STOL Unicorn! if playerData.actype == AIRBOSS.AircraftCarrier.AV8B and (t >= 60.0 and t <= 65.0) then grade = "_OK_ V/STOL" end return grade end --- Grade approach. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data table. -- @return #string LSO grade, i.g. _OK_, OK, (OK), --, etc. -- @return #number Points. -- @return #string LSO analysis of flight path. function AIRBOSS:_LSOgrade( playerData ) --- Count deviations. local function count( base, pattern ) return select( 2, string.gsub( base, pattern, "" ) ) end -- Analyse flight data and convert to LSO text. local GXX, nXX = self:_Flightdata2Text( playerData, AIRBOSS.GroovePos.XX ) local GIM, nIM = self:_Flightdata2Text( playerData, AIRBOSS.GroovePos.IM ) local GIC, nIC = self:_Flightdata2Text( playerData, AIRBOSS.GroovePos.IC ) local GAR, nAR = self:_Flightdata2Text( playerData, AIRBOSS.GroovePos.AR ) -- VTOL approach, which is graded differently (currently only Harrier). local vtol=playerData.actype==AIRBOSS.AircraftCarrier.AV8B -- Put everything together. local G = GXX .. " " .. GIM .. " " .. " " .. GIC .. " " .. GAR -- Count number of minor/small nS, normal nN and major/large deviations nL. local N=nXX+nIM+nIC+nAR local nL=count(G, '_')/2 local nS=count(G, '%(') local nN=N-nS-nL -- Groove time 15-18.99 sec for a unicorn. Or 60-65 for V/STOL unicorn. local Tgroove=playerData.Tgroove local TgrooveUnicorn=Tgroove and (Tgroove>=15.0 and Tgroove<=18.99) or false local TgrooveVstolUnicorn=Tgroove and (Tgroove>=60.0 and Tgroove<=65.0)and playerData.actype==AIRBOSS.AircraftCarrier.AV8B or false local grade local points if N == 0 and (TgrooveUnicorn or TgrooveVstolUnicorn or playerData.case==3) then -- No deviations, should be REALLY RARE! grade = "_OK_" points = 5.0 G = "Unicorn" else if vtol then -- Add AV-8B Harrier devation allowances due to lower groundspeed and 3x conventional groove time, this allows to maintain LSO tolerances while respecting the deviations are not unsafe.--Pene testing -- Large devaitions still result in a No Grade, A Unicorn still requires a clean pass with no deviation. -- Normal laning part at the beginning local Gb = GXX .. " " .. GIM -- Number of deviations that occurred at the the beginning of the landing (XX or IM). These are graded like in non-VTOL landings, i.e. on deviations is local N=nXX+nIM local nL=count(Gb, '_')/2 local nS=count(Gb, '%(') local nN=N-nS-nL -- VTOL part of the landing local Gv = GIC .. " " .. GAR -- Number of deviations that occurred at the the end (VTOL part) of the landing (IC or AR). local Nv=nIC+nAR local nLv=count(Gv, '_')/2 local nSv=count(Gv, '%(') local nNv=Nv-nSv-nLv if nL>0 or nLv>1 then -- Larger deviations at XX or IM or at least one larger deviation IC or AR==> "No grade" 2.0 points. -- In other words, we allow one larger deviation at IC+AR grade="--" points=2.0 elseif nN>0 or nNv>1 or nLv==1 then -- Average deviations at XX+IM or more than one normal deviation IC or AR ==> "Fair Pass" Pass with average deviations and corrections. grade="(OK)" points=3.0 else -- Only minor corrections grade="OK" points=4.0 end else -- This is a normal (non-VTOL) landing. if nL > 0 then -- Larger deviations ==> "No grade" 2.0 points. grade="--" points=2.0 elseif nN> 0 then -- No larger but average/normal deviations ==> "Fair Pass" Pass with average deviations and corrections. grade="(OK)" points=3.0 else -- Only minor corrections ==> "Okay pass" 4.0 points. grade="OK" points=4.0 end end end -- Replace" )"( and "__" G = G:gsub( "%)%(", "" ) G = G:gsub( "__", "" ) -- Debug info local text = "LSO grade:\n" text = text .. G .. "\n" text = text .. "Grade = " .. grade .. " points = " .. points .. "\n" text = text .. "# of total deviations = " .. N .. "\n" text = text .. "# of large deviations _ = " .. nL .. "\n" text = text .. "# of normal deviations = " .. nN .. "\n" text = text .. "# of small deviations ( = " .. nS .. "\n" self:T2( self.lid .. text ) -- Special cases. if playerData.wop then --------------------- -- Pattern Waveoff -- --------------------- if playerData.lig then -- Long In the Groove (LIG). -- According to Stingers this is a CUT pass and gives 1.0 points. grade = "WO" points = 1.0 G = "LIG" else -- Other pattern WO grade = "WOP" points = 2.0 G = "n/a" end elseif playerData.wofd then ----------------------- -- Foul Deck Waveoff -- ----------------------- if playerData.landed then -- AIRBOSS wants to talk to you! grade = "CUT" points = 0.0 else grade = "WOFD" points = -1.0 end G = "n/a" elseif playerData.owo then ----------------- -- Own Waveoff -- ----------------- grade = "OWO" points = 2.0 if N == 0 then G = "n/a" end elseif playerData.waveoff then ------------- -- Waveoff -- ------------- if playerData.landed then -- AIRBOSS wants to talk to you! grade = "CUT" points = 0.0 else grade = "WO" points = 1.0 end elseif playerData.boltered then -- Bolter grade = "-- (BOLTER)" points = 2.5 elseif not playerData.hover and playerData.actype == AIRBOSS.AircraftCarrier.AV8B then ------------------------------- -- AV-8B not cleared to land -- -- Landing clearence is carrier from LC to Landing ------------------------------- if playerData.landed then -- AIRBOSS wants your balls! grade = "CUT" points = 0.0 end end return grade, points, G end --- Grade flight data. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data. -- @param #string groovestep Step in the groove. -- @param #AIRBOSS.GrooveData fdata Flight data in the groove. -- @return #string LSO grade or empty string if flight data table is nil. -- @return #number Number of deviations from perfect flight path. function AIRBOSS:_Flightdata2Text( playerData, groovestep ) local function little( text ) return string.format( "(%s)", text ) end local function underline( text ) return string.format( "_%s_", text ) end -- Groove Data. local fdata = playerData.groove[groovestep] -- #AIRBOSS.GrooveData -- No flight data ==> return empty string. if fdata == nil then self:T3( self.lid .. "Flight data is nil." ) return "", 0 end -- Flight data. local step = fdata.Step local AOA = fdata.AoA local GSE = fdata.GSE local LUE = fdata.LUE local ROL = fdata.Roll -- Aircraft specific AoA values. local acaoa = self:_GetAircraftAoA( playerData ) -- Angled Approach. local P = nil if step == AIRBOSS.PatternStep.GROOVE_XX and ROL <= 4.0 and playerData.case < 3 then if LUE > self.lue.RIGHT then P = underline( "AA" ) elseif LUE > self.lue.RightMed then P = "AA " elseif LUE > self.lue.Right then P = little( "AA" ) end end -- Overshoot Start. local O = nil if step == AIRBOSS.PatternStep.GROOVE_XX then if LUE < self.lue.LEFT then O = underline( "OS" ) elseif LUE < self.lue.Left then O = "OS" elseif LUE < self.lue._min then O = little( "OS" ) end end -- Speed via AoA. Depends on aircraft type. local S = nil if AOA > acaoa.SLOW then S = underline( "SLO" ) elseif AOA > acaoa.Slow then S = "SLO" elseif AOA > acaoa.OnSpeedMax then S = little( "SLO" ) elseif AOA < acaoa.FAST then S = underline( "F" ) elseif AOA < acaoa.Fast then S = "F" elseif AOA < acaoa.OnSpeedMin then S = little( "F" ) end -- Glideslope/altitude. Good [-0.3, 0.4] asymmetric! local A = nil if GSE > self.gle.HIGH then A = underline( "H" ) elseif GSE > self.gle.High then A = "H" elseif GSE > self.gle._max then A = little( "H" ) elseif GSE < self.gle.LOW then A = underline( "LO" ) elseif GSE < self.gle.Low then A = "LO" elseif GSE < self.gle._min then A = little( "LO" ) end -- Line up. XX Step replaced by Overshoot start (OS). Good [-0.5, 0.5] local D = nil if LUE > self.lue.RIGHT then D = underline( "LUL" ) elseif LUE > self.lue.Right then D = "LUL" elseif LUE > self.lue._max then D = little( "LUL" ) elseif playerData.case < 3 then if LUE < self.lue.LEFT and step ~= AIRBOSS.PatternStep.GROOVE_XX then D = underline( "LUR" ) elseif LUE < self.lue.Left and step ~= AIRBOSS.PatternStep.GROOVE_XX then D = "LUR" elseif LUE < self.lue._min and step ~= AIRBOSS.PatternStep.GROOVE_XX then D = little( "LUR" ) end elseif playerData.case == 3 then if LUE < self.lue.LEFT then D = underline( "LUR" ) elseif LUE < self.lue.Left then D = "LUR" elseif LUE < self.lue._min then D = little( "LUR" ) end end -- Compile. local G = "" local n = 0 -- Fly trough. if fdata.FlyThrough then G = G .. fdata.FlyThrough end -- Angled Approach - doesn't affect score, advisory only. if P then G = G .. P n = n end -- Speed. if S then G = G .. S n = n + 1 end -- Glide slope. if A then G = G .. A n = n + 1 end -- Line up. if D then G = G .. D n = n + 1 end -- Drift in Lineup if fdata.Drift then G = G .. fdata.Drift n = n -- Drift doesn't affect score, advisory only. end -- Overshoot. if O then G = G .. O n = n + 1 end -- Add current step. local step = self:_GS( step ) step = step:gsub( "XX", "X" ) if G ~= "" then G = G .. step end -- Debug info. local text = string.format( "LSO Grade at %s:\n", step ) text = text .. string.format( "AOA=%.1f\n", AOA ) text = text .. string.format( "GSE=%.1f\n", GSE ) text = text .. string.format( "LUE=%.1f\n", LUE ) text = text .. string.format( "ROL=%.1f\n", ROL ) text = text .. G self:T3( self.lid .. text ) return G, n end --- Get short name of the grove step. -- @param #AIRBOSS self -- @param #string step Player step. -- @param #number n Use -1 for previous or +1 for next. Default 0. -- @return #string Shortcut name "X", "RB", "IM", "AR", "IW". function AIRBOSS:_GS( step, n ) local gp n = n or 0 if step == AIRBOSS.PatternStep.FINAL then gp = AIRBOSS.GroovePos.X0 -- "X0" -- Entering the groove. if n == -1 then gp = AIRBOSS.GroovePos.X0 -- There is no previous step. elseif n == 1 then gp = AIRBOSS.GroovePos.XX end elseif step == AIRBOSS.PatternStep.GROOVE_XX then gp = AIRBOSS.GroovePos.XX -- "XX" -- Starting the groove. if n == -1 then gp = AIRBOSS.GroovePos.X0 elseif n == 1 then gp = AIRBOSS.GroovePos.IM end elseif step == AIRBOSS.PatternStep.GROOVE_IM then gp = AIRBOSS.GroovePos.IM -- "IM" -- In the middle. if n == -1 then gp = AIRBOSS.GroovePos.XX elseif n == 1 then gp = AIRBOSS.GroovePos.IC end elseif step == AIRBOSS.PatternStep.GROOVE_IC then gp = AIRBOSS.GroovePos.IC -- "IC" -- In close. if n == -1 then gp = AIRBOSS.GroovePos.IM elseif n == 1 then gp = AIRBOSS.GroovePos.AR end elseif step == AIRBOSS.PatternStep.GROOVE_AR then gp = AIRBOSS.GroovePos.AR -- "AR" -- At the ramp. if n == -1 then gp = AIRBOSS.GroovePos.IC elseif n == 1 then if self.carriertype == AIRBOSS.CarrierType.INVINCIBLE or self.carriertype == AIRBOSS.CarrierType.HERMES or self.carriertype == AIRBOSS.CarrierType.TARAWA or self.carriertype == AIRBOSS.CarrierType.AMERICA or self.carriertype == AIRBOSS.CarrierType.JCARLOS or self.carriertype == AIRBOSS.CarrierType.CANBERRA then gp = AIRBOSS.GroovePos.AL else gp = AIRBOSS.GroovePos.IW end end elseif step == AIRBOSS.PatternStep.GROOVE_AL then gp = AIRBOSS.GroovePos.AL -- "AL" -- Abeam landing spot. if n == -1 then gp = AIRBOSS.GroovePos.AR elseif n == 1 then gp = AIRBOSS.GroovePos.LC end elseif step == AIRBOSS.PatternStep.GROOVE_LC then gp = AIRBOSS.GroovePos.LC -- "LC" -- Level crossing. if n == -1 then gp = AIRBOSS.GroovePos.AL elseif n == 1 then gp = AIRBOSS.GroovePos.LC end elseif step == AIRBOSS.PatternStep.GROOVE_IW then gp = AIRBOSS.GroovePos.IW -- "IW" -- In the wires. if n == -1 then gp = AIRBOSS.GroovePos.AR elseif n == 1 then gp = AIRBOSS.GroovePos.IW -- There is no next step. end end return gp end --- Check if a player is within the right area. -- @param #AIRBOSS self -- @param #number X X distance player to carrier. -- @param #number Z Z distance player to carrier. -- @param #AIRBOSS.Checkpoint pos Position data limits. -- @return #boolean If true, approach should be aborted. function AIRBOSS:_CheckAbort( X, Z, pos ) local abort = false if pos.Xmin and X < pos.Xmin then self:T( string.format( "Xmin: X=%d < %d=Xmin", X, pos.Xmin ) ) abort = true elseif pos.Xmax and X > pos.Xmax then self:T( string.format( "Xmax: X=%d > %d=Xmax", X, pos.Xmax ) ) abort = true elseif pos.Zmin and Z < pos.Zmin then self:T( string.format( "Zmin: Z=%d < %d=Zmin", Z, pos.Zmin ) ) abort = true elseif pos.Zmax and Z > pos.Zmax then self:T( string.format( "Zmax: Z=%d > %d=Zmax", Z, pos.Zmax ) ) abort = true end return abort end --- Generate a text if a player is too far from where he should be. -- @param #AIRBOSS self -- @param #number X X distance player to carrier. -- @param #number Z Z distance player to carrier. -- @param #AIRBOSS.Checkpoint posData Checkpoint data. function AIRBOSS:_TooFarOutText( X, Z, posData ) -- Intro. local text = "you are too " -- X text. local xtext = nil if posData.Xmin and X < posData.Xmin then if posData.Xmin <= 0 then xtext = "far behind " else xtext = "close to " end elseif posData.Xmax and X > posData.Xmax then if posData.Xmax >= 0 then xtext = "far ahead of " else xtext = "close to " end end -- Z text. local ztext = nil if posData.Zmin and Z < posData.Zmin then if posData.Zmin <= 0 then ztext = "far port of " else ztext = "close to " end elseif posData.Zmax and Z > posData.Zmax then if posData.Zmax >= 0 then ztext = "far starboard of " else ztext = "too close to " end end -- Combine X-Z text. if xtext and ztext then text = text .. xtext .. " and " .. ztext elseif xtext then text = text .. xtext elseif ztext then text = text .. ztext end -- Complete the sentence text = text .. "the carrier." -- If no case could be identified. if xtext == nil and ztext == nil then text = "you are too far from where you should be!" end return text end --- Pattern aborted. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data. -- @param #number X X distance player to carrier. -- @param #number Z Z distance player to carrier. -- @param #AIRBOSS.Checkpoint posData Checkpoint data. -- @param #boolean patternwo (Optional) Pattern wave off. function AIRBOSS:_AbortPattern( playerData, X, Z, posData, patternwo ) -- Text where we are wrong. local text = self:_TooFarOutText( X, Z, posData ) -- Debug. local dtext = string.format( "Abort: X=%d Xmin=%s, Xmax=%s | Z=%d Zmin=%s Zmax=%s", X, tostring( posData.Xmin ), tostring( posData.Xmax ), Z, tostring( posData.Zmin ), tostring( posData.Zmax ) ) self:T( self.lid .. dtext ) -- Message to player. self:MessageToPlayer( playerData, text, "LSO" ) if patternwo then -- Pattern wave off! playerData.wop = true -- Add to debrief. self:_AddToDebrief( playerData, string.format( "Pattern wave off: %s", text ) ) -- Depart and re-enter radio message. -- TODO: Radio should depend on player step. self:RadioTransmission( self.LSORadio, self.LSOCall.DEPARTANDREENTER, false, 3, nil, nil, true ) -- Next step debrief. playerData.step = AIRBOSS.PatternStep.DEBRIEF playerData.warning = nil end end --- Display hint to player. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data table. -- @param #number delay Delay before playing sound messages. Default 0 sec. -- @param #boolean soundoff If true, don't play and sound hint. function AIRBOSS:_PlayerHint( playerData, delay, soundoff ) -- No hint for the pros. if not playerData.showhints then return end -- Get optimal altitude, distance and speed. local alt, aoa, dist, speed = self:_GetAircraftParameters( playerData ) -- Get altitude hint. local hintAlt, debriefAlt, callAlt = self:_AltitudeCheck( playerData, alt ) -- Get speed hint. local hintSpeed, debriefSpeed, callSpeed = self:_SpeedCheck( playerData, speed ) -- Get AoA hint. local hintAoA, debriefAoA, callAoA = self:_AoACheck( playerData, aoa ) -- Get distance to the boat hint. local hintDist, debriefDist, callDist = self:_DistanceCheck( playerData, dist ) -- Message to player. local hint = "" if hintAlt and hintAlt ~= "" then hint = hint .. "\n" .. hintAlt end if hintSpeed and hintSpeed ~= "" then hint = hint .. "\n" .. hintSpeed end if hintAoA and hintAoA ~= "" then hint = hint .. "\n" .. hintAoA end if hintDist and hintDist ~= "" then hint = hint .. "\n" .. hintDist end -- Debriefing text. local debrief = "" if debriefAlt and debriefAlt ~= "" then debrief = debrief .. "\n- " .. debriefAlt end if debriefSpeed and debriefSpeed ~= "" then debrief = debrief .. "\n- " .. debriefSpeed end if debriefAoA and debriefAoA ~= "" then debrief = debrief .. "\n- " .. debriefAoA end if debriefDist and debriefDist ~= "" then debrief = debrief .. "\n- " .. debriefDist end -- Add step to debriefing. if debrief ~= "" then self:_AddToDebrief( playerData, debrief ) end -- Voice hint. delay = delay or 0 if not soundoff then if callAlt then self:Sound2Player( playerData, self.LSORadio, callAlt, false, delay ) delay = delay + callAlt.duration + 0.5 end if callSpeed then self:Sound2Player( playerData, self.LSORadio, callSpeed, false, delay ) delay = delay + callSpeed.duration + 0.5 end if callAoA then self:Sound2Player( playerData, self.LSORadio, callAoA, false, delay ) delay = delay + callAoA.duration + 0.5 end if callDist then self:Sound2Player( playerData, self.LSORadio, callDist, false, delay ) delay = delay + callDist.duration + 0.5 end end -- ARC IN info. if playerData.step == AIRBOSS.PatternStep.ARCIN then -- Hint turn and set TACAN. if playerData.difficulty == AIRBOSS.Difficulty.EASY then -- Get inverse magnetic radial without offset ==> FB for Case II or BRC for Case III. local radial = self:GetRadial( playerData.case, true, false, true ) local turn = "right" if self.holdingoffset < 0 then turn = "left" end hint = hint .. string.format( "\nTurn %s and select TACAN %03d°.", turn, radial ) end end -- DIRTUP additonal info. if playerData.step == AIRBOSS.PatternStep.DIRTYUP then if playerData.difficulty == AIRBOSS.Difficulty.EASY then if playerData.actype == AIRBOSS.AircraftCarrier.AV8B then hint = hint .. "\nFAF! Checks completed. Nozzles 50°." else -- TODO: Tomcat? hint = hint .. "\nDirty up! Hook, gear and flaps down." end end end -- BULLSEYE additonal info. if playerData.step == AIRBOSS.PatternStep.BULLSEYE then -- Hint follow the needles. if playerData.difficulty == AIRBOSS.Difficulty.EASY then if playerData.actype == AIRBOSS.AircraftCarrier.HORNET or playerData.actype == AIRBOSS.AircraftCarrier.RHINOE or playerData.actype == AIRBOSS.AircraftCarrier.RHINOF or playerData.actype == AIRBOSS.AircraftCarrier.GROWLER then hint = hint .. string.format( "\nIntercept glideslope and follow the needles." ) else hint = hint .. string.format( "\nIntercept glideslope." ) end end end -- Message to player. if hint ~= "" then local text = string.format( "%s%s", playerData.step, hint ) self:MessageToPlayer( playerData, hint, "AIRBOSS", "" ) end end --- Display hint for flight students about the (next) step. Message is displayed after one second. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data. -- @param #string step Step for which hint is given. function AIRBOSS:_StepHint( playerData, step ) -- Set step. step = step or playerData.step -- Message is only for "Flight Students". if playerData.difficulty == AIRBOSS.Difficulty.EASY and playerData.showhints then -- Get optimal parameters at step. local alt, aoa, dist, speed = self:_GetAircraftParameters( playerData, step ) -- Hint: local hint = "" -- Altitude. if alt then hint = hint .. string.format( "\nAltitude %d ft", UTILS.MetersToFeet( alt ) ) end -- AoA. if aoa then hint = hint .. string.format( "\nAoA %.1f", self:_AoADeg2Units( playerData, aoa ) ) end -- Speed. if speed then hint = hint .. string.format( "\nSpeed %d knots", UTILS.MpsToKnots( speed ) ) end -- Distance to the boat. if dist then hint = hint .. string.format( "\nDistance to the boat %.1f NM", UTILS.MetersToNM( dist ) ) end -- Late break. if step == AIRBOSS.PatternStep.LATEBREAK then if playerData.actype == AIRBOSS.AircraftCarrier.F14A or playerData.actype == AIRBOSS.AircraftCarrier.F14B then hint = hint .. "\nWing Sweep 20°, Gear DOWN < 280 KIAS." end end -- Abeam. if step == AIRBOSS.PatternStep.ABEAM then if playerData.actype == AIRBOSS.AircraftCarrier.AV8B then hint = hint .. "\nNozzles 50°-60°. Antiskid OFF. Lights OFF." elseif playerData.actype == AIRBOSS.AircraftCarrier.F14A or playerData.actype == AIRBOSS.AircraftCarrier.F14B then hint = hint .. "\nSlats/Flaps EXTENDED < 225 KIAS. DLC SELECTED. Auto Throttle IF DESIRED." else hint = hint .. "\nDirty up! Gear DOWN, flaps DOWN. Check hook down." end end -- Check if there was actually anything to tell. if hint ~= "" then -- Compile text if any. local text = string.format( "Optimal setup at next step %s:%s", step, hint ) -- Send hint to player. self:MessageToPlayer( playerData, text, "AIRBOSS", "", nil, false, 1 ) end end end --- Evaluate player's altitude at checkpoint. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data table. -- @param #number altopt Optimal altitude in meters. -- @return #string Feedback text. -- @return #string Debriefing text. -- @return #AIRBOSS.RadioCall Radio call. function AIRBOSS:_AltitudeCheck( playerData, altopt ) if altopt == nil then return nil, nil end -- Player altitude. local altitude = playerData.unit:GetAltitude() -- Get relative score. local lowscore, badscore = self:_GetGoodBadScore( playerData ) -- Altitude error +-X% local _error = (altitude - altopt) / altopt * 100 -- Radio call for flight students. local radiocall = nil -- #AIRBOSS.RadioCall local hint = "" if _error > badscore then -- hint=string.format("You're high.") radiocall = self:_NewRadioCall( self.LSOCall.HIGH, "Paddles", "" ) elseif _error > lowscore then -- hint= string.format("You're slightly high.") radiocall = self:_NewRadioCall( self.LSOCall.HIGH, "Paddles", "" ) elseif _error < -badscore then -- hint=string.format("You're low. ") radiocall = self:_NewRadioCall( self.LSOCall.LOW, "Paddles", "" ) elseif _error < -lowscore then -- hint=string.format("You're slightly low.") radiocall = self:_NewRadioCall( self.LSOCall.LOW, "Paddles", "" ) else hint = string.format( "Good altitude. " ) end -- Extend or decrease depending on skill. if playerData.difficulty == AIRBOSS.Difficulty.EASY then -- Also inform students about the optimal altitude. hint = hint .. string.format( "Optimal altitude is %d ft.", UTILS.MetersToFeet( altopt ) ) elseif playerData.difficulty == AIRBOSS.Difficulty.NORMAL then -- We keep it short normally. hint = "" elseif playerData.difficulty == AIRBOSS.Difficulty.HARD then -- No hint at all for the pros. hint = "" end -- Debrief text. local debrief = string.format( "Altitude %d ft = %d%% deviation from %d ft.", UTILS.MetersToFeet( altitude ), _error, UTILS.MetersToFeet( altopt ) ) return hint, debrief, radiocall end --- Score for correct AoA. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data. -- @param #number optaoa Optimal AoA. -- @return #string Feedback message text or easy and normal difficulty level or nil for hard. -- @return #string Debriefing text. -- @return #AIRBOSS.RadioCall Radio call. function AIRBOSS:_AoACheck( playerData, optaoa ) if optaoa == nil then return nil, nil end -- Get relative score. local lowscore, badscore = self:_GetGoodBadScore( playerData ) -- Player AoA local aoa = playerData.unit:GetAoA() -- Altitude error +-X% local _error = (aoa - optaoa) / optaoa * 100 -- Get aircraft AoA parameters. local aircraftaoa = self:_GetAircraftAoA( playerData ) -- Radio call for flight students. local radiocall = nil -- #AIRBOSS.RadioCall -- Rate aoa. local hint = "" if aoa >= aircraftaoa.SLOW then -- hint="Your're slow!" radiocall = self:_NewRadioCall( self.LSOCall.SLOW, "Paddles", "" ) elseif aoa >= aircraftaoa.Slow then -- hint="Your're slow." radiocall = self:_NewRadioCall( self.LSOCall.SLOW, "Paddles", "" ) elseif aoa >= aircraftaoa.OnSpeedMax then hint = "Your're a little slow. " elseif aoa >= aircraftaoa.OnSpeedMin then hint = "You're on speed. " elseif aoa >= aircraftaoa.Fast then hint = "You're a little fast. " elseif aoa >= aircraftaoa.FAST then -- hint="Your're fast." radiocall = self:_NewRadioCall( self.LSOCall.FAST, "Paddles", "" ) else -- hint="You're fast!" radiocall = self:_NewRadioCall( self.LSOCall.FAST, "Paddles", "" ) end -- Extend or decrease depending on skill. if playerData.difficulty == AIRBOSS.Difficulty.EASY then -- Also inform students about optimal value. hint = hint .. string.format( "Optimal AoA is %.1f.", self:_AoADeg2Units( playerData, optaoa ) ) elseif playerData.difficulty == AIRBOSS.Difficulty.NORMAL then -- We keep is short normally. hint = "" elseif playerData.difficulty == AIRBOSS.Difficulty.HARD then -- No hint at all for the pros. hint = "" end -- Debriefing text. local debrief = string.format( "AoA %.1f = %d%% deviation from %.1f.", self:_AoADeg2Units( playerData, aoa ), _error, self:_AoADeg2Units( playerData, optaoa ) ) return hint, debrief, radiocall end --- Evaluate player's speed. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data table. -- @param #number speedopt Optimal speed in m/s. -- @return #string Feedback text. -- @return #string Debriefing text. -- @return #AIRBOSS.RadioCall Radio call. function AIRBOSS:_SpeedCheck( playerData, speedopt ) if speedopt == nil then return nil, nil end -- Player altitude. local speed = playerData.unit:GetVelocityMPS() -- Get relative score. local lowscore, badscore = self:_GetGoodBadScore( playerData ) -- Altitude error +-X% local _error = (speed - speedopt) / speedopt * 100 -- Radio call for flight students. local radiocall = nil -- #AIRBOSS.RadioCall local hint = "" if _error > badscore then -- hint=string.format("You're fast.") radiocall = self:_NewRadioCall( self.LSOCall.FAST, "AIRBOSS", "" ) elseif _error > lowscore then -- hint= string.format("You're slightly fast.") radiocall = self:_NewRadioCall( self.LSOCall.FAST, "AIRBOSS", "" ) elseif _error < -badscore then -- hint=string.format("You're slow.") radiocall = self:_NewRadioCall( self.LSOCall.SLOW, "AIRBOSS", "" ) elseif _error < -lowscore then -- hint=string.format("You're slightly slow.") radiocall = self:_NewRadioCall( self.LSOCall.SLOW, "AIRBOSS", "" ) else hint = string.format( "Good speed. " ) end -- Extend or decrease depending on skill. if playerData.difficulty == AIRBOSS.Difficulty.EASY then hint = hint .. string.format( "Optimal speed is %d knots.", UTILS.MpsToKnots( speedopt ) ) elseif playerData.difficulty == AIRBOSS.Difficulty.NORMAL then -- We keep is short normally. hint = "" elseif playerData.difficulty == AIRBOSS.Difficulty.HARD then -- No hint at all for pros. hint = "" end -- Debrief text. local debrief = string.format( "Speed %d knots = %d%% deviation from %d knots.", UTILS.MpsToKnots( speed ), _error, UTILS.MpsToKnots( speedopt ) ) return hint, debrief, radiocall end --- Evaluate player's distance to the boat at checkpoint. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data table. -- @param #number optdist Optimal distance in meters. -- @return #string Feedback message text. -- @return #string Debriefing text. -- @return #AIRBOSS.RadioCall Distance radio call. Not implemented yet. function AIRBOSS:_DistanceCheck( playerData, optdist ) if optdist == nil then return nil, nil end -- Distance to carrier. local distance = playerData.unit:GetCoordinate():Get2DDistance( self:GetCoordinate() ) -- Get relative score. local lowscore, badscore = self:_GetGoodBadScore( playerData ) -- Altitude error +-X% local _error = (distance - optdist) / optdist * 100 local hint if _error > badscore then hint = string.format( "You're too far from the boat!" ) elseif _error > lowscore then hint = string.format( "You're slightly too far from the boat." ) elseif _error < -badscore then hint = string.format( "You're too close to the boat!" ) elseif _error < -lowscore then hint = string.format( "You're slightly too far from the boat." ) else hint = string.format( "Good distance to the boat." ) end -- Extend or decrease depending on skill. if playerData.difficulty == AIRBOSS.Difficulty.EASY then -- Also inform students about optimal value. hint = hint .. string.format( " Optimal distance is %.1f NM.", UTILS.MetersToNM( optdist ) ) elseif playerData.difficulty == AIRBOSS.Difficulty.NORMAL then -- We keep it short normally. hint = "" elseif playerData.difficulty == AIRBOSS.Difficulty.HARD then -- No hint at all for the pros. hint = "" end -- Debriefing text. local debrief = string.format( "Distance %.1f NM = %d%% deviation from %.1f NM.", UTILS.MetersToNM( distance ), _error, UTILS.MetersToNM( optdist ) ) return hint, debrief, nil end ----------------------------------------------------------------------------------------------------------------------------------------------------------------------- -- DEBRIEFING ----------------------------------------------------------------------------------------------------------------------------------------------------------------------- --- Append text to debriefing. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data. -- @param #string hint Debrief text of this step. -- @param #string step (Optional) Current step in the pattern. Default from playerData. function AIRBOSS:_AddToDebrief( playerData, hint, step ) step = step or playerData.step table.insert( playerData.debrief, { step = step, hint = hint } ) end --- Debrief player and set next step. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data. function AIRBOSS:_Debrief( playerData ) self:F( self.lid .. string.format( "Debriefing of player %s.", playerData.name ) ) -- Delete scheduler ID. playerData.debriefschedulerID = nil -- Switch attitude monitor off if on. playerData.attitudemonitor = false -- LSO grade, points, and flight data analyis. local grade, points, analysis = self:_LSOgrade( playerData ) -- Insert points to table of all points until player landed. if points and points >= 0 then table.insert( playerData.points, points ) end -- Player has landed and is not airborne any more. local Points = 0 if playerData.landed and not playerData.unit:InAir() then -- Average over all points received so far. for _, _points in pairs( playerData.points ) do Points = Points + _points end -- This is the final points. Points = Points / #playerData.points -- Reset points array. playerData.points = {} else -- Player boltered or was waved off ==> We display the normal points. Points = points end -- My LSO grade. local mygrade = {} -- #AIRBOSS.LSOgrade mygrade.grade = grade mygrade.points = points mygrade.details = analysis mygrade.wire = playerData.wire mygrade.Tgroove = playerData.Tgroove if playerData.landed and not playerData.unit:InAir() then mygrade.finalscore = Points end mygrade.case = playerData.case local windondeck = self:GetWindOnDeck() mygrade.wind = UTILS.Round( UTILS.MpsToKnots( windondeck ), 1 ) mygrade.modex = playerData.onboard mygrade.airframe = playerData.actype mygrade.carriertype = self.carriertype mygrade.carriername = self.alias mygrade.carrierrwy = self.carrierparam.rwyangle mygrade.theatre = self.theatre mygrade.mitime = UTILS.SecondsToClock( timer.getAbsTime(), true ) mygrade.midate = UTILS.GetDCSMissionDate() mygrade.osdate = "n/a" if os then mygrade.osdate = os.date() -- os.date("%d.%m.%Y") end -- Add last grade to playerdata for FunkMan. playerData.grade=mygrade -- Save trap sheet. if playerData.trapon and self.trapsheet then self:_SaveTrapSheet( playerData, mygrade ) end -- Add LSO grade to player grades table. table.insert( self.playerscores[playerData.name], mygrade ) -- Trigger grading event. self:LSOGrade( playerData, mygrade ) -- LSO grade: (OK) 3.0 PT - LURIM local text = string.format( "%s %.1f PT - %s", grade, Points, analysis ) if Points == -1 then text = string.format( "%s n/a PT - Foul deck", grade, Points, analysis ) end -- Wire and Groove time only if not pattern WO. if not (playerData.wop or playerData.wofd) then -- Wire trapped. Not if pattern WI. if playerData.wire and playerData.wire <= 4 then text = text .. string.format( " %d-wire", playerData.wire ) end -- Time in the groove. Only Case I/II and not pattern WO. if playerData.Tgroove and playerData.Tgroove <= 360 and playerData.case < 3 then text = text .. string.format( "\nTime in the groove %.1f seconds: %s", playerData.Tgroove, self:_EvalGrooveTime( playerData ) ) end end -- Copy debriefing text. playerData.lastdebrief = UTILS.DeepCopy( playerData.debrief ) -- Info text. if playerData.difficulty == AIRBOSS.Difficulty.EASY then text = text .. string.format( "\nYour detailed debriefing can be found via the F10 radio menu." ) end -- Message. self:MessageToPlayer( playerData, text, "LSO", "", 30, true ) -- Set step to undefined and check if other cases apply. playerData.step = AIRBOSS.PatternStep.UNDEFINED -- Check what happened? if playerData.wop then ---------------------- -- Pattern Wave Off -- ---------------------- -- Next step? -- TODO: CASE I: After bolter/wo turn left and climb to 600 ft and re-enter the pattern. But do not go to initial but reenter earlier? -- TODO: CASE I: After pattern wo? go back to initial, I guess? -- TODO: CASE III: After bolter/wo turn left and climb to 1200 ft and re-enter pattern? -- TODO: CASE III: After pattern wo? No idea... -- Can become nil when I crashed and changed to observer. Which events are captured? Nil check for unit? if playerData.unit:IsAlive() then -- Heading and distance tip. local heading, distance if playerData.case == 1 or playerData.case == 2 then -- Next step: Initial again. playerData.step = AIRBOSS.PatternStep.INITIAL -- Create a point 3.0 NM astern for re-entry. local initial = self:GetCoordinate():Translate( UTILS.NMToMeters( 3.5 ), self:GetRadial( 2, false, false, false ) ) -- Get heading and distance to initial zone ~3 NM astern. heading = playerData.unit:GetCoordinate():HeadingTo( initial ) distance = playerData.unit:GetCoordinate():Get2DDistance( initial ) elseif playerData.case == 3 then -- Next step? Bullseye for now. -- TODO: Could be DIRTY UP or PLATFORM or even back to MARSHAL STACK? playerData.step = AIRBOSS.PatternStep.BULLSEYE -- Get heading and distance to bullseye zone ~3 NM astern. local zone = self:_GetZoneBullseye( playerData.case ) heading = playerData.unit:GetCoordinate():HeadingTo( zone:GetCoordinate() ) distance = playerData.unit:GetCoordinate():Get2DDistance( zone:GetCoordinate() ) end -- Re-enter message. local text = string.format( "fly heading %03d° for %d NM to re-enter the pattern.", heading, UTILS.MetersToNM( distance ) ) self:MessageToPlayer( playerData, text, "LSO", nil, nil, false, 5 ) else -- Unit does not seem to be alive! -- TODO: What now? self:E( self.lid .. string.format( "ERROR: Player unit not alive!" ) ) end elseif playerData.wofd then --------------- -- Foul Deck -- --------------- if playerData.unit:InAir() then -- Bolter pattern. Then Abeam or bullseye. playerData.step = AIRBOSS.PatternStep.BOLTER else -- Welcome aboard! self:Sound2Player( playerData, self.LSORadio, self.LSOCall.WELCOMEABOARD ) -- Airboss talkto! local text = string.format( "deck was fouled but you landed anyway. Airboss wants to talk to you!" ) self:MessageToPlayer( playerData, text, "LSO", nil, nil, false, 3 ) end elseif playerData.owo then ------------------ -- Own Wave Off -- ------------------ if playerData.unit:InAir() then -- Bolter pattern. Then Abeam or bullseye. playerData.step = AIRBOSS.PatternStep.BOLTER else -- Welcome aboard! -- NOTE: This should not happen as owo is only triggered if player flew past the carrier. self:E( self.lid .. "ERROR: player landed when OWO was issues. This should not happen. Please report!" ) self:Sound2Player( playerData, self.LSORadio, self.LSOCall.WELCOMEABOARD ) end elseif playerData.waveoff then -------------- -- Wave Off -- -------------- if playerData.unit:InAir() then -- Bolter pattern. Then Abeam or bullseye. playerData.step = AIRBOSS.PatternStep.BOLTER else -- Welcome aboard! self:Sound2Player( playerData, self.LSORadio, self.LSOCall.WELCOMEABOARD ) -- Airboss talkto! local text = string.format( "you were waved off but landed anyway. Airboss wants to talk to you!" ) self:MessageToPlayer( playerData, text, "LSO", nil, nil, false, 3 ) end elseif playerData.boltered then -------------- -- Boltered -- -------------- if playerData.unit:InAir() then -- Bolter pattern. Then Abeam or bullseye. playerData.step = AIRBOSS.PatternStep.BOLTER end elseif playerData.landed then ------------ -- Landed -- ------------ if not playerData.unit:InAir() then -- Welcome aboard! self:Sound2Player( playerData, self.LSORadio, self.LSOCall.WELCOMEABOARD ) end else -- Message to player. self:MessageToPlayer( playerData, "Undefined state after landing! Please report.", "ERROR", nil, 20 ) -- Next step. playerData.step = AIRBOSS.PatternStep.UNDEFINED end -- Player landed and is not in air anymore. if playerData.landed and not playerData.unit:InAir() then -- Set recovered flag. self:_RecoveredElement( playerData.unit ) -- Check if all elements self:_CheckSectionRecovered( playerData ) end -- Increase number of passes. playerData.passes = playerData.passes + 1 -- Next step hint for students if any. self:_StepHint( playerData ) -- Reinitialize player data for new approach. self:_InitPlayer( playerData, playerData.step ) -- Debug message. MESSAGE:New( string.format( "Player step %s.", playerData.step ), 5, "DEBUG" ):ToAllIf( self.Debug ) -- Auto save player results. if self.autosave and mygrade.finalscore then self:Save( self.autosavepath, self.autosavefile ) end end ----------------------------------------------------------------------------------------------------------------------------------------------------------------------- -- CARRIER ROUTING Functions ----------------------------------------------------------------------------------------------------------------------------------------------------------------------- --- Check for possible collisions between two coordinates. -- @param #AIRBOSS self -- @param Core.Point#COORDINATE coordto Coordinate to which the collision is check. -- @param Core.Point#COORDINATE coordfrom Coordinate from which the collision is check. -- @return #boolean If true, surface type ahead is not deep water. -- @return #number Max free distance in meters. function AIRBOSS:_CheckCollisionCoord( coordto, coordfrom ) -- Increment in meters. local dx = 100 -- From coordinate. Default 500 in front of the carrier. local d = 0 if coordfrom then d = 0 else d = 250 coordfrom = self:GetCoordinate():Translate( d, self:GetHeading() ) end -- Distance between the two coordinates. local dmax = coordfrom:Get2DDistance( coordto ) -- Direction. local direction = coordfrom:HeadingTo( coordto ) -- Scan path between the two coordinates. local clear = true while d <= dmax do -- Check point. local cp = coordfrom:Translate( d, direction ) -- Check if surface type is water. if not cp:IsSurfaceTypeWater() then -- Debug mark points. if self.Debug then local st = cp:GetSurfaceType() cp:MarkToAll( string.format( "Collision check surface type %d", st ) ) end -- Collision WARNING! clear = false break end -- Increase distance. d = d + dx end local text = "" if clear then text = string.format( "Path into direction %03d° is clear for the next %.1f NM.", direction, UTILS.MetersToNM( d ) ) else text = string.format( "Detected obstacle at distance %.1f NM into direction %03d°.", UTILS.MetersToNM( d ), direction ) end self:T2( self.lid .. text ) return not clear, d end --- Check Collision. -- @param #AIRBOSS self -- @param Core.Point#COORDINATE fromcoord Coordinate from which the path to the next WP is calculated. Default current carrier position. -- @return #boolean If true, surface type ahead is not deep water. function AIRBOSS:_CheckFreePathToNextWP( fromcoord ) -- Position. fromcoord = fromcoord or self:GetCoordinate():Translate( 250, self:GetHeading() ) -- Next wp = current+1 (or last) local Nnextwp = math.min( self.currentwp + 1, #self.waypoints ) -- Next waypoint. local nextwp = self.waypoints[Nnextwp] -- Core.Point#COORDINATE -- Check for collision. local collision = self:_CheckCollisionCoord( nextwp, fromcoord ) return collision end --- Find free path to the next waypoint. -- @param #AIRBOSS self function AIRBOSS:_Pathfinder() -- Heading and current coordiante. local hdg = self:GetHeading() local cv = self:GetCoordinate() -- Possible directions. local directions = { -20, 20, -30, 30, -40, 40, -50, 50, -60, 60, -70, 70, -80, 80, -90, 90, -100, 100 } -- Starboard turns up to 90 degrees. for _, _direction in pairs( directions ) do -- New direction. local direction = hdg + _direction -- Check for collisions in the next 20 NM of the current direction. local _, dfree = self:_CheckCollisionCoord( cv:Translate( UTILS.NMToMeters( 20 ), direction ), cv ) -- Loop over distances and find the first one which gives a clear path to the next waypoint. local distance = 500 while distance <= dfree do -- Coordinate from which we calculate the path. local fromcoord = cv:Translate( distance, direction ) -- Check for collision between point and next waypoint. local collision = self:_CheckFreePathToNextWP( fromcoord ) -- Debug info. self:T2( self.lid .. string.format( "Pathfinder d=%.1f m, direction=%03d°, collision=%s", distance, direction, tostring( collision ) ) ) -- If path is clear, we start a little detour. if not collision then self:CarrierDetour( fromcoord ) return end distance = distance + 500 end end end --- Carrier resumes the route at its next waypoint. -- @param #AIRBOSS self -- @param Core.Point#COORDINATE gotocoord (Optional) First goto this coordinate before resuming route. -- @return #AIRBOSS self function AIRBOSS:CarrierResumeRoute( gotocoord ) -- Make carrier resume its route. AIRBOSS._ResumeRoute( self.carrier:GetGroup(), self, gotocoord ) return self end --- Let the carrier make a detour to a given point. When it reaches the point, it will resume its normal route. -- @param #AIRBOSS self -- @param Core.Point#COORDINATE coord Coordinate of the detour. -- @param #number speed Speed in knots. Default is current carrier velocity. -- @param #boolean uturn (Optional) If true, carrier will go back to where it came from before it resumes its route to the next waypoint. -- @param #number uspeed Speed in knots after U-turn. Default is same as before. -- @param Core.Point#COORDINATE tcoord Additional coordinate to make turn smoother. -- @return #AIRBOSS self function AIRBOSS:CarrierDetour( coord, speed, uturn, uspeed, tcoord ) -- Current coordinate of the carrier. local pos0 = self:GetCoordinate() -- Current speed in knots. local vel0 = self.carrier:GetVelocityKNOTS() -- Default. If speed is not given we take the current speed but at least 5 knots. speed = speed or math.max( vel0, 5 ) -- Speed in km/h. At least 2 knots. local speedkmh = math.max( UTILS.KnotsToKmph( speed ), UTILS.KnotsToKmph( 2 ) ) -- Turn speed in km/h. At least 10 knots. local cspeedkmh = math.max( self.carrier:GetVelocityKMH(), UTILS.KnotsToKmph( 10 ) ) -- U-turn speed in km/h. local uspeedkmh = UTILS.KnotsToKmph( uspeed or speed ) -- Waypoint table. local wp = {} -- Waypoint at current position. table.insert( wp, pos0:WaypointGround( cspeedkmh ) ) -- Waypooint to help the turn. if tcoord then table.insert( wp, tcoord:WaypointGround( cspeedkmh ) ) end -- Detour waypoint. table.insert( wp, coord:WaypointGround( speedkmh ) ) -- U-turn waypoint. If enabled, go back to where you came from. if uturn then table.insert( wp, pos0:WaypointGround( uspeedkmh ) ) end -- Get carrier group. local group = self.carrier:GetGroup() -- Passing waypoint taskfunction local TaskResumeRoute = group:TaskFunction( "AIRBOSS._ResumeRoute", self ) -- Set task to restart route at the last point. group:SetTaskWaypoint( wp[#wp], TaskResumeRoute ) -- Debug mark. if self.Debug then if tcoord then tcoord:MarkToAll( string.format( "Detour Turn Help WP. Speed %.1f knots", UTILS.KmphToKnots( cspeedkmh ) ) ) end coord:MarkToAll( string.format( "Detour Waypoint. Speed %.1f knots", UTILS.KmphToKnots( speedkmh ) ) ) if uturn then pos0:MarkToAll( string.format( "Detour U-turn WP. Speed %.1f knots", UTILS.KmphToKnots( uspeedkmh ) ) ) end end -- Detour switch true. self.detour = true -- Route carrier into the wind. self.carrier:Route( wp ) end --- Let the carrier turn into the wind. -- @param #AIRBOSS self -- @param #number time Time in seconds. -- @param #number vdeck Speed on deck m/s. Carrier will -- @param #boolean uturn Make U-turn and go back to initial after downwind leg. -- @return #AIRBOSS self function AIRBOSS:CarrierTurnIntoWind( time, vdeck, uturn ) -- Wind speed. local _, vwind = self:GetWind() -- Desired wind on deck in knots. local vdeck=UTILS.MpsToKnots(vdeck) -- Get heading into the wind accounting for angled runway. local hiw, speedknots = self:GetHeadingIntoWind(vdeck) -- Speed of carrier in m/s but at least 4 knots. local vtot = UTILS.KnotsToMps(speedknots) -- Distance to travel local dist = vtot * time -- Distance in NM. local distNM = UTILS.MetersToNM( dist ) -- Current heading. local hdg = self:GetHeading() -- Heading difference. local deltaH = self:_GetDeltaHeading( hdg, hiw ) -- Debug output self:I( self.lid .. string.format( "Carrier steaming into the wind (%.1f kts). Heading=%03d-->%03d (Delta=%.1f), Speed=%.1f knots, Distance=%.1f NM, Time=%d sec", UTILS.MpsToKnots( vwind ), hdg, hiw, deltaH, speedknots, distNM, speedknots, time ) ) -- Current coordinate. local Cv = self:GetCoordinate() local Ctiw = nil -- Core.Point#COORDINATE local Csoo = nil -- Core.Point#COORDINATE -- Define path depending on turn angle. if deltaH < 45 then -- Small turn. -- Point in the right direction to help turning. Csoo = Cv:Translate( 750, hdg ):Translate( 750, hiw ) -- Heading into wind from Csoo. local hsw = self:GetHeadingIntoWind(vdeck, false, Csoo ) -- Into the wind coord. Ctiw = Csoo:Translate( dist, hsw ) elseif deltaH < 90 then -- Medium turn. -- Point in the right direction to help turning. Csoo = Cv:Translate( 900, hdg ):Translate( 900, hiw ) -- Heading into wind from Csoo. local hsw = self:GetHeadingIntoWind(vdeck, false, Csoo ) -- Into the wind coord. Ctiw = Csoo:Translate( dist, hsw ) elseif deltaH < 135 then -- Large turn backwards. -- Point in the right direction to help turning. Csoo = Cv:Translate( 1100, hdg - 90 ):Translate( 1000, hiw ) -- Heading into wind from Csoo. local hsw = self:GetHeadingIntoWind(vdeck, false, Csoo ) -- Into the wind coord. Ctiw = Csoo:Translate( dist, hsw ) else -- Huge turn backwards. -- Point in the right direction to help turning. Csoo = Cv:Translate( 1200, hdg - 90 ):Translate( 1000, hiw ) -- Heading into wind from Csoo. local hsw = self:GetHeadingIntoWind(vdeck, false, Csoo ) -- Into the wind coord. Ctiw = Csoo:Translate( dist, hsw ) end -- Return to coordinate if collision is detected. self.Creturnto = self:GetCoordinate() -- Next waypoint. local nextwp = self:_GetNextWaypoint() -- For downwind, we take the velocity at the next WP. local vdownwind = UTILS.MpsToKnots( nextwp:GetVelocity() ) -- Make sure we move at all in case the speed at the waypoint is zero. if vdownwind < 1 then vdownwind = 10 end -- Let the carrier make a detour from its route but return to its current position. self:CarrierDetour( Ctiw, speedknots, uturn, vdownwind, Csoo ) -- Set switch that we are currently turning into the wind. self.turnintowind = true return self end --- Get next waypoint of the carrier. -- @param #AIRBOSS self -- @return Core.Point#COORDINATE Coordinate of the next waypoint. -- @return #number Number of waypoint. function AIRBOSS:_GetNextWaypoint() -- Next waypoint. local Nextwp = nil if self.currentwp == #self.waypoints then Nextwp = 1 else Nextwp = self.currentwp + 1 end -- Debug output local text = string.format( "Current WP=%d/%d, next WP=%d", self.currentwp, #self.waypoints, Nextwp ) self:T2( self.lid .. text ) -- Next waypoint. local nextwp = self.waypoints[Nextwp] -- Core.Point#COORDINATE return nextwp, Nextwp end --- Initialize Mission Editor waypoints. -- @param #AIRBOSS self -- @return #AIRBOSS self function AIRBOSS:_InitWaypoints() -- Waypoints of group as defined in the ME. local Waypoints = self.carrier:GetGroup():GetTemplateRoutePoints() -- Init array. self.waypoints = {} -- Set waypoint table. for i, point in ipairs( Waypoints ) do -- Coordinate of the waypoint local coord = COORDINATE:New( point.x, point.alt, point.y ) -- Set velocity of the coordinate. coord:SetVelocity( point.speed ) -- Add to table. table.insert( self.waypoints, coord ) -- Debug info. if self.Debug then coord:MarkToAll( string.format( "Carrier Waypoint %d, Speed=%.1f knots", i, UTILS.MpsToKnots( point.speed ) ) ) end end return self end --- Patrol carrier. -- @param #AIRBOSS self -- @param #number n Next waypoint number. -- @return #AIRBOSS self function AIRBOSS:_PatrolRoute( n ) -- Get next waypoint coordinate and number. local nextWP, N = self:_GetNextWaypoint() -- Default resume is to next waypoint. n = n or N -- Get carrier group. local CarrierGroup = self.carrier:GetGroup() -- Waypoints table. local Waypoints = {} -- Create a waypoint from the current coordinate. local wp = self:GetCoordinate():WaypointGround( CarrierGroup:GetVelocityKMH() ) -- Add current position as first waypoint. table.insert( Waypoints, wp ) -- Loop over waypoints. for i = n, #self.waypoints do local coord = self.waypoints[i] -- Core.Point#COORDINATE -- Create a waypoint from the coordinate. local wp = coord:WaypointGround( UTILS.MpsToKmph( coord.Velocity ) ) -- Passing waypoint taskfunction local TaskPassingWP = CarrierGroup:TaskFunction( "AIRBOSS._PassingWaypoint", self, i, #self.waypoints ) -- Call task function when carrier arrives at waypoint. CarrierGroup:SetTaskWaypoint( wp, TaskPassingWP ) -- Add waypoint to table. table.insert( Waypoints, wp ) end -- Route carrier group. CarrierGroup:Route( Waypoints ) return self end --- Estimated the carrier position at some point in the future given the current waypoints and speeds. -- @param #AIRBOSS self -- @return DCS#time ETA abs. time in seconds. function AIRBOSS:_GetETAatNextWP() -- Current waypoint local cwp = self.currentwp -- Current abs. time. local tnow = timer.getAbsTime() -- Current position. local p = self:GetCoordinate() -- Current velocity [m/s]. local v = self.carrier:GetVelocityMPS() -- Next waypoint. local nextWP = self:_GetNextWaypoint() -- Distance to next waypoint. local s = p:Get2DDistance( nextWP ) -- Distance to next waypoint. -- local s=0 -- if #self.waypoints>cwp then -- s=p:Get2DDistance(self.waypoints[cwp+1]) -- end -- v=s/t <==> t=s/v local t = s / v -- ETA local eta = t + tnow return eta end --- Check if carrier is turning. If turning started or stopped, we inform the players via radio message. -- @param #AIRBOSS self function AIRBOSS:_CheckCarrierTurning() -- Current orientation of carrier. local vNew = self.carrier:GetOrientationX() -- Last orientation from 30 seconds ago. local vLast = self.Corientlast -- We only need the X-Z plane. vNew.y = 0; vLast.y = 0 -- Angle between current heading and last time we checked ~30 seconds ago. local deltaLast = math.deg( math.acos( UTILS.VecDot( vNew, vLast ) / UTILS.VecNorm( vNew ) / UTILS.VecNorm( vLast ) ) ) -- Last orientation becomes new orientation self.Corientlast = vNew -- Carrier is turning when its heading changed by at least one degree since last check. local turning = math.abs( deltaLast ) >= 1 -- Check if turning stopped. (Carrier was turning but is not any more.) if self.turning and not turning then -- Get final bearing. local FB = self:GetFinalBearing( true ) -- Marshal radio call: "99, new final bearing XYZ degrees." self:_MarshalCallNewFinalBearing( FB ) end -- Check if turning started. (Carrier was not turning and is now.) if turning and not self.turning then -- Get heading. local hdg if self.turnintowind then -- We are now steaming into the wind. local vdeck=self.recoverywindow and self.recoverywindow.SPEED or 20 hdg = self:GetHeadingIntoWind(vdeck, false) else -- We turn towards the next waypoint. hdg = self:GetCoordinate():HeadingTo( self:_GetNextWaypoint() ) end -- Magnetic! hdg = hdg - self.magvar if hdg < 0 then hdg = 360 + hdg end -- Radio call: "99, Carrier starting turn to heading XYZ degrees". self:_MarshalCallCarrierTurnTo( hdg ) end -- Update turning. self.turning = turning end --- Check if heading or position of carrier have changed significantly. -- @param #AIRBOSS self function AIRBOSS:_CheckPatternUpdate() ---------------------------------------- -- TODO: Make parameters input values -- ---------------------------------------- -- Min 10 min between pattern updates. local dTPupdate = 10 * 60 -- Update if carrier moves by more than 2.5 NM. local Dupdate = UTILS.NMToMeters( 2.5 ) -- Update if carrier turned by more than 5°. local Hupdate = 5 ----------------------- -- Time Update Check -- ----------------------- -- Time since last pattern update local dt = timer.getTime() - self.Tpupdate -- Check whether at least 10 min between updates and not turning currently. if dt < dTPupdate or self.turning then return end -------------------------- -- Heading Update Check -- -------------------------- -- Current orientation of carrier. local vNew = self.carrier:GetOrientationX() -- Reference orientation of carrier after the last update. local vOld = self.Corientation -- We only need the X-Z plane. vNew.y = 0; vOld.y = 0 -- Get angle between old and new orientation vectors in rad and convert to degrees. local deltaHeading = math.deg( math.acos( UTILS.VecDot( vNew, vOld ) / UTILS.VecNorm( vNew ) / UTILS.VecNorm( vOld ) ) ) -- Check if orientation changed. local Hchange = false if math.abs( deltaHeading ) >= Hupdate then self:T( self.lid .. string.format( "Carrier heading changed by %d°.", deltaHeading ) ) Hchange = true end --------------------------- -- Distance Update Check -- --------------------------- -- Get current position and orientation of carrier. local pos = self:GetCoordinate() -- Get distance to saved position. local dist = pos:Get2DDistance( self.Cposition ) -- Check if carrier moved more than ~10 km. local Dchange = false if dist >= Dupdate then self:T( self.lid .. string.format( "Carrier position changed by %.1f NM.", UTILS.MetersToNM( dist ) ) ) Dchange = true end ---------------------------- -- Update Marshal Flights -- ---------------------------- -- If heading or distance changed ==> update marshal AI patterns. if Hchange or Dchange then -- Loop over all marshal flights for _, _flight in pairs( self.Qmarshal ) do local flight = _flight -- #AIRBOSS.FlightGroup -- Update marshal pattern of AI keeping the same stack. if flight.ai then self:_MarshalAI( flight, flight.flag ) end end -- Reset parameters for next update check. self.Corientation = vNew self.Cposition = pos self.Tpupdate = timer.getTime() end end --- Function called when a group is passing a waypoint. -- @param Wrapper.Group#GROUP group Group that passed the waypoint -- @param #AIRBOSS airboss Airboss object. -- @param #number i Waypoint number that has been reached. -- @param #number final Final waypoint number. function AIRBOSS._PassingWaypoint( group, airboss, i, final ) -- Debug message. local text = string.format( "Group %s passing waypoint %d of %d.", group:GetName(), i, final ) -- Debug smoke and marker. if airboss.Debug and false then local pos = group:GetCoordinate() pos:SmokeRed() local MarkerID = pos:MarkToAll( string.format( "Group %s reached waypoint %d", group:GetName(), i ) ) end -- Debug message. MESSAGE:New( text, 10 ):ToAllIf( airboss.Debug ) airboss:T( airboss.lid .. text ) -- Set current waypoint. airboss.currentwp = i -- Passing Waypoint event. airboss:PassingWaypoint( i ) -- Reactivate beacons. -- airboss:_ActivateBeacons() -- If final waypoint reached, do route all over again. if i == final and final > 1 and airboss.adinfinitum then airboss:_PatrolRoute() end end --- Carrier Strike Group resumes the route of the waypoints defined in the mission editor. -- @param Wrapper.Group#GROUP group Carrier Strike Group that passed the waypoint. -- @param #AIRBOSS airboss Airboss object. -- @param Core.Point#COORDINATE gotocoord Go to coordinate before route is resumed. function AIRBOSS._ResumeRoute( group, airboss, gotocoord ) -- Get next waypoint local nextwp, Nextwp = airboss:_GetNextWaypoint() -- Speed set at waypoint. local speedkmh = nextwp.Velocity * 3.6 -- If speed at waypoint is zero, we set it to 10 knots. if speedkmh < 1 then speedkmh = UTILS.KnotsToKmph( 10 ) end -- Waypoints array. local waypoints = {} -- Current position. local c0 = group:GetCoordinate() -- Current positon as first waypoint. local wp0 = c0:WaypointGround( speedkmh ) table.insert( waypoints, wp0 ) -- First goto this coordinate. if gotocoord then -- gotocoord:MarkToAll(string.format("Goto waypoint speed=%.1f km/h", speedkmh)) local headingto = c0:HeadingTo( gotocoord ) local hdg1 = airboss:GetHeading() local hdg2 = c0:HeadingTo( gotocoord ) local delta = airboss:_GetDeltaHeading( hdg1, hdg2 ) -- env.info(string.format("FF hdg1=%d, hdg2=%d, delta=%d", hdg1, hdg2, delta)) -- Add additional turn points if delta > 90 then -- Turn radius 3 NM. local turnradius = UTILS.NMToMeters( 3 ) local gotocoordh = c0:Translate( turnradius, hdg1 + 45 ) -- gotocoordh:MarkToAll(string.format("Goto help waypoint 1 speed=%.1f km/h", speedkmh)) local wp = gotocoordh:WaypointGround( speedkmh ) table.insert( waypoints, wp ) gotocoordh = c0:Translate( turnradius, hdg1 + 90 ) -- gotocoordh:MarkToAll(string.format("Goto help waypoint 2 speed=%.1f km/h", speedkmh)) wp = gotocoordh:WaypointGround( speedkmh ) table.insert( waypoints, wp ) end local wp1 = gotocoord:WaypointGround( speedkmh ) table.insert( waypoints, wp1 ) end -- Debug message. local text = string.format( "Carrier is resuming route. Next waypoint %d, Speed=%.1f knots.", Nextwp, UTILS.KmphToKnots( speedkmh ) ) -- Debug message. MESSAGE:New( text, 10 ):ToAllIf( airboss.Debug ) airboss:I( airboss.lid .. text ) -- Loop over all remaining waypoints. for i = Nextwp, #airboss.waypoints do -- Coordinate of the next WP. local coord = airboss.waypoints[i] -- Core.Point#COORDINATE -- Speed in km/h of that WP. Velocity is in m/s. local speed = coord.Velocity * 3.6 -- If speed is zero we set it to 10 knots. if speed < 1 then speed = UTILS.KnotsToKmph( 10 ) end -- coord:MarkToAll(string.format("Resume route WP %d, speed=%.1f km/h", i, speed)) -- Create waypoint. local wp = coord:WaypointGround( speed ) -- Passing waypoint task function. local TaskPassingWP = group:TaskFunction( "AIRBOSS._PassingWaypoint", airboss, i, #airboss.waypoints ) -- Call task function when carrier arrives at waypoint. group:SetTaskWaypoint( wp, TaskPassingWP ) -- Add waypoints to table. table.insert( waypoints, wp ) end -- Set turn into wind switch false. airboss.turnintowind = false airboss.detour = false -- Route group. group:Route( waypoints ) end --- Function called when a group has reached the holding zone. -- @param Wrapper.Group#GROUP group Group that reached the holding zone. -- @param #AIRBOSS airboss Airboss object. -- @param #AIRBOSS.FlightGroup flight Flight group that has reached the holding zone. function AIRBOSS._ReachedHoldingZone( group, airboss, flight ) -- Debug message. local text = string.format( "Flight %s reached holding zone.", group:GetName() ) MESSAGE:New( text, 10 ):ToAllIf( airboss.Debug ) airboss:T( airboss.lid .. text ) -- Debug mark. if airboss.Debug then group:GetCoordinate():MarkToAll( text ) end -- Set holding flag true and set timestamp for marshal time check. if flight then flight.holding = true flight.time = timer.getAbsTime() end end --- Function called when a group should be send to the Marshal stack. If stack is full, it is send to wait. -- @param Wrapper.Group#GROUP group Group that reached the holding zone. -- @param #AIRBOSS airboss Airboss object. -- @param #AIRBOSS.FlightGroup flight Flight group that has reached the holding zone. function AIRBOSS._TaskFunctionMarshalAI( group, airboss, flight ) -- Debug message. local text = string.format( "Flight %s is send to marshal.", group:GetName() ) MESSAGE:New( text, 10 ):ToAllIf( airboss.Debug ) airboss:T( airboss.lid .. text ) -- Get the next free stack for current recovery case. local stack = airboss:_GetFreeStack( flight.ai ) if stack then -- Send AI to marshal stack. airboss:_MarshalAI( flight, stack ) else -- Send AI to orbit outside 10 NM zone and wait until the next Marshal stack is available. if not airboss:_InQueue( airboss.Qwaiting, flight.group ) then airboss:_WaitAI( flight ) end end -- If it came from refueling. if flight.refueling == true then airboss:I( airboss.lid .. string.format( "Flight group %s finished refueling task.", flight.groupname ) ) end -- Not refueling any more in case it was. flight.refueling = false end ---------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- -- MISC functions ---------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- --- Get aircraft nickname. -- @param #AIRBOSS self -- @param #string actype Aircraft type name. -- @return #string Aircraft nickname. E.g. "Hornet" for the F/A-18C or "Tomcat" For the F-14A. function AIRBOSS:_GetACNickname( actype ) local nickname = "unknown" if actype == AIRBOSS.AircraftCarrier.A4EC then nickname = "Skyhawk" elseif actype == AIRBOSS.AircraftCarrier.T45C then nickname = "Goshawk" elseif actype == AIRBOSS.AircraftCarrier.AV8B then nickname = "Harrier" elseif actype == AIRBOSS.AircraftCarrier.E2D then nickname = "Hawkeye" elseif actype == AIRBOSS.AircraftCarrier.C2A then nickname = "Greyhound" elseif actype == AIRBOSS.AircraftCarrier.F14A_AI or actype == AIRBOSS.AircraftCarrier.F14A or actype == AIRBOSS.AircraftCarrier.F14B then nickname = "Tomcat" elseif actype == AIRBOSS.AircraftCarrier.FA18C or actype == AIRBOSS.AircraftCarrier.HORNET then nickname = "Hornet" elseif actype == AIRBOSS.AircraftCarrier.RHINOE or actype == AIRBOSS.AircraftCarrier.RHINOF then nickname = "Rhino" elseif actype == AIRBOSS.AircraftCarrier.GROWLER then nickname = "Growler" elseif actype == AIRBOSS.AircraftCarrier.S3B or actype == AIRBOSS.AircraftCarrier.S3BTANKER then nickname = "Viking" end return nickname end --- Get onboard number of player or client. -- @param #AIRBOSS self -- @param Wrapper.Group#GROUP group Aircraft group. -- @return #string Onboard number as string. function AIRBOSS:_GetOnboardNumberPlayer( group ) return self:_GetOnboardNumbers( group, true ) end --- Get onboard numbers of all units in a group. -- @param #AIRBOSS self -- @param Wrapper.Group#GROUP group Aircraft group. -- @param #boolean playeronly If true, return the onboard number for player or client skill units. -- @return #table Table of onboard numbers. function AIRBOSS:_GetOnboardNumbers( group, playeronly ) -- self:F({groupname=group:GetName}) -- Get group name. local groupname = group:GetName() -- Debug text. local text = string.format( "Onboard numbers of group %s:", groupname ) local template=group:GetTemplate() local numbers = {} if template then -- Units of template group. local units = template.units -- Get numbers. for _, unit in pairs( units ) do -- Onboard number and unit name. local n = tostring( unit.onboard_num ) local name = unit.name local skill = unit.skill or "Unknown" -- Debug text. text = text .. string.format( "\n- unit %s: onboard #=%s skill=%s", name, n, tostring( skill ) ) if playeronly and skill == "Client" or skill == "Player" then -- There can be only one player in the group, so we skip everything else. return n end -- Table entry. numbers[name] = n end -- Debug info. self:T2( self.lid .. text ) else if playeronly then return 101 else local units=group:GetUnits() for i,_unit in pairs(units) do local name=_unit:GetName() numbers[name]=100+i end end end return numbers end --- Get Tower frequency of carrier. -- @param #AIRBOSS self function AIRBOSS:_GetTowerFrequency() -- Tower frequency in MHz self.TowerFreq = 0 -- Get Template of Strike Group local striketemplate = self.carrier:GetGroup():GetTemplate() -- Find the carrier unit. for _, unit in pairs( striketemplate.units ) do if self.carrier:GetName() == unit.name then self.TowerFreq = unit.frequency / 1000000 return end end end --- Get error margin depending on player skill. -- -- * Flight students: 10% and 20% -- * Naval Aviators: 5% and 10% -- * TOPGUN Graduates: 2.5% and 5% -- -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data table. -- @return #number Error margin for still being okay. -- @return #number Error margin for really sucking. function AIRBOSS:_GetGoodBadScore( playerData ) local lowscore local badscore if playerData.difficulty == AIRBOSS.Difficulty.EASY then lowscore = 10 badscore = 20 elseif playerData.difficulty == AIRBOSS.Difficulty.NORMAL then lowscore = 5 badscore = 10 elseif playerData.difficulty == AIRBOSS.Difficulty.HARD then lowscore = 2.5 badscore = 5 end return lowscore, badscore end --- Check if aircraft is capable of landing on this aircraft carrier. -- @param #AIRBOSS self -- @param Wrapper.Unit#UNIT unit Aircraft unit. (Will also work with groups as given parameter.) -- @return #boolean If true, aircraft can land on a carrier. function AIRBOSS:_IsCarrierAircraft( unit ) -- Get aircraft type name local aircrafttype = unit:GetTypeName() -- Special case for Harrier which can only land on Tarawa, LHA and LHD. if aircrafttype == AIRBOSS.AircraftCarrier.AV8B then if self.carriertype == AIRBOSS.CarrierType.INVINCIBLE or self.carriertype == AIRBOSS.CarrierType.HERMES or self.carriertype == AIRBOSS.CarrierType.TARAWA or self.carriertype == AIRBOSS.CarrierType.AMERICA or self.carriertype == AIRBOSS.CarrierType.JCARLOS or self.carriertype == AIRBOSS.CarrierType.CANBERRA then return true else return false end end -- Also only Harriers can land on the Tarawa, LHA and LHD. if self.carriertype == AIRBOSS.CarrierType.INVINCIBLE or self.carriertype == AIRBOSS.CarrierType.TARAWA or self.carriertype == AIRBOSS.CarrierType.AMERICA or self.carriertype == AIRBOSS.CarrierType.JCARLOS or self.carriertype == AIRBOSS.CarrierType.CANBERRA then if aircrafttype ~= AIRBOSS.AircraftCarrier.AV8B then return false end end -- Loop over all other known carrier capable aircraft. for _, actype in pairs( AIRBOSS.AircraftCarrier ) do -- Check if this is a carrier capable aircraft type. if actype == aircrafttype then return true end end -- No carrier carrier aircraft. return false end --- Checks if a human player sits in the unit. -- @param #AIRBOSS self -- @param Wrapper.Unit#UNIT unit Aircraft unit. -- @return #boolean If true, human player inside the unit. function AIRBOSS:_IsHumanUnit( unit ) -- Get player unit or nil if no player unit. local playerunit = self:_GetPlayerUnitAndName( unit:GetName() ) if playerunit then return true else return false end end --- Checks if a group has a human player. -- @param #AIRBOSS self -- @param Wrapper.Group#GROUP group Aircraft group. -- @return #boolean If true, human player inside group. function AIRBOSS:_IsHuman( group ) -- Get all units of the group. local units = group:GetUnits() -- Loop over all units. for _, _unit in pairs( units ) do -- Check if unit is human. local human = self:_IsHumanUnit( _unit ) if human then return true end end return false end --- Get fuel state in pounds. -- @param #AIRBOSS self -- @param Wrapper.Unit#UNIT unit The unit for which the mass is determined. -- @return #number Fuel state in pounds. function AIRBOSS:_GetFuelState( unit ) -- Get relative fuel [0,1]. local fuel = unit:GetFuel() -- Get max weight of fuel in kg. local maxfuel = self:_GetUnitMasses( unit ) -- Fuel state, i.e. what let's local fuelstate = fuel * maxfuel -- Debug info. self:T2( self.lid .. string.format( "Unit %s fuel state = %.1f kg = %.1f lbs", unit:GetName(), fuelstate, UTILS.kg2lbs( fuelstate ) ) ) return UTILS.kg2lbs( fuelstate ) end --- Convert altitude from meters to angels (thousands of feet). -- @param #AIRBOSS self -- @param alt altitude in meters. -- @return #number Altitude in Anglels = thousands of feet using math.floor(). function AIRBOSS:_GetAngels( alt ) if alt then local angels = UTILS.Round( UTILS.MetersToFeet( alt ) / 1000, 0 ) return angels else return 0 end end --- Get unit masses especially fuel from DCS descriptor values. -- @param #AIRBOSS self -- @param Wrapper.Unit#UNIT unit The unit for which the mass is determined. -- @return #number Mass of fuel in kg. -- @return #number Empty weight of unit in kg. -- @return #number Max weight of unit in kg. -- @return #number Max cargo weight in kg. function AIRBOSS:_GetUnitMasses( unit ) -- Get DCS descriptors table. local Desc = unit:GetDesc() -- Mass of fuel in kg. local massfuel = Desc.fuelMassMax or 0 -- Mass of empty unit in km. local massempty = Desc.massEmpty or 0 -- Max weight of unit in kg. local massmax = Desc.massMax or 0 -- Rest is cargo. local masscargo = massmax - massfuel - massempty -- Debug info. self:T2( self.lid .. string.format( "Unit %s mass fuel=%.1f kg, empty=%.1f kg, max=%.1f kg, cargo=%.1f kg", unit:GetName(), massfuel, massempty, massmax, masscargo ) ) return massfuel, massempty, massmax, masscargo end --- Get player data from unit object -- @param #AIRBOSS self -- @param Wrapper.Unit#UNIT unit Unit in question. -- @return #AIRBOSS.PlayerData Player data or nil if not player with this name or unit exists. function AIRBOSS:_GetPlayerDataUnit( unit ) if unit:IsAlive() then local unitname = unit:GetName() local playerunit, playername = self:_GetPlayerUnitAndName( unitname ) if playerunit and playername then return self.players[playername] end end return nil end --- Get player data from group object. -- @param #AIRBOSS self -- @param Wrapper.Group#GROUP group Group in question. -- @return #AIRBOSS.PlayerData Player data or nil if not player with this name or unit exists. function AIRBOSS:_GetPlayerDataGroup( group ) local units = group:GetUnits() for _, unit in pairs( units ) do local playerdata = self:_GetPlayerDataUnit( unit ) if playerdata then return playerdata end end return nil end --- Returns the unit of a player and the player name from the self.players table if it exists. -- @param #AIRBOSS self -- @param #string _unitName Name of the player unit. -- @return Wrapper.Unit#UNIT Unit of player or nil. -- @return #string Name of player or nil. function AIRBOSS:_GetPlayerUnit( _unitName ) for _, _player in pairs( self.players ) do local player = _player -- #AIRBOSS.PlayerData if player.unit and player.unit:GetName() == _unitName then self:T( self.lid .. string.format( "Found player=%s unit=%s in players table.", tostring( player.name ), tostring( _unitName ) ) ) return player.unit, player.name end end return nil, nil end --- Returns the unit of a player and the player name. If the unit does not belong to a player, nil is returned. -- @param #AIRBOSS self -- @param #string _unitName Name of the player unit. -- @return Wrapper.Unit#UNIT Unit of player or nil. -- @return #string Name of the player or nil. function AIRBOSS:_GetPlayerUnitAndName( _unitName ) self:F2( _unitName ) if _unitName ~= nil then -- First, let's look up all current players. local u, pn = self:_GetPlayerUnit( _unitName ) -- Return if u and pn then return u, pn end -- Get DCS unit from its name. local DCSunit = Unit.getByName( _unitName ) if DCSunit and DCSunit.getPlayerName then -- Get player name if any. local playername = DCSunit:getPlayerName() -- Unit object. local unit = UNIT:Find( DCSunit ) -- Debug. self:T2( { DCSunit = DCSunit, unit = unit, playername = playername } ) -- Check if enverything is there. if DCSunit and unit and playername then self:T( self.lid .. string.format( "Found DCS unit %s with player %s.", tostring( _unitName ), tostring( playername ) ) ) return unit, playername end end end -- Return nil if we could not find a player. return nil, nil end --- Get carrier coalition. -- @param #AIRBOSS self -- @return #number Coalition side of carrier. function AIRBOSS:GetCoalition() return self.carrier:GetCoalition() end --- Get carrier coordinate. -- @param #AIRBOSS self -- @return Core.Point#COORDINATE Carrier coordinate. function AIRBOSS:GetCoordinate() return self.carrier:GetCoord() end --- Get carrier coordinate. -- @param #AIRBOSS self -- @return Core.Point#COORDINATE Carrier coordinate. function AIRBOSS:GetCoord() return self.carrier:GetCoord() end --- Get static weather of this mission from env.mission.weather. -- @param #AIRBOSS self -- @param #table Clouds table which has entries "thickness", "density", "base", "iprecptns". -- @param #number Visibility distance in meters. -- @param #table Fog table, which has entries "thickness", "visibility" or nil if fog is disabled in the mission. -- @param #number Dust density or nil if dust is disabled in the mission. function AIRBOSS:_GetStaticWeather() -- Weather data from mission file. local weather = env.mission.weather -- Clouds --[[ ["clouds"] = { ["thickness"] = 430, ["density"] = 7, ["base"] = 0, ["iprecptns"] = 1, }, -- end of ["clouds"] ]] local clouds = weather.clouds -- Visibilty distance in meters. local visibility = weather.visibility.distance -- Dust --[[ ["enable_dust"] = false, ["dust_density"] = 0, ]] local dust = nil if weather.enable_dust == true then dust = weather.dust_density end -- Fog --[[ ["enable_fog"] = false, ["fog"] = { ["thickness"] = 0, ["visibility"] = 25, }, -- end of ["fog"] ]] local fog = nil if weather.enable_fog == true then fog = weather.fog end return clouds, visibility, fog, dust end ----------------------------------------------------------------------------------------------------------------------------------------------------------------------- -- RADIO MESSAGE Functions ----------------------------------------------------------------------------------------------------------------------------------------------------------------------- --- Function called by DCS timer. Unused. -- @param #table param Parameters. -- @param #number time Time. function AIRBOSS._CheckRadioQueueT( param, time ) AIRBOSS._CheckRadioQueue( param.airboss, param.radioqueue, param.name ) return time + 0.05 end --- Radio queue item. -- @type AIRBOSS.Radioitem -- @field #number Tplay Abs time when transmission should be played. -- @field #number Tstarted Abs time when transmission began to play. -- @field #boolean isplaying Currently playing. -- @field #AIRBOSS.Radio radio Radio object. -- @field #AIRBOSS.RadioCall call Radio call. -- @field #boolean loud If true, play loud version of file. -- @field #number interval Interval in seconds after the last sound was played. --- Check radio queue for transmissions to be broadcasted. -- @param #AIRBOSS self -- @param #table radioqueue The radio queue. -- @param #string name Name of the queue. function AIRBOSS:_CheckRadioQueue( radioqueue, name ) -- env.info(string.format("FF %s #radioqueue %d", name, #radioqueue)) -- Check if queue is empty. if #radioqueue == 0 then if name == "LSO" then self:T( self.lid .. string.format( "Stopping LSO radio queue." ) ) self.radiotimer:Stop( self.RQLid ) self.RQLid = nil elseif name == "MARSHAL" then self:T( self.lid .. string.format( "Stopping Marshal radio queue." ) ) self.radiotimer:Stop( self.RQMid ) self.RQMid = nil end return end -- Get current abs time. local _time = timer.getAbsTime() local playing = false local next = nil -- #AIRBOSS.Radioitem local _remove = nil for i, _transmission in ipairs( radioqueue ) do local transmission = _transmission -- #AIRBOSS.Radioitem -- Check if transmission time has passed. if _time >= transmission.Tplay then -- Check if transmission is currently playing. if transmission.isplaying then -- Check if transmission is finished. if _time >= transmission.Tstarted + transmission.call.duration then -- Transmission over. transmission.isplaying = false _remove = i if transmission.radio.alias == "LSO" then self.TQLSO = _time elseif transmission.radio.alias == "MARSHAL" then self.TQMarshal = _time end else -- still playing -- Transmission is still playing. playing = true end else -- not playing yet local Tlast = nil if transmission.interval then if transmission.radio.alias == "LSO" then Tlast = self.TQLSO elseif transmission.radio.alias == "MARSHAL" then Tlast = self.TQMarshal end end if transmission.interval == nil then -- Not playing ==> this will be next. if next == nil then next = transmission end else if _time - Tlast >= transmission.interval then next = transmission else end end -- We got a transmission or one with an interval that is not due yet. No need for anything else. if next or Tlast then break end end else -- Transmission not due yet. end end -- Found a new transmission. if next ~= nil and not playing then self:Broadcast( next.radio, next.call, next.loud ) next.isplaying = true next.Tstarted = _time end -- Remove completed calls from queue. if _remove then table.remove( radioqueue, _remove ) end return end --- Add Radio transmission to radio queue. -- @param #AIRBOSS self -- @param #AIRBOSS.Radio radio Radio sending the transmission. -- @param #AIRBOSS.RadioCall call Radio sound files and subtitles. -- @param #boolean loud If true, play loud sound file version. -- @param #number delay Delay in seconds, before the message is broadcasted. -- @param #number interval Interval in seconds after the last sound has been played. -- @param #boolean click If true, play radio click at the end. -- @param #boolean pilotcall If true, it's a pilot call. function AIRBOSS:RadioTransmission( radio, call, loud, delay, interval, click, pilotcall ) self:F2( { radio = radio, call = call, loud = loud, delay = delay, interval = interval, click = click } ) -- Nil check. if radio == nil or call == nil then return end if not self.SRS then -- Create a new radio transmission item. local transmission = {} -- #AIRBOSS.Radioitem transmission.radio = radio transmission.call = call transmission.Tplay = timer.getAbsTime() + (delay or 0) transmission.interval = interval transmission.isplaying = false transmission.Tstarted = nil transmission.loud = loud and call.loud -- Player onboard number if sender has one. if self:_IsOnboard( call.modexsender ) then self:_Number2Radio( radio, call.modexsender, delay, 0.3, pilotcall ) end -- Play onboard number if receiver has one. if self:_IsOnboard( call.modexreceiver ) then self:_Number2Radio( radio, call.modexreceiver, delay, 0.3, pilotcall ) end -- Add transmission to the right queue. local caller = "" if radio.alias == "LSO" then table.insert( self.RQLSO, transmission ) caller = "LSOCall" -- Schedule radio queue checks. if not self.RQLid then self:T( self.lid .. string.format( "Starting LSO radio queue." ) ) self.RQLid = self.radiotimer:Schedule( nil, AIRBOSS._CheckRadioQueue, { self, self.RQLSO, "LSO" }, 0.02, 0.05 ) end elseif radio.alias == "MARSHAL" then table.insert( self.RQMarshal, transmission ) caller = "MarshalCall" if not self.RQMid then self:T( self.lid .. string.format( "Starting Marhal radio queue." ) ) self.RQMid = self.radiotimer:Schedule( nil, AIRBOSS._CheckRadioQueue, { self, self.RQMarshal, "MARSHAL" }, 0.02, 0.05 ) end end -- Append radio click sound at the end of the transmission. if click then self:RadioTransmission( radio, self[caller].CLICK, false, delay ) end else -- SRS transmission if call.subtitle ~= nil and string.len(call.subtitle) > 1 then local frequency = self.MarshalRadio.frequency local modulation = self.MarshalRadio.modulation local voice = nil local gender = nil local culture = nil if radio.alias == "AIRBOSS" then frequency = self.AirbossRadio.frequency modulation = self.AirbossRadio.modulation voice = self.AirbossRadio.voice gender = self.AirbossRadio.gender culture = self.AirbossRadio.culture end if radio.alias == "MARSHAL" then voice = self.MarshalRadio.voice gender = self.MarshalRadio.gender culture = self.MarshalRadio.culture end if radio.alias == "LSO" then frequency = self.LSORadio.frequency modulation = self.LSORadio.modulation voice = self.LSORadio.voice gender = self.LSORadio.gender culture = self.LSORadio.culture end if pilotcall then voice = self.PilotRadio.voice gender = self.PilotRadio.gender culture = self.PilotRadio.culture radio.alias = "PILOT" end if not radio.alias then -- TODO - what freq to use here? frequency = self.AirbossRadio.frequency modulation = self.AirbossRadio.modulation radio.alias = "AIRBOSS" end local volume = nil if loud then volume = 1.0 end --local text = tostring(call.modexreceiver).."; "..radio.alias.."; "..call.subtitle local text = call.subtitle self:T(self.lid..text) local srstext = self:_GetNiceSRSText(text) self.SRSQ:NewTransmission(srstext, call.duration, self.SRS, nil, 0.1, nil, call.subtitle, call.subduration, frequency, modulation, gender, culture, voice, volume, radio.alias) end end end --- Set SRS voice for the pilot calls. -- @param #AIRBOSS self -- @param #string Voice (Optional) SRS specific voice -- @param #string Gender (Optional) SRS specific gender -- @param #string Culture (Optional) SRS specific culture -- @return #AIRBOSS self function AIRBOSS:SetSRSPilotVoice( Voice, Gender, Culture ) self.PilotRadio = {} -- #AIRBOSS.Radio self.PilotRadio.alias = "PILOT" self.PilotRadio.voice = Voice or MSRS.Voices.Microsoft.David self.PilotRadio.gender = Gender or "male" self.PilotRadio.culture = Culture or "en-US" if (not Voice) and self.SRS and self.SRS:GetProvider() == MSRS.Provider.GOOGLE then self.PilotRadio.voice = MSRS.Voices.Google.Standard.en_US_Standard_J end return self end --- Check if a call needs a subtitle because the complete voice overs are not available. -- @param #AIRBOSS self -- @param #AIRBOSS.RadioCall call Radio sound files and subtitles. -- @return #boolean If true, call needs a subtitle. function AIRBOSS:_NeedsSubtitle( call ) -- Currently we play the noise file. if call.file == self.MarshalCall.NOISE.file or call.file == self.LSOCall.NOISE.file then return true else return false end end --- Broadcast radio message. -- @param #AIRBOSS self -- @param #AIRBOSS.Radio radio Radio sending transmission. -- @param #AIRBOSS.RadioCall call Radio sound files and subtitles. -- @param #boolean loud Play loud version of file. function AIRBOSS:Broadcast( radio, call, loud ) self:F( call ) -- Check which sound output method to use. if not self.usersoundradio then ---------------------------- -- Transmission via Radio -- ---------------------------- -- Get unit sending the transmission. local sender = self:_GetRadioSender( radio ) -- Construct file name and subtitle. local filename = self:_RadioFilename( call, loud, radio.alias ) -- Create subtitle for transmission. local subtitle = self:_RadioSubtitle( radio, call, loud ) -- Debug. self:T( { filename = filename, subtitle = subtitle } ) if sender then -- Broadcasting from aircraft. Only players tuned in to the right frequency will see the message. self:T( self.lid .. string.format( "Broadcasting from aircraft %s", sender:GetName() ) ) -- Command to set the Frequency for the transmission. local commandFrequency = { id = "SetFrequency", params = { frequency = radio.frequency * 1000000, -- Frequency in Hz. modulation = radio.modulation, }, } -- Command to tranmit the call. local commandTransmit = { id = "TransmitMessage", params = { file = filename, duration = call.subduration or 5, subtitle = subtitle, loop = false, }, } -- Set commend for frequency sender:SetCommand( commandFrequency ) -- Set command for radio transmission. sender:SetCommand( commandTransmit ) else -- Broadcasting from carrier. No subtitle possible. Need to send messages to players. self:T( self.lid .. string.format( "Broadcasting from carrier via trigger.action.radioTransmission()." ) ) -- Transmit from carrier position. local vec3 = self.carrier:GetPositionVec3() -- Transmit via trigger. trigger.action.radioTransmission( filename, vec3, radio.modulation, false, radio.frequency * 1000000, 100 ) -- Display subtitle of message to players. for _, _player in pairs( self.players ) do local playerData = _player -- #AIRBOSS.PlayerData -- Message to all players in CCA that have subtites on. if playerData.unit:IsInZone( self.zoneCCA ) and playerData.actype ~= AIRBOSS.AircraftCarrier.A4EC then -- Only to players with subtitle on or if noise is played. if playerData.subtitles or self:_NeedsSubtitle( call ) then -- Messages to marshal to everyone. Messages on LSO radio only to those in the pattern. if radio.alias == "MARSHAL" or (radio.alias == "LSO" and self:_InQueue( self.Qpattern, playerData.group )) then -- Message to player. self:MessageToPlayer( playerData, subtitle, nil, "", call.subduration or 5 ) end end end end end end ---------------- -- Easy Comms -- ---------------- -- Workaround for the community A-4E-C as long as their radios are not functioning properly. for _, _player in pairs( self.players ) do local playerData = _player -- #AIRBOSS.PlayerData -- Easy comms if globally activated but definitly for all player in the community A-4E. if self.usersoundradio or playerData.actype == AIRBOSS.AircraftCarrier.A4EC then -- Messages to marshal to everyone. Messages on LSO radio only to those in the pattern. if radio.alias == "MARSHAL" or (radio.alias == "LSO" and self:_InQueue( self.Qpattern, playerData.group )) then -- User sound to players (inside CCA). self:Sound2Player( playerData, radio, call, loud ) end end end end --- Player user sound to player if he is inside the CCA. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data. -- @param #AIRBOSS.Radio radio The radio used for transmission. -- @param #AIRBOSS.RadioCall call Radio sound files and subtitles. -- @param #boolean loud If true, play loud sound file version. -- @param #number delay Delay in seconds, before the message is broadcasted. function AIRBOSS:Sound2Player( playerData, radio, call, loud, delay ) -- Only to players inside the CCA. if playerData.unit:IsInZone( self.zoneCCA ) and call then -- Construct file name. local filename = self:_RadioFilename( call, loud, radio.alias ) -- Get Subtitle local subtitle = self:_RadioSubtitle( radio, call, loud ) -- Play sound file via usersound trigger. USERSOUND:New( filename ):ToGroup( playerData.group, delay ) -- Only to players with subtitle on or if noise is played. if playerData.subtitles or self:_NeedsSubtitle( call ) then self:MessageToPlayer( playerData, subtitle, nil, "", call.subduration, false, delay ) end end end --- Create radio subtitle from radio call. -- @param #AIRBOSS self -- @param #AIRBOSS.Radio radio The radio used for transmission. -- @param #AIRBOSS.RadioCall call Radio sound files and subtitles. -- @param #boolean loud If true, append "!" else ".". -- @return #string Subtitle to be displayed. function AIRBOSS:_RadioSubtitle( radio, call, loud ) -- No subtitle if call is nil, or subtitle is nil or subtitle is empty. if call == nil or call.subtitle == nil or call.subtitle == "" then return "" end -- Sender local sender = call.sender or radio.alias if call.modexsender then sender = call.modexsender end -- Modex of receiver. local receiver = call.modexreceiver or "" -- Init subtitle. local subtitle = string.format( "%s: %s", sender, call.subtitle ) if receiver and receiver ~= "" then subtitle = string.format( "%s: %s, %s", sender, receiver, call.subtitle ) end -- Last character of the string. local lastchar = string.sub( subtitle, -1 ) -- Append ! or . if loud then if lastchar == "." or lastchar == "!" then subtitle = string.sub( subtitle, 1, -1 ) end subtitle = subtitle .. "!" else if lastchar == "!" then -- This also okay. elseif lastchar == "." then -- Nothing to do. else subtitle = subtitle .. "." end end return subtitle end --- Get full file name for radio call. -- @param #AIRBOSS self -- @param #AIRBOSS.RadioCall call Radio sound files and subtitles. -- @param #boolean loud Use loud version of file if available. -- @param #string channel Radio channel alias "LSO" or "LSOCall", "MARSHAL" or "MarshalCall". -- @return #string The file name of the radio sound. function AIRBOSS:_RadioFilename( call, loud, channel ) -- Construct file name and subtitle. local prefix = call.file or "" local suffix = call.suffix or "ogg" -- Path to sound files. Default is in the ME local path = self.soundfolder or "l10n/DEFAULT/" -- Check for special LSO and Marshal sound folders. if string.find( call.file, "LSO-" ) and channel and (channel == "LSO" or channel == "LSOCall") then path = self.soundfolderLSO or path end if string.find( call.file, "MARSHAL-" ) and channel and (channel == "MARSHAL" or channel == "MarshalCall") then path = self.soundfolderMSH or path end -- Loud version. if loud then prefix = prefix .. "_Loud" end -- File name inclusing path in miz file. local filename = string.format( "%s%s.%s", path, prefix, suffix ) return filename end --- Format text into SRS friendly string -- @param #AIRBOSS self -- @param #string text -- @return #string text function AIRBOSS:_GetNiceSRSText(text) text = string.gsub(text,"================================\n","") text = string.gsub(text,"||","parallel") text = string.gsub(text,"==","perpendicular") text = string.gsub(text,"BRC","Base recovery") --text = string.gsub(text,"#","Number") text = string.gsub(text,"%((%a+)%)","Morse %1") text = string.gsub(text,"°C","° Celsius") text = string.gsub(text,"°"," degrees") text = string.gsub(text," FB "," Final bearing ") text = string.gsub(text," ops"," operations ") text = string.gsub(text," kts"," knots") text = string.gsub(text,"TACAN","Tackan") text = string.gsub(text,"ICLS","I.C.L.S.") text = string.gsub(text,"LSO","L.S.O.") text = string.gsub(text,"inHg","inches of Mercury") text = string.gsub(text,"QFE","Q.F.E.") text = string.gsub(text,"hPa","hecto pascal") text = string.gsub(text," NM"," nautical miles") text = string.gsub(text," ft"," feet") text = string.gsub(text,"A/C","aircraft") text = string.gsub(text,"(#[%a%d%p%s]+)\n","") text = string.gsub(text,"%.000"," dot zero") text = string.gsub(text,"00"," double zero") text = string.gsub(text," 0 "," zero " ) text = string.gsub(text,"\n","; ") return text end --- Send text message to player client. -- Message format will be "SENDER: RECCEIVER, MESSAGE". -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data. -- @param #string message The message to send. -- @param #string sender The person who sends the message or nil. -- @param #string receiver The person who receives the message. Default player's onboard number. Set to "" for no receiver. -- @param #number duration Display message duration. Default 10 seconds. -- @param #boolean clear If true, clear screen from previous messages. -- @param #number delay Delay in seconds, before the message is displayed. function AIRBOSS:MessageToPlayer( playerData, message, sender, receiver, duration, clear, delay ) self:T({sender,receiver,message}) if playerData and message and message ~= "" then -- Default duration. duration = duration or self.Tmessage -- Format message. local text if receiver and receiver == "" then -- No (blank) receiver. text = string.format( "%s", message ) else -- Default "receiver" is onboard number of player. receiver = receiver or playerData.onboard text = string.format( "%s, %s", receiver, message ) end self:T( self.lid .. text ) if delay and delay > 0 then -- Delayed call. -- SCHEDULER:New(nil, self.MessageToPlayer, {self, playerData, message, sender, receiver, duration, clear}, delay) self:ScheduleOnce( delay, self.MessageToPlayer, self, playerData, message, sender, receiver, duration, clear ) else if not self.SRS then -- Wait until previous sound finished. local wait = 0 -- Onboard number to get the attention. if receiver == playerData.onboard then -- Which voice over number to use. if sender and (sender == "LSO" or sender == "MARSHAL" or sender == "AIRBOSS") then -- User sound of board number. wait = wait + self:_Number2Sound( playerData, sender, receiver ) end end -- Negative. if string.find( text:lower(), "negative" ) then local filename = self:_RadioFilename( self.MarshalCall.NEGATIVE, false, "MARSHAL" ) USERSOUND:New( filename ):ToGroup( playerData.group, wait ) wait = wait + self.MarshalCall.NEGATIVE.duration end -- Affirm. if string.find( text:lower(), "affirm" ) then local filename = self:_RadioFilename( self.MarshalCall.AFFIRMATIVE, false, "MARSHAL" ) USERSOUND:New( filename ):ToGroup( playerData.group, wait ) wait = wait + self.MarshalCall.AFFIRMATIVE.duration end -- Roger. if string.find( text:lower(), "roger" ) then local filename = self:_RadioFilename( self.MarshalCall.ROGER, false, "MARSHAL" ) USERSOUND:New( filename ):ToGroup( playerData.group, wait ) wait = wait + self.MarshalCall.ROGER.duration end -- Play click sound to end message. if wait > 0 then local filename = self:_RadioFilename( self.MarshalCall.CLICK ) USERSOUND:New( filename ):ToGroup( playerData.group, wait ) end else -- SRS transmission local frequency = self.MarshalRadio.frequency local modulation = self.MarshalRadio.modulation local voice = self.MarshalRadio.voice local gender = self.MarshalRadio.gender local culture = self.MarshalRadio.culture if not sender then sender = "AIRBOSS" end if string.find(sender,"AIRBOSS" ) then frequency = self.AirbossRadio.frequency modulation = self.AirbossRadio.modulation voice = self.AirbossRadio.voice gender = self.AirbossRadio.gender culture = self.AirbossRadio.culture end --if sender == "MARSHAL" then --voice = self.MarshalRadio.voice --gender = self.MarshalRadio.gender --culture = self.MarshalRadio.culture --end if sender == "LSO" then frequency = self.LSORadio.frequency modulation = self.LSORadio.modulation voice = self.LSORadio.voice gender = self.LSORadio.gender culture = self.LSORadio.culture --elseif not sender then -- TODO - what freq to use here? --frequency = self.AirbossRadio.frequency --modulation = self.AirbossRadio.modulation --sender = "AIRBOSS" end self:T(self.lid..text) self:T({sender,frequency,modulation,voice}) local srstext = self:_GetNiceSRSText(text) self.SRSQ:NewTransmission(srstext,duration,self.SRS,nil,0.1,nil,nil,nil,frequency,modulation,gender,culture,voice,nil,sender) end -- Text message to player client. if playerData.client then MESSAGE:New( text, duration, sender, clear ):ToClient( playerData.client ) end end end end --- Send text message to all players in the pattern queue. -- Message format will be "SENDER: RECCEIVER, MESSAGE". -- @param #AIRBOSS self -- @param #string message The message to send. -- @param #string sender The person who sends the message or nil. -- @param #string receiver The person who receives the message. Default player's onboard number. Set to "" for no receiver. -- @param #number duration Display message duration. Default 10 seconds. -- @param #boolean clear If true, clear screen from previous messages. -- @param #number delay Delay in seconds, before the message is displayed. function AIRBOSS:MessageToPattern( message, sender, receiver, duration, clear, delay ) -- Create new (fake) radio call to show the subtitile. local call = self:_NewRadioCall( self.LSOCall.NOISE, sender or "LSO", message, duration, receiver, sender ) -- Dummy radio transmission to display subtitle only to those who tuned in. self:RadioTransmission( self.LSORadio, call, false, delay, nil, true ) end --- Send text message to all players in the marshal queue. -- Message format will be "SENDER: RECCEIVER, MESSAGE". -- @param #AIRBOSS self -- @param #string message The message to send. -- @param #string sender The person who sends the message or nil. -- @param #string receiver The person who receives the message. Default player's onboard number. Set to "" for no receiver. -- @param #number duration Display message duration. Default 10 seconds. -- @param #boolean clear If true, clear screen from previous messages. -- @param #number delay Delay in seconds, before the message is displayed. function AIRBOSS:MessageToMarshal( message, sender, receiver, duration, clear, delay ) -- Create new (fake) radio call to show the subtitile. local call = self:_NewRadioCall( self.MarshalCall.NOISE, sender or "MARSHAL", message, duration, receiver, sender ) -- Dummy radio transmission to display subtitle only to those who tuned in. self:RadioTransmission( self.MarshalRadio, call, false, delay, nil, true ) end --- Generate a new radio call (deepcopy) from an existing default call. -- @param #AIRBOSS self -- @param #AIRBOSS.RadioCall call Radio call to be enhanced. -- @param #string sender Sender of the message. Default is the radio alias. -- @param #string subtitle Subtitle of the message. Default from original radio call. Use "" for no subtitle. -- @param #number subduration Time in seconds the subtitle is displayed. Default 10 seconds. -- @param #string modexreceiver Onboard number of the receiver or nil. -- @param #string modexsender Onboard number of the sender or nil. function AIRBOSS:_NewRadioCall( call, sender, subtitle, subduration, modexreceiver, modexsender ) -- Create a new call local newcall = UTILS.DeepCopy( call ) -- #AIRBOSS.RadioCall -- Sender for displaying the subtitle. newcall.sender = sender -- Subtitle of the message. newcall.subtitle = subtitle or call.subtitle -- Duration of subtitle display. newcall.subduration = subduration or self.Tmessage -- Tail number of the receiver. if self:_IsOnboard( modexreceiver ) then newcall.modexreceiver = modexreceiver end -- Tail number of the sender. if self:_IsOnboard( modexsender ) then newcall.modexsender = modexsender end return newcall end --- Get unit from which we want to transmit a radio message. This has to be an aircraft for subtitles to work. -- @param #AIRBOSS self -- @param #AIRBOSS.Radio radio Airboss radio data. -- @return Wrapper.Unit#UNIT Sending aircraft unit or nil if was not setup, is not an aircraft or is not alive. function AIRBOSS:_GetRadioSender( radio ) -- Check if we have a sending aircraft. local sender = nil -- Wrapper.Unit#UNIT -- Try the general default. if self.senderac then sender = UNIT:FindByName( self.senderac ) end -- Try the specific marshal unit. if radio.alias == "MARSHAL" then if self.radiorelayMSH then sender = UNIT:FindByName( self.radiorelayMSH ) end end -- Try the specific LSO unit. if radio.alias == "LSO" then if self.radiorelayLSO then sender = UNIT:FindByName( self.radiorelayLSO ) end end -- Check that sender is alive and an aircraft. if sender and sender:IsAlive() and sender:IsAir() then return sender end return nil end --- Check if text is an onboard number of a flight. -- @param #AIRBOSS self -- @param #string text Text to check. -- @return #boolean If true, text is an onboard number of a flight. function AIRBOSS:_IsOnboard( text ) -- Nil check. if text == nil then return false end -- Message to all. if text == "99" then return true end -- Loop over all flights. for _, _flight in pairs( self.flights ) do local flight = _flight -- #AIRBOSS.FlightGroup -- Loop over all onboard number of that flight. for _, onboard in pairs( flight.onboardnumbers ) do if text == onboard then return true end end end return false end --- Convert a number (as string) into an outsound and play it to a player group. E.g. for board number or headings. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data. -- @param #string sender Who is sending the call, either "LSO" or "MARSHAL". -- @param #string number Number string, e.g. "032" or "183". -- @param #number delay Delay before transmission in seconds. -- @return #number Duration of the call in seconds. function AIRBOSS:_Number2Sound( playerData, sender, number, delay ) -- Default. delay = delay or 0 --- Split string into characters. local function _split( str ) local chars = {} for i = 1, #str do local c = str:sub( i, i ) table.insert( chars, c ) end return chars end -- Sender local Sender if sender == "LSO" then Sender = "LSOCall" elseif sender == "MARSHAL" or sender == "AIRBOSS" then Sender = "MarshalCall" else self:E( self.lid .. string.format( "ERROR: Unknown radio sender %s!", tostring( sender ) ) ) return end -- Split string into characters. local numbers = _split( tostring(number) ) local wait = 0 for i = 1, #numbers do -- Current number local n = numbers[i] -- Convert to N0, N1, ... local N = string.format( "N%s", n ) -- Radio call. local call = self[Sender][N] -- #AIRBOSS.RadioCall -- Create file name. local filename = self:_RadioFilename( call, false, Sender ) -- Play sound. USERSOUND:New( filename ):ToGroup( playerData.group, delay + wait ) -- Wait until this call is over before playing the next. wait = wait + call.duration end return wait end --- Convert a number (as string) into a radio message. -- E.g. for board number or headings. -- @param #AIRBOSS self -- @param #AIRBOSS.Radio radio Radio used for transmission. -- @param #string number Number string, e.g. "032" or "183". -- @param #number delay Delay before transmission in seconds. -- @param #number interval Interval between the next call. -- @param #boolean pilotcall If true, use pilot sound files. -- @return #number Duration of the call in seconds. function AIRBOSS:_Number2Radio( radio, number, delay, interval, pilotcall ) --- Split string into characters. local function _split( str ) local chars = {} for i = 1, #str do local c = str:sub( i, i ) table.insert( chars, c ) end return chars end -- Sender. local Sender = "" if radio.alias == "LSO" then Sender = "LSOCall" elseif radio.alias == "MARSHAL" then Sender = "MarshalCall" else self:E( self.lid .. string.format( "ERROR: Unknown radio alias %s!", tostring( radio.alias ) ) ) end if pilotcall then Sender = "PilotCall" end if Sender=="" then self:E( self.lid .. string.format( "ERROR: Sender unknown!") ) return end -- Split string into characters. local numbers = _split( tostring(number) ) local wait = 0 for i = 1, #numbers do -- Current number local n = numbers[i] -- Convert to N0, N1, ... local N = string.format( "N%s", n ) -- Radio call. local call = self[Sender][N] -- #AIRBOSS.RadioCall if interval and i == 1 then -- Transmit. self:RadioTransmission( radio, call, false, delay, interval ) else self:RadioTransmission( radio, call, false, delay ) end -- Add up duration of the number. wait = wait + call.duration end -- Return the total duration of the call. return wait end --- Aircraft request marshal (Inbound call both for players and AI). -- @param #AIRBOSS self -- @return Wrapper.Unit#UNIT Unit of player or nil. -- @param #string modex Tail number. function AIRBOSS:_MarshallInboundCall(unit, modex) -- Calculate local vectorCarrier = self:GetCoordinate():GetDirectionVec3(unit:GetCoordinate()) local bearing = UTILS.Round(unit:GetCoordinate():GetAngleDegrees( vectorCarrier ), 0) local distance = UTILS.Round(UTILS.MetersToNM(unit:GetCoordinate():Get2DDistance(self:GetCoordinate())),0) local angels = UTILS.Round(UTILS.MetersToFeet(unit:GetHeight()/1000),0) local state = UTILS.Round(self:_GetFuelState(unit)/1000,1) -- Pilot: "Marshall, [modex], marking mom's [bearing] for [distance], angels [XX], state [X.X]" local text=string.format("Marshal, %s, marking mom's %d for %d, angels %d, state %.1f", modex, bearing, distance, angels, state) -- Debug message. self:T(self.lid..text) -- Fuel state. local FS=UTILS.Split(string.format("%.1f", state), ".") -- Create new call to display complete subtitle. local inboundcall=self:_NewRadioCall(self.MarshalCall.CLICK, unit.UnitName:upper() , text, self.Tmessage, nil, unit.UnitName:upper()) -- CLICK! self:RadioTransmission(self.MarshalRadio, inboundcall) -- Marshal .. self:RadioTransmission(self.MarshalRadio, self.PilotCall.MARSHAL, nil, nil, nil, nil, true) -- Modex.. self:_Number2Radio(self.MarshalRadio, modex, nil, nil, true) -- Marking Mom's, self:RadioTransmission(self.MarshalRadio, self.PilotCall.MARKINGMOMS, nil, nil, nil, nil, true) -- Bearing .. self:_Number2Radio(self.MarshalRadio, tostring(bearing), nil, nil, true) -- For .. self:RadioTransmission(self.MarshalRadio, self.PilotCall.FOR, nil, nil, nil, nil, true) -- Distance .. self:_Number2Radio(self.MarshalRadio, tostring(distance), nil, nil, true) -- Angels .. self:RadioTransmission(self.MarshalRadio, self.PilotCall.ANGELS, nil, nil, nil, nil, true) -- Angels Number .. self:_Number2Radio(self.MarshalRadio, tostring(angels), nil, nil, true) -- State .. self:RadioTransmission(self.MarshalRadio, self.PilotCall.STATE, nil, nil, nil, nil, true) -- X.. self:_Number2Radio(self.MarshalRadio, FS[1], nil, nil, true) -- Point.. self:RadioTransmission(self.MarshalRadio, self.PilotCall.POINT, nil, nil, nil, nil, true) -- Y. self:_Number2Radio(self.MarshalRadio, FS[2], nil, nil, true) -- CLICK! self:RadioTransmission(self.MarshalRadio, self.MarshalRadio.CLICK, nil, nil, nil, nil, true) end --- Aircraft commencing call (both for players and AI). -- @param #AIRBOSS self -- @return Wrapper.Unit#UNIT Unit of player or nil. -- @param #string modex Tail number. function AIRBOSS:_CommencingCall(unit, modex) -- Pilot: "[modex], commencing" local text=string.format("%s, commencing", modex) -- Debug message. self:T(self.lid..text) -- Create new call to display complete subtitle. local commencingCall=self:_NewRadioCall(self.MarshalCall.CLICK, unit.UnitName:upper() , text, self.Tmessage, nil, unit.UnitName:upper()) -- Click self:RadioTransmission(self.MarshalRadio, commencingCall) -- Modex.. self:_Number2Radio(self.MarshalRadio, modex, nil, nil, true) -- Commencing self:RadioTransmission(self.MarshalRadio, self.PilotCall.COMMENCING, nil, nil, nil, nil, true) -- CLICK! self:RadioTransmission(self.MarshalRadio, self.MarshalRadio.CLICK, nil, nil, nil, nil, true) end --- AI aircraft calls the ball. -- @param #AIRBOSS self -- @param #string modex Tail number. -- @param #string nickname Aircraft nickname. -- @param #number fuelstate Aircraft fuel state in thouthands of pounds. function AIRBOSS:_LSOCallAircraftBall( modex, nickname, fuelstate ) -- Pilot: "405, Hornet Ball, 3.2" local text = string.format( "%s Ball, %.1f.", nickname, fuelstate ) -- Debug message. self:T( self.lid .. text ) -- Nickname UPPERCASE. local NICKNAME = nickname:upper() -- Fuel state. local FS = UTILS.Split( string.format( "%.1f", fuelstate ), "." ) -- Create new call to display complete subtitle. local call = self:_NewRadioCall( self.PilotCall[NICKNAME], modex, text, self.Tmessage, nil, modex ) -- Hornet .. self:RadioTransmission( self.LSORadio, call, nil, nil, nil, nil, true ) -- Ball, self:RadioTransmission( self.LSORadio, self.PilotCall.BALL, nil, nil, nil, nil, true ) -- X.. self:_Number2Radio( self.LSORadio, FS[1], nil, nil, true ) -- Point.. self:RadioTransmission( self.LSORadio, self.PilotCall.POINT, nil, nil, nil, nil, true ) -- Y. self:_Number2Radio( self.LSORadio, FS[2], nil, nil, true ) -- CLICK! self:RadioTransmission( self.LSORadio, self.LSOCall.CLICK ) end --- AI is bingo and goes to the recovery tanker. -- @param #AIRBOSS self -- @param #string modex Tail number. function AIRBOSS:_MarshalCallGasAtTanker( modex ) -- Subtitle. local text = string.format( "Bingo fuel! Going for gas at the recovery tanker." ) -- Debug message. self:T( self.lid .. text ) -- Create new call to display complete subtitle. local call = self:_NewRadioCall( self.PilotCall.BINGOFUEL, modex, text, self.Tmessage, nil, modex ) -- MODEX, bingo fuel! self:RadioTransmission( self.MarshalRadio, call, nil, nil, nil, nil, true ) -- Going for fuel at the recovery tanker. Click! self:RadioTransmission( self.MarshalRadio, self.PilotCall.GASATTANKER, nil, nil, nil, true, true ) end --- AI is bingo and goes to the divert field. -- @param #AIRBOSS self -- @param #string modex Tail number. -- @param #string divertname Name of the divert field. function AIRBOSS:_MarshalCallGasAtDivert( modex, divertname ) -- Subtitle. local text = string.format( "Bingo fuel! Going for gas at divert field %s.", divertname ) -- Debug message. self:T( self.lid .. text ) -- Create new call to display complete subtitle. local call = self:_NewRadioCall( self.PilotCall.BINGOFUEL, modex, text, self.Tmessage, nil, modex ) -- MODEX, bingo fuel! self:RadioTransmission( self.MarshalRadio, call, nil, nil, nil, nil, true ) -- Going for fuel at the divert field. Click! self:RadioTransmission( self.MarshalRadio, self.PilotCall.GASATDIVERT, nil, nil, nil, true, true ) end --- Inform everyone that recovery ops are stopped and deck is closed. -- @param #AIRBOSS self -- @param #number case Recovery case. function AIRBOSS:_MarshalCallRecoveryStopped( case ) -- Subtitle. local text = string.format( "Case %d recovery ops are stopped. Deck is closed.", case ) -- Debug message. self:T( self.lid .. text ) -- Create new call to display complete subtitle. local call = self:_NewRadioCall( self.MarshalCall.CASE, "AIRBOSS", text, self.Tmessage, "99" ) -- 99, Case.. self:RadioTransmission( self.MarshalRadio, call ) -- X. self:_Number2Radio( self.MarshalRadio, tostring( case ) ) -- recovery ops are stopped. self:RadioTransmission( self.MarshalRadio, self.MarshalCall.RECOVERYOPSSTOPPED, nil, nil, 0.2 ) -- Deck is closed. Click! self:RadioTransmission( self.MarshalRadio, self.MarshalCall.DECKCLOSED, nil, nil, nil, true ) end --- Inform everyone that recovery is paused and will resume at a certain time. -- @param #AIRBOSS self function AIRBOSS:_MarshalCallRecoveryPausedUntilFurtherNotice() -- Create new call. Subtitle already set. local call = self:_NewRadioCall( self.MarshalCall.RECOVERYPAUSEDNOTICE, "AIRBOSS", nil, self.Tmessage, "99" ) -- 99, aircraft recovery is paused until further notice. self:RadioTransmission( self.MarshalRadio, call, nil, nil, nil, true ) end --- Inform everyone that recovery is paused and will resume at a certain time. -- @param #AIRBOSS self -- @param #string clock Time. function AIRBOSS:_MarshalCallRecoveryPausedResumedAt( clock ) -- Get relevant part of clock. local _clock = UTILS.Split( clock, "+" ) local CT = UTILS.Split( _clock[1], ":" ) -- Subtitle. local text = string.format( "aircraft recovery is paused and will be resumed at %s.", clock ) -- Debug message. self:T( self.lid .. text ) -- Create new call with full subtitle. local call = self:_NewRadioCall( self.MarshalCall.RECOVERYPAUSEDRESUMED, "AIRBOSS", text, self.Tmessage, "99" ) -- 99, aircraft recovery is paused and will resume at... self:RadioTransmission( self.MarshalRadio, call ) -- XY.. (hours) self:_Number2Radio( self.MarshalRadio, CT[1] ) -- XY (minutes).. self:_Number2Radio( self.MarshalRadio, CT[2] ) -- hours. Click! self:RadioTransmission( self.MarshalRadio, self.MarshalCall.HOURS, nil, nil, nil, true ) end --- Inform flight that he is cleared for recovery. -- @param #AIRBOSS self -- @param #string modex Tail number. -- @param #number case Recovery case. function AIRBOSS:_MarshalCallClearedForRecovery( modex, case ) -- Subtitle. local text = string.format( "you're cleared for Case %d recovery.", case ) -- Debug message. self:T( self.lid .. text ) -- Create new call with full subtitle. local call = self:_NewRadioCall( self.MarshalCall.CLEAREDFORRECOVERY, "MARSHAL", text, self.Tmessage, modex ) -- Two second delay. local delay = 2 -- XYZ, you're cleared for case.. self:RadioTransmission( self.MarshalRadio, call, nil, delay ) -- X.. self:_Number2Radio( self.MarshalRadio, tostring( case ), delay ) -- recovery. Click! self:RadioTransmission( self.MarshalRadio, self.MarshalCall.RECOVERY, nil, delay, nil, true ) end --- Inform everyone that recovery is resumed after pause. -- @param #AIRBOSS self function AIRBOSS:_MarshalCallResumeRecovery() -- Create new call with full subtitle. local call = self:_NewRadioCall( self.MarshalCall.RESUMERECOVERY, "AIRBOSS", nil, self.Tmessage, "99" ) -- 99, aircraft recovery resumed. Click! self:RadioTransmission( self.MarshalRadio, call, nil, nil, nil, true ) end --- Inform everyone about new final bearing. -- @param #AIRBOSS self -- @param #number FB Final Bearing in degrees. function AIRBOSS:_MarshalCallNewFinalBearing( FB ) -- Subtitle. local text = string.format( "new final bearing %03d°.", FB ) -- Debug message. self:T( self.lid .. text ) -- Create new call with full subtitle. local call = self:_NewRadioCall( self.MarshalCall.NEWFB, "AIRBOSS", text, self.Tmessage, "99" ) -- 99, new final bearing.. self:RadioTransmission( self.MarshalRadio, call ) -- XYZ.. self:_Number2Radio( self.MarshalRadio, string.format( "%03d", FB ), nil, 0.2 ) -- Degrees. Click! self:RadioTransmission( self.MarshalRadio, self.MarshalCall.DEGREES, nil, nil, nil, true ) end --- Compile a radio call when Marshal tells a flight the holding altitude. -- @param #AIRBOSS self -- @param #number hdg Heading in degrees. function AIRBOSS:_MarshalCallCarrierTurnTo( hdg ) -- Subtitle. local text = string.format( "carrier is now starting turn to heading %03d°.", hdg ) -- Debug message. self:T( self.lid .. text ) -- Create new call with full subtitle. local call = self:_NewRadioCall( self.MarshalCall.CARRIERTURNTOHEADING, "AIRBOSS", text, self.Tmessage, "99" ) -- 99, turning to heading... self:RadioTransmission( self.MarshalRadio, call ) -- XYZ.. self:_Number2Radio( self.MarshalRadio, string.format( "%03d", hdg ), nil, 0.2 ) -- Degrees. Click! self:RadioTransmission( self.MarshalRadio, self.MarshalCall.DEGREES, nil, nil, nil, true ) end --- Compile a radio call when Marshal tells a flight the holding altitude. -- @param #AIRBOSS self -- @param #string modex Tail number. -- @param #number nwaiting Number of flights already waiting. function AIRBOSS:_MarshalCallStackFull( modex, nwaiting ) -- Subtitle. local text = string.format( "Marshal stack is currently full. Hold outside 10 NM zone and wait for further instructions. " ) if nwaiting == 1 then text = text .. string.format( "There is one flight ahead of you." ) elseif nwaiting > 1 then text = text .. string.format( "There are %d flights ahead of you.", nwaiting ) else text = text .. string.format( "You are next in line." ) end -- Debug message. self:T( self.lid .. text ) -- Create new call with full subtitle. local call = self:_NewRadioCall( self.MarshalCall.STACKFULL, "AIRBOSS", text, self.Tmessage, modex ) -- XYZ, Marshal stack is currently full. self:RadioTransmission( self.MarshalRadio, call, nil, nil, nil, true ) end --- Compile a radio call when Marshal tells a flight the holding altitude. -- @param #AIRBOSS self function AIRBOSS:_MarshalCallRecoveryStart( case ) -- Marshal radial. local radial = self:GetRadial( case, true, true, false ) -- Debug output. local text = string.format( "Starting aircraft recovery Case %d ops.", case ) if case == 1 then text = text .. string.format( " BRC %03d°.", self:GetBRC() ) elseif case == 2 then text = text .. string.format( " Marshal radial %03d°. BRC %03d°.", radial, self:GetBRC() ) elseif case == 3 then text = text .. string.format( " Marshal radial %03d°. Final heading %03d°.", radial, self:GetFinalBearing( false ) ) end self:T( self.lid .. text ) -- New call including the subtitle. local call = self:_NewRadioCall( self.MarshalCall.STARTINGRECOVERY, "AIRBOSS", text, self.Tmessage, "99" ) -- 99, Starting aircraft recovery case.. self:RadioTransmission( self.MarshalRadio, call ) -- X.. self:_Number2Radio( self.MarshalRadio, tostring( case ), nil, 0.1 ) -- ops. self:RadioTransmission( self.MarshalRadio, self.MarshalCall.OPS ) -- Marshal Radial if case > 1 then -- Marshal radial.. self:RadioTransmission( self.MarshalRadio, self.MarshalCall.MARSHALRADIAL ) -- XYZ.. self:_Number2Radio( self.MarshalRadio, string.format( "%03d", radial ), nil, 0.2 ) -- Degrees. self:RadioTransmission( self.MarshalRadio, self.MarshalCall.DEGREES, nil, nil, nil, true ) end end --- Compile a radio call when Marshal tells a flight the holding altitude. -- @param #AIRBOSS self -- @param #string modex Tail number. -- @param #number case Recovery case. -- @param #number brc Base recovery course. -- @param #number altitude Holding altitude. -- @param #string charlie Charlie Time estimate. -- @param #number qfe Alitmeter inHg. function AIRBOSS:_MarshalCallArrived( modex, case, brc, altitude, charlie, qfe ) self:F( { modex = modex, case = case, brc = brc, altitude = altitude, charlie = charlie, qfe = qfe } ) -- Split strings etc. local angels = self:_GetAngels( altitude ) -- local QFE=UTILS.Split(tostring(UTILS.Round(qfe,2)), ".") local QFE = UTILS.Split( string.format( "%.2f", qfe ), "." ) local clock = UTILS.Split( charlie, "+" ) local CT = UTILS.Split( clock[1], ":" ) -- Subtitle text. local text = string.format( "Case %d, expected BRC %03d°, hold at angels %d. Expected Charlie Time %s. Altimeter %.2f. Report see me.", case, brc, angels, charlie, qfe ) -- Debug message. self:T( self.lid .. text ) -- Create new call to display complete subtitle. local casecall = self:_NewRadioCall( self.MarshalCall.CASE, "MARSHAL", text, self.Tmessage, modex ) -- Case.. self:RadioTransmission( self.MarshalRadio, casecall ) -- X. self:_Number2Radio( self.MarshalRadio, tostring( case ) ) -- Expected.. self:RadioTransmission( self.MarshalRadio, self.MarshalCall.EXPECTED, nil, nil, 0.5 ) -- BRC.. self:RadioTransmission( self.MarshalRadio, self.MarshalCall.BRC ) -- XYZ... self:_Number2Radio( self.MarshalRadio, string.format( "%03d", brc ) ) -- Degrees. self:RadioTransmission( self.MarshalRadio, self.MarshalCall.DEGREES ) -- Hold at.. self:RadioTransmission( self.MarshalRadio, self.MarshalCall.HOLDATANGELS, nil, nil, 0.5 ) -- X. self:_Number2Radio( self.MarshalRadio, tostring( angels ) ) -- Expected.. self:RadioTransmission( self.MarshalRadio, self.MarshalCall.EXPECTED, nil, nil, 0.5 ) -- Charlie time.. self:RadioTransmission( self.MarshalRadio, self.MarshalCall.CHARLIETIME ) -- XY.. (hours) self:_Number2Radio( self.MarshalRadio, CT[1] ) -- XY (minutes). self:_Number2Radio( self.MarshalRadio, CT[2] ) -- hours. self:RadioTransmission( self.MarshalRadio, self.MarshalCall.HOURS ) -- Altimeter.. self:RadioTransmission( self.MarshalRadio, self.MarshalCall.ALTIMETER, nil, nil, 0.5 ) -- XY.. self:_Number2Radio( self.MarshalRadio, QFE[1] ) -- Point.. self:RadioTransmission( self.MarshalRadio, self.MarshalCall.POINT ) -- XY. self:_Number2Radio( self.MarshalRadio, QFE[2] ) -- Report see me. Click! self:RadioTransmission( self.MarshalRadio, self.MarshalCall.REPORTSEEME, nil, nil, 0.5, true ) end ----------------------------------------------------------------------------------------------------------------------------------------------------------------------- -- RADIO MENU Functions ----------------------------------------------------------------------------------------------------------------------------------------------------------------------- --- Add menu commands for player. -- @param #AIRBOSS self -- @param #string _unitName Name of player unit. function AIRBOSS:_AddF10Commands( _unitName ) self:F( _unitName ) -- Get player unit and name. local _unit, playername = self:_GetPlayerUnitAndName( _unitName ) -- Check for player unit. if _unit and playername then -- Get group and ID. local group = _unit:GetGroup() local gid = group:GetID() if group and gid then if not self.menuadded[gid] then -- Enable switch so we don't do this twice. self.menuadded[gid] = true -- Set menu root path. local _rootPath = nil if AIRBOSS.MenuF10Root then ------------------------ -- MISSON LEVEL MENUE -- ------------------------ if self.menusingle then -- F10/Airboss/... _rootPath = AIRBOSS.MenuF10Root else -- F10/Airboss//... _rootPath = missionCommands.addSubMenuForGroup( gid, self.alias, AIRBOSS.MenuF10Root ) end else ------------------------ -- GROUP LEVEL MENUES -- ------------------------ -- Main F10 menu: F10/Airboss/ if AIRBOSS.MenuF10[gid] == nil then AIRBOSS.MenuF10[gid] = missionCommands.addSubMenuForGroup( gid, "Airboss" ) end if self.menusingle then -- F10/Airboss/... _rootPath = AIRBOSS.MenuF10[gid] else -- F10/Airboss//... _rootPath = missionCommands.addSubMenuForGroup( gid, self.alias, AIRBOSS.MenuF10[gid] ) end end -------------------------------- -- F10/Airboss//F1 Help -------------------------------- local _helpPath = missionCommands.addSubMenuForGroup( gid, "Help", _rootPath ) -- F10/Airboss//F1 Help/F1 Mark Zones if self.menumarkzones then local _markPath = missionCommands.addSubMenuForGroup( gid, "Mark Zones", _helpPath ) -- F10/Airboss//F1 Help/F1 Mark Zones/ if self.menusmokezones then missionCommands.addCommandForGroup( gid, "Smoke Pattern Zones", _markPath, self._MarkCaseZones, self, _unitName, false ) -- F1 end missionCommands.addCommandForGroup( gid, "Flare Pattern Zones", _markPath, self._MarkCaseZones, self, _unitName, true ) -- F2 if self.menusmokezones then missionCommands.addCommandForGroup( gid, "Smoke Marshal Zone", _markPath, self._MarkMarshalZone, self, _unitName, false ) -- F3 end missionCommands.addCommandForGroup( gid, "Flare Marshal Zone", _markPath, self._MarkMarshalZone, self, _unitName, true ) -- F4 end -- F10/Airboss//F1 Help/F2 Skill Level local _skillPath = missionCommands.addSubMenuForGroup( gid, "Skill Level", _helpPath ) -- F10/Airboss//F1 Help/F2 Skill Level/ missionCommands.addCommandForGroup( gid, "Flight Student", _skillPath, self._SetDifficulty, self, _unitName, AIRBOSS.Difficulty.EASY ) -- F1 missionCommands.addCommandForGroup( gid, "Naval Aviator", _skillPath, self._SetDifficulty, self, _unitName, AIRBOSS.Difficulty.NORMAL ) -- F2 missionCommands.addCommandForGroup( gid, "TOPGUN Graduate", _skillPath, self._SetDifficulty, self, _unitName, AIRBOSS.Difficulty.HARD ) -- F3 missionCommands.addCommandForGroup( gid, "Hints On/Off", _skillPath, self._SetHintsOnOff, self, _unitName ) -- F4 -- F10/Airboss//F1 Help/ missionCommands.addCommandForGroup( gid, "My Status", _helpPath, self._DisplayPlayerStatus, self, _unitName ) -- F3 missionCommands.addCommandForGroup( gid, "Attitude Monitor", _helpPath, self._DisplayAttitude, self, _unitName ) -- F4 missionCommands.addCommandForGroup( gid, "Radio Check LSO", _helpPath, self._LSORadioCheck, self, _unitName ) -- F5 missionCommands.addCommandForGroup( gid, "Radio Check Marshal", _helpPath, self._MarshalRadioCheck, self, _unitName ) -- F6 missionCommands.addCommandForGroup( gid, "Subtitles On/Off", _helpPath, self._SubtitlesOnOff, self, _unitName ) -- F7 missionCommands.addCommandForGroup( gid, "Trapsheet On/Off", _helpPath, self._TrapsheetOnOff, self, _unitName ) -- F8 ------------------------------------- -- F10/Airboss//F2 Kneeboard ------------------------------------- local _kneeboardPath = missionCommands.addSubMenuForGroup( gid, "Kneeboard", _rootPath ) -- F10/Airboss//F2 Kneeboard/F1 Results local _resultsPath = missionCommands.addSubMenuForGroup( gid, "Results", _kneeboardPath ) -- F10/Airboss//F2 Kneeboard/F1 Results/ missionCommands.addCommandForGroup( gid, "Greenie Board", _resultsPath, self._DisplayScoreBoard, self, _unitName ) -- F1 missionCommands.addCommandForGroup( gid, "My LSO Grades", _resultsPath, self._DisplayPlayerGrades, self, _unitName ) -- F2 missionCommands.addCommandForGroup( gid, "Last Debrief", _resultsPath, self._DisplayDebriefing, self, _unitName ) -- F3 -- F10/Airboss//F2 Kneeboard/F2 Skipper/ if self.skipperMenu then local _skipperPath = missionCommands.addSubMenuForGroup( gid, "Skipper", _kneeboardPath ) local _menusetspeed = missionCommands.addSubMenuForGroup( gid, "Set Speed", _skipperPath ) missionCommands.addCommandForGroup( gid, "10 knots", _menusetspeed, self._SkipperRecoverySpeed, self, _unitName, 10 ) missionCommands.addCommandForGroup( gid, "15 knots", _menusetspeed, self._SkipperRecoverySpeed, self, _unitName, 15 ) missionCommands.addCommandForGroup( gid, "20 knots", _menusetspeed, self._SkipperRecoverySpeed, self, _unitName, 20 ) missionCommands.addCommandForGroup( gid, "25 knots", _menusetspeed, self._SkipperRecoverySpeed, self, _unitName, 25 ) missionCommands.addCommandForGroup( gid, "30 knots", _menusetspeed, self._SkipperRecoverySpeed, self, _unitName, 30 ) local _menusetrtime = missionCommands.addSubMenuForGroup( gid, "Set Time", _skipperPath ) missionCommands.addCommandForGroup( gid, "15 min", _menusetrtime, self._SkipperRecoveryTime, self, _unitName, 15 ) missionCommands.addCommandForGroup( gid, "30 min", _menusetrtime, self._SkipperRecoveryTime, self, _unitName, 30 ) missionCommands.addCommandForGroup( gid, "45 min", _menusetrtime, self._SkipperRecoveryTime, self, _unitName, 45 ) missionCommands.addCommandForGroup( gid, "60 min", _menusetrtime, self._SkipperRecoveryTime, self, _unitName, 60 ) missionCommands.addCommandForGroup( gid, "90 min", _menusetrtime, self._SkipperRecoveryTime, self, _unitName, 90 ) local _menusetrtime = missionCommands.addSubMenuForGroup( gid, "Set Marshal Radial", _skipperPath ) missionCommands.addCommandForGroup( gid, "+30°", _menusetrtime, self._SkipperRecoveryOffset, self, _unitName, 30 ) missionCommands.addCommandForGroup( gid, "+15°", _menusetrtime, self._SkipperRecoveryOffset, self, _unitName, 15 ) missionCommands.addCommandForGroup( gid, "0°", _menusetrtime, self._SkipperRecoveryOffset, self, _unitName, 0 ) missionCommands.addCommandForGroup( gid, "-15°", _menusetrtime, self._SkipperRecoveryOffset, self, _unitName, -15 ) missionCommands.addCommandForGroup( gid, "-30°", _menusetrtime, self._SkipperRecoveryOffset, self, _unitName, -30 ) missionCommands.addCommandForGroup( gid, "U-turn On/Off", _skipperPath, self._SkipperRecoveryUturn, self, _unitName ) missionCommands.addCommandForGroup( gid, "Start CASE I", _skipperPath, self._SkipperStartRecovery, self, _unitName, 1 ) missionCommands.addCommandForGroup( gid, "Start CASE II", _skipperPath, self._SkipperStartRecovery, self, _unitName, 2 ) missionCommands.addCommandForGroup( gid, "Start CASE III", _skipperPath, self._SkipperStartRecovery, self, _unitName, 3 ) missionCommands.addCommandForGroup( gid, "Stop Recovery", _skipperPath, self._SkipperStopRecovery, self, _unitName ) end -- F10/Airboss// ------------------------- missionCommands.addCommandForGroup( gid, "Request Marshal", _rootPath, self._RequestMarshal, self, _unitName ) -- F3 missionCommands.addCommandForGroup( gid, "Request Commence", _rootPath, self._RequestCommence, self, _unitName ) -- F4 missionCommands.addCommandForGroup( gid, "Request Refueling", _rootPath, self._RequestRefueling, self, _unitName ) -- F5 missionCommands.addCommandForGroup( gid, "Spinning", _rootPath, self._RequestSpinning, self, _unitName ) -- F6 missionCommands.addCommandForGroup( gid, "Emergency Landing", _rootPath, self._RequestEmergency, self, _unitName ) -- F7 missionCommands.addCommandForGroup( gid, "[Reset My Status]", _rootPath, self._ResetPlayerStatus, self, _unitName ) -- F8 end else self:E( self.lid .. string.format( "ERROR: Could not find group or group ID in AddF10Menu() function. Unit name: %s.", _unitName ) ) end else self:E( self.lid .. string.format( "ERROR: Player unit does not exist in AddF10Menu() function. Unit name: %s.", _unitName ) ) end end ----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- -- SKIPPER MENU ----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- --- Reset player status. Player is removed from all queues and its status is set to undefined. -- @param #AIRBOSS self -- @param #string _unitName Name fo the player unit. -- @param #number case Recovery case. function AIRBOSS:_SkipperStartRecovery( _unitName, case ) -- Get player unit and name. local _unit, _playername = self:_GetPlayerUnitAndName( _unitName ) -- Check if we have a unit which is a player. if _unit and _playername then local playerData = self.players[_playername] -- #AIRBOSS.PlayerData if playerData then -- Inform player. local text = string.format( "affirm, Case %d recovery will start in 5 min for %d min. Wind on deck %d knots. U-turn=%s.", case, self.skipperTime, self.skipperSpeed, tostring( self.skipperUturn ) ) if case > 1 then text = text .. string.format( " Marshal radial %d°.", self.skipperOffset ) end if self:IsRecovering() then text = "negative, carrier is already recovering." self:MessageToPlayer( playerData, text, "AIRBOSS" ) return end self:MessageToPlayer( playerData, text, "AIRBOSS" ) -- Recovery staring in 5 min for 30 min. local t0 = timer.getAbsTime() + 5 * 60 local t9 = t0 + self.skipperTime * 60 local C0 = UTILS.SecondsToClock( t0 ) local C9 = UTILS.SecondsToClock( t9 ) -- Carrier will turn into the wind. Wind on deck 25 knots. U-turn on. self:AddRecoveryWindow( C0, C9, case, self.skipperOffset, true, self.skipperSpeed, self.skipperUturn ) end end end --- Skipper Stop recovery function. -- @param #AIRBOSS self -- @param #string _unitName Name fo the player unit. function AIRBOSS:_SkipperStopRecovery( _unitName ) -- Get player unit and name. local _unit, _playername = self:_GetPlayerUnitAndName( _unitName ) -- Check if we have a unit which is a player. if _unit and _playername then local playerData = self.players[_playername] -- #AIRBOSS.PlayerData if playerData then -- Inform player. local text = "roger, stopping recovery right away." if not self:IsRecovering() then text = "negative, carrier is currently not recovering." self:MessageToPlayer( playerData, text, "AIRBOSS" ) return end self:MessageToPlayer( playerData, text, "AIRBOSS" ) self:RecoveryStop() end end end --- Skipper set recovery offset angle. -- @param #AIRBOSS self -- @param #string _unitName Name fo the player unit. -- @param #number offset Recovery holding offset angle in degrees for Case II/III. function AIRBOSS:_SkipperRecoveryOffset( _unitName, offset ) -- Get player unit and name. local _unit, _playername = self:_GetPlayerUnitAndName( _unitName ) -- Check if we have a unit which is a player. if _unit and _playername then local playerData = self.players[_playername] -- #AIRBOSS.PlayerData if playerData then -- Inform player. local text = string.format( "roger, relative CASE II/III Marshal radial set to %d°.", offset ) self:MessageToPlayer( playerData, text, "AIRBOSS" ) self.skipperOffset = offset end end end --- Skipper set recovery time. -- @param #AIRBOSS self -- @param #string _unitName Name fo the player unit. -- @param #number time Recovery time in minutes. function AIRBOSS:_SkipperRecoveryTime( _unitName, time ) -- Get player unit and name. local _unit, _playername = self:_GetPlayerUnitAndName( _unitName ) -- Check if we have a unit which is a player. if _unit and _playername then local playerData = self.players[_playername] -- #AIRBOSS.PlayerData if playerData then -- Inform player. local text = string.format( "roger, manual recovery time set to %d min.", time ) self:MessageToPlayer( playerData, text, "AIRBOSS" ) self.skipperTime = time end end end --- Skipper set recovery speed. -- @param #AIRBOSS self -- @param #string _unitName Name fo the player unit. -- @param #number speed Recovery speed in knots. function AIRBOSS:_SkipperRecoverySpeed( _unitName, speed ) -- Get player unit and name. local _unit, _playername = self:_GetPlayerUnitAndName( _unitName ) -- Check if we have a unit which is a player. if _unit and _playername then local playerData = self.players[_playername] -- #AIRBOSS.PlayerData if playerData then -- Inform player. local text = string.format( "roger, wind on deck set to %d knots.", speed ) self:MessageToPlayer( playerData, text, "AIRBOSS" ) self.skipperSpeed = speed end end end --- Skipper set recovery speed. -- @param #AIRBOSS self -- @param #string _unitName Name fo the player unit. function AIRBOSS:_SkipperRecoveryUturn( _unitName ) -- Get player unit and name. local _unit, _playername = self:_GetPlayerUnitAndName( _unitName ) -- Check if we have a unit which is a player. if _unit and _playername then local playerData = self.players[_playername] -- #AIRBOSS.PlayerData if playerData then self.skipperUturn = not self.skipperUturn -- Inform player. local text = string.format( "roger, U-turn is now %s.", tostring( self.skipperUturn ) ) self:MessageToPlayer( playerData, text, "AIRBOSS" ) end end end ----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- -- ROOT MENU ----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- --- Reset player status. Player is removed from all queues and its status is set to undefined. -- @param #AIRBOSS self -- @param #string _unitName Name fo the player unit. function AIRBOSS:_ResetPlayerStatus( _unitName ) self:F( _unitName ) -- Get player unit and name. local _unit, _playername = self:_GetPlayerUnitAndName( _unitName ) -- Check if we have a unit which is a player. if _unit and _playername then local playerData = self.players[_playername] -- #AIRBOSS.PlayerData if playerData then -- Inform player. local text = "roger, status reset executed! You have been removed from all queues." self:MessageToPlayer( playerData, text, "AIRBOSS" ) -- Remove flight from queues. Collapse marshal stack if necessary. -- Section members are removed from the Spinning queue. If flight is member, he is removed from the section. self:_RemoveFlight( playerData ) -- Stop pending debrief scheduler. if playerData.debriefschedulerID and self.Scheduler then self.Scheduler:Stop( playerData.debriefschedulerID ) end -- Initialize player data. self:_InitPlayer( playerData ) end end end --- Request marshal. -- @param #AIRBOSS self -- @param #string _unitName Name fo the player unit. function AIRBOSS:_RequestMarshal( _unitName ) self:F( _unitName ) -- Get player unit and name. local _unit, _playername = self:_GetPlayerUnitAndName( _unitName ) -- Check if we have a unit which is a player. if _unit and _playername then local playerData = self.players[_playername] -- #AIRBOSS.PlayerData if playerData then -- Voice over of inbound call (regardless of airboss rejecting it or not) if self.xtVoiceOvers then self:_MarshallInboundCall(_unit, playerData.onboard) end -- Check if player is in CCA local inCCA = playerData.unit:IsInZone( self.zoneCCA ) if inCCA then if self:_InQueue( self.Qmarshal, playerData.group ) then -- Flight group is already in marhal queue. local text = string.format( "negative, you are already in the Marshal queue. New marshal request denied!" ) self:MessageToPlayer( playerData, text, "MARSHAL" ) elseif self:_InQueue( self.Qpattern, playerData.group ) then -- Flight group is already in pattern queue. local text = string.format( "negative, you are already in the Pattern queue. Marshal request denied!" ) self:MessageToPlayer( playerData, text, "MARSHAL" ) elseif self:_InQueue( self.Qwaiting, playerData.group ) then -- Flight group is already in pattern queue. local text = string.format( "negative, you are in the Waiting queue with %d flights ahead of you. Marshal request denied!", #self.Qwaiting ) self:MessageToPlayer( playerData, text, "MARSHAL" ) elseif not _unit:InAir() then -- Flight group is already in pattern queue. local text = string.format( "negative, you are not airborne. Marshal request denied!" ) self:MessageToPlayer( playerData, text, "MARSHAL" ) elseif playerData.name ~= playerData.seclead then -- Flight group is already in pattern queue. local text = string.format( "negative, your section lead %s needs to request Marshal.", playerData.seclead ) self:MessageToPlayer( playerData, text, "MARSHAL" ) else -- Get next free Marshal stack. local freestack = self:_GetFreeStack( playerData.ai ) -- Check if stack is available. For Case I the number is limited. if freestack then -- Add flight to marshal stack. self:_MarshalPlayer( playerData, freestack ) else -- Add flight to waiting queue. self:_WaitPlayer( playerData ) end end else -- Flight group is not in CCA yet. local text = string.format( "negative, you are not inside CCA. Marshal request denied!" ) self:MessageToPlayer( playerData, text, "MARSHAL" ) end end end end --- Request emergency landing. -- @param #AIRBOSS self -- @param #string _unitName Name fo the player unit. function AIRBOSS:_RequestEmergency( _unitName ) self:F( _unitName ) -- Get player unit and name. local _unit, _playername = self:_GetPlayerUnitAndName( _unitName ) -- Check if we have a unit which is a player. if _unit and _playername then local playerData = self.players[_playername] -- #AIRBOSS.PlayerData if playerData then local text = "" if not self.emergency then -- Mission designer did not allow emergency landing. text = "negative, no emergency landings on my carrier. We are currently busy. See how you get along!" elseif not _unit:InAir() then -- Carrier zone. local zone = self:_GetZoneCarrierBox() -- Check if player is on the carrier. if playerData.unit:IsInZone( zone ) then -- Bolter pattern. text = "roger, you are now technically in the bolter pattern. Your next step after takeoff is abeam!" -- Get flight lead. local lead = self:_GetFlightLead( playerData ) -- Set set for lead. self:_SetPlayerStep( lead, AIRBOSS.PatternStep.BOLTER ) -- Also set bolter pattern for all members. for _, sec in pairs( lead.section ) do local sectionmember = sec -- #AIRBOSS.PlayerData self:_SetPlayerStep( sectionmember, AIRBOSS.PatternStep.BOLTER ) end -- Remove flight from waiting queue just in case. self:_RemoveFlightFromQueue( self.Qwaiting, lead ) if self:_InQueue( self.Qmarshal, lead.group ) then -- Remove flight from Marshal queue and add to pattern. self:_RemoveFlightFromMarshalQueue( lead ) else -- Add flight to pattern if he was not. if not self:_InQueue( self.Qpattern, lead.group ) then self:_AddFlightToPatternQueue( lead ) end end else -- Flight group is not in air. text = string.format( "negative, you are not airborne. Request denied!" ) end else -- Cleared. text = "affirmative, you can bypass the pattern and are cleared for final approach!" -- Now, if player is in the marshal or waiting queue he will be removed. But the new leader should stay in or not. local lead = self:_GetFlightLead( playerData ) -- Set set for lead. self:_SetPlayerStep( lead, AIRBOSS.PatternStep.EMERGENCY ) -- Also set emergency landing for all members. for _, sec in pairs( lead.section ) do local sectionmember = sec -- #AIRBOSS.PlayerData self:_SetPlayerStep( sectionmember, AIRBOSS.PatternStep.EMERGENCY ) -- Remove flight from spinning queue just in case (everone can spin on his own). self:_RemoveFlightFromQueue( self.Qspinning, sectionmember ) end -- Remove flight from waiting queue just in case. self:_RemoveFlightFromQueue( self.Qwaiting, lead ) if self:_InQueue( self.Qmarshal, lead.group ) then -- Remove flight from Marshal queue and add to pattern. self:_RemoveFlightFromMarshalQueue( lead ) else -- Add flight to pattern if he was not. if not self:_InQueue( self.Qpattern, lead.group ) then self:_AddFlightToPatternQueue( lead ) end end end -- Send message. self:MessageToPlayer( playerData, text, "AIRBOSS" ) end end end --- Request spinning. -- @param #AIRBOSS self -- @param #string _unitName Name fo the player unit. function AIRBOSS:_RequestSpinning( _unitName ) self:F( _unitName ) -- Get player unit and name. local _unit, _playername = self:_GetPlayerUnitAndName( _unitName ) -- Check if we have a unit which is a player. if _unit and _playername then local playerData = self.players[_playername] -- #AIRBOSS.PlayerData if playerData then local text = "" if not self:_InQueue( self.Qpattern, playerData.group ) then -- Player not in pattern queue. text = "negative, you have to be in the pattern to spin it!" elseif playerData.step == AIRBOSS.PatternStep.SPINNING then -- Player is already spinning. text = "negative, you are already spinning." -- Check if player is in the right step. elseif not (playerData.step == AIRBOSS.PatternStep.BREAKENTRY or playerData.step == AIRBOSS.PatternStep.EARLYBREAK or playerData.step == AIRBOSS.PatternStep.LATEBREAK) then -- Player is not in the right step. text = "negative, you have to be in the right step to spin it!" else -- Set player step. self:_SetPlayerStep( playerData, AIRBOSS.PatternStep.SPINNING ) -- Add player to spinning queue. table.insert( self.Qspinning, playerData ) -- 405, Spin it! Click. local call = self:_NewRadioCall( self.LSOCall.SPINIT, "AIRBOSS", "Spin it!", self.Tmessage, playerData.onboard ) self:RadioTransmission( self.LSORadio, call, nil, nil, nil, true ) -- Some advice. if playerData.difficulty == AIRBOSS.Difficulty.EASY then local text = "Climb to 1200 feet and proceed to the initial again." self:MessageToPlayer( playerData, text, "AIRBOSS", "" ) end return end -- Send message. self:MessageToPlayer( playerData, text, "AIRBOSS" ) end end end --- Request to commence landing approach. -- @param #AIRBOSS self -- @param #string _unitName Name fo the player unit. function AIRBOSS:_RequestCommence( _unitName ) self:F( _unitName ) -- Get player unit and name. local _unit, _playername = self:_GetPlayerUnitAndName( _unitName ) -- Check if we have a unit which is a player. if _unit and _playername then local playerData = self.players[_playername] -- #AIRBOSS.PlayerData if playerData then -- Voice over of Commencing call (regardless of Airboss will rejected or not) if self.xtVoiceOvers then self:_CommencingCall(_unit, playerData.onboard) end -- Check if unit is in CCA. local text = "" local cleared = false if _unit:IsInZone( self.zoneCCA ) then -- Get stack value. local stack = playerData.flag -- Number of airborne aircraft currently in pattern. local _, npattern = self:_GetQueueInfo( self.Qpattern ) -- TODO: Check distance to initial or platform. Only allow commence if < max distance. Otherwise say bearing. if self:_InQueue( self.Qpattern, playerData.group ) then -- Flight group is already in pattern queue. text = string.format( "negative, %s, you are already in the Pattern queue.", playerData.name ) elseif not _unit:InAir() then -- Flight group is already in pattern queue. text = string.format( "negative, %s, you are not airborne.", playerData.name ) elseif playerData.seclead ~= playerData.name then -- Flight group is already in pattern queue. text = string.format( "negative, %s, your section leader %s has to request commence!", playerData.name, playerData.seclead ) elseif stack > 1 then -- We are in a higher stack. text = string.format( "negative, %s, it's not your turn yet! You are in stack no. %s.", playerData.name, stack ) elseif npattern >= self.Nmaxpattern then -- Patern is full! text = string.format( "negative ghostrider, pattern is full!\nThere are %d aircraft currently in the pattern.", npattern ) elseif self:IsRecovering() == false and not self.airbossnice then -- Carrier is not recovering right now. if self.recoverywindow then local clock = UTILS.SecondsToClock( self.recoverywindow.START ) text = string.format( "negative, carrier is currently not recovery. Next window will open at %s.", clock ) else text = string.format( "negative, carrier is not recovering. No future windows planned." ) end elseif not self:_InQueue( self.Qmarshal, playerData.group ) and not self.airbossnice then text = "negative, you have to request Marshal before you can commence." else ----------------------- -- Positive Response -- ----------------------- text = text .. "roger." -- Carrier is not recovering but Airboss has a good day. if not self:IsRecovering() then text = text .. " Carrier is not recovering currently! However, you are cleared anyway as I have a nice day." end -- If player is not in the Marshal queue set player case to current case. if not self:_InQueue( self.Qmarshal, playerData.group ) then -- Set current case. playerData.case = self.case -- Hint about TACAN bearing. if self.TACANon and playerData.difficulty ~= AIRBOSS.Difficulty.HARD then -- Get inverse magnetic radial potential offset. local radial = self:GetRadial( playerData.case, true, true, true ) if playerData.case == 1 then -- For case 1 we want the BRC but above routine return FB. radial = self:GetBRC() end text = text .. string.format( "\nSelect TACAN %03d°, Channel %d%s (%s).\n", radial, self.TACANchannel, self.TACANmode, self.TACANmorse ) end -- TODO: Inform section members. -- Set case of section members as well. Not sure if necessary any more since it is set as soon as the recovery case is changed. for _, flight in pairs( playerData.section ) do flight.case = playerData.case end -- Add player to pattern queue. Usually this is done when the stack is collapsed but this player is not in the Marshal queue. self:_AddFlightToPatternQueue( playerData ) end -- Clear player for commence. cleared = true end else -- This flight is not yet registered! text = string.format( "negative, %s, you are not inside the CCA!", playerData.name ) end -- Debug self:T( self.lid .. text ) -- Send message. self:MessageToPlayer( playerData, text, "MARSHAL" ) -- Check if player was cleard. Need to do this after the message above is displayed. if cleared then -- Call commence routine. No zone check. NOTE: Commencing will set step for all section members as well. self:_Commencing( playerData, false ) end end end end --- Player requests refueling. -- @param #AIRBOSS self -- @param #string _unitName Name of the player unit. function AIRBOSS:_RequestRefueling( _unitName ) -- Get player unit and name. local _unit, _playername = self:_GetPlayerUnitAndName( _unitName ) -- Check if we have a unit which is a player. if _unit and _playername then local playerData = self.players[_playername] -- #AIRBOSS.PlayerData if playerData then -- Check if there is a recovery tanker defined. local text if self.tanker then -- Check if player is in CCA. if _unit:IsInZone( self.zoneCCA ) then -- Check if tanker is running or refueling or returning. if self.tanker:IsRunning() or self.tanker:IsRefueling() then -- Get alt of tanker in angels. -- local angels=UTILS.Round(UTILS.MetersToFeet(self.tanker.altitude)/1000, 0) local angels = self:_GetAngels( self.tanker.altitude ) -- Tanker is up and running. text = string.format( "affirmative, proceed to tanker at angels %d.", angels ) -- State TACAN channel of tanker if defined. if self.tanker.TACANon then text = text .. string.format( "\nTanker TACAN channel %d%s (%s).", self.tanker.TACANchannel, self.tanker.TACANmode, self.tanker.TACANmorse ) text = text .. string.format( "\nRadio frequency %.3f MHz AM.", self.tanker.RadioFreq ) end -- Tanker is currently refueling. Inform player. if self.tanker:IsRefueling() then text = text .. "\nTanker is currently refueling. You might have to queue up." end -- Collapse marshal stack if player is in queue. self:_RemoveFlightFromMarshalQueue( playerData, true ) -- Set step to refueling. self:_SetPlayerStep( playerData, AIRBOSS.PatternStep.REFUELING ) -- Inform section and set step. for _, sec in pairs( playerData.section ) do local sectext = "follow your section leader to the tanker." self:MessageToPlayer( sec, sectext, "MARSHAL" ) self:_SetPlayerStep( sec, AIRBOSS.PatternStep.REFUELING ) end elseif self.tanker:IsReturning() then -- Tanker is RTB. text = "negative, tanker is RTB. Request denied!\nWait for the tanker to be back on station if you can." end else text = "negative, you are not inside the CCA yet." end else text = "negative, no refueling tanker available." end -- Send message. self:MessageToPlayer( playerData, text, "MARSHAL" ) end end end --- Remove a member from the player's section. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player -- @param #AIRBOSS.PlayerData sectionmember The section member to be removed. -- @return #boolean If true, flight was a section member and could be removed. False otherwise. function AIRBOSS:_RemoveSectionMember( playerData, sectionmember ) -- Loop over all flights in player's section for i, _flight in pairs( playerData.section ) do local flight = _flight -- #AIRBOSS.PlayerData if flight.name == sectionmember.name then table.remove( playerData.section, i ) return true end end return false end --- Set all flights within 100 meters to be part of my section. -- @param #AIRBOSS self -- @param #string _unitName Name of the player unit. function AIRBOSS:_SetSection( _unitName ) -- Get player unit and name. local _unit, _playername = self:_GetPlayerUnitAndName( _unitName ) -- Check if we have a unit which is a player. if _unit and _playername then local playerData = self.players[_playername] -- #AIRBOSS.PlayerData if playerData then -- Coordinate of flight lead. local mycoord = _unit:GetCoordinate() -- Max distance up to which section members are allowed. local dmax = 100 -- Check if player is in Marshal or pattern queue already. local text if self.NmaxSection == 0 then text = string.format( "negative, setting sections is disabled in this mission. You stay alone." ) elseif self:_InQueue( self.Qmarshal, playerData.group ) then text = string.format( "negative, you are already in the Marshal queue. Setting section not possible any more!" ) elseif self:_InQueue( self.Qpattern, playerData.group ) then text = string.format( "negative, you are already in the Pattern queue. Setting section not possible any more!" ) else -- Check if player is member of another section already. If so, remove him from his current section. if playerData.seclead ~= playerData.name then local lead = self.players[playerData.seclead] -- #AIRBOSS.PlayerData if lead then -- Remove player from his old section lead. local removed = self:_RemoveSectionMember( lead, playerData ) if removed then self:MessageToPlayer( lead, string.format( "Flight %s has been removed from your section.", playerData.name ), "AIRBOSS", "", 5 ) self:MessageToPlayer( playerData, string.format( "You have been removed from %s's section.", lead.name ), "AIRBOSS", "", 5 ) end end end -- Potential section members. local section = {} -- Loop over all registered flights. for _, _flight in pairs( self.flights ) do local flight = _flight -- #AIRBOSS.FlightGroup -- Only human flight groups excluding myself. Also only flights that dont have a section itself (would get messy) or are part of another section (no double membership). if flight.ai == false and flight.groupname ~= playerData.groupname and #flight.section == 0 and flight.seclead == flight.name then -- Distance (3D) to other flight group. local distance = flight.group:GetCoordinate():Get3DDistance( mycoord ) -- Check distance. if distance < dmax then self:T( self.lid .. string.format( "Found potential section member %s for lead %s at distance %.1f m.", flight.name, playerData.name, distance ) ) table.insert( section, { flight = flight, distance = distance } ) end end end -- Sort potential section members wrt to distance to lead. table.sort( section, function( a, b ) return a.distance < b.distance end ) -- Make player section lead if he was not before. playerData.seclead = playerData.name -- Loop over all flights in player's current section and inform those members that will be removed because they are not in range any more. for _, _flight in pairs( playerData.section ) do local flight = _flight -- #AIRBOSS.PlayerData -- Loop over all potential new members and check if they were already part of the player's section. local gotit = false for _, _new in pairs( section ) do local newflight = _new.flight -- #AIRBOSS.PlayerData if newflight.name == flight.name then gotit = true -- This is an old one that stays. end end -- Flight is not a member any more ==> remove it. if not gotit then self:MessageToPlayer( flight, string.format( "you were removed from %s's section and are on your own now.", playerData.name ), "AIRBOSS", "", 5 ) flight.seclead = flight.name self:_RemoveSectionMember( playerData, flight ) end end -- Remove all flights that are currently in the player's section already from scanned potential new section members. for i, _new in pairs( section ) do local newflight = _new.flight -- #AIRBOSS.PlayerData for _, _flight in pairs( playerData.section ) do local currentflight = _flight -- #AIRBOSS.PlayerData if newflight.name == currentflight.name then table.remove( section, i ) end end end -- Init section table. Should not be necessary as all members are removed anyhow above. -- playerData.section={} -- Output text. text = string.format( "Registered flight section:" ) text = text .. string.format( "\n- %s (lead)", playerData.seclead ) -- Old members that stay (if any). for _, _flight in pairs( playerData.section ) do local flight = _flight -- #AIRBOSS.PlayerData text = text .. string.format( "\n- %s", flight.name ) end -- New members (if any). for i = 1, math.min( self.NmaxSection - #playerData.section, #section ) do local flight = section[i].flight -- #AIRBOSS.PlayerData -- New flight members. text = text .. string.format( "\n- %s", flight.name ) -- Set section lead of player flight. flight.seclead = playerData.name -- Set case of f flight.case = playerData.case -- Inform player that he is now part of a section. self:MessageToPlayer( flight, string.format( "your section lead is now %s.", playerData.name ), "AIRBOSS" ) -- Add flight to section table. table.insert( playerData.section, flight ) end -- Section is empty. if #playerData.section == 0 then text = text .. string.format( "\n- No other human flights found within radius of %.1f meters!", dmax ) end end -- Message to section lead. self:MessageToPlayer( playerData, text, "MARSHAL" ) end end end ----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- -- RESULTS MENU ----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- --- Display top 10 player scores. -- @param #AIRBOSS self -- @param #string _unitName Name fo the player unit. function AIRBOSS:_DisplayScoreBoard( _unitName ) self:F( _unitName ) -- Get player unit and name. local _unit, _playername = self:_GetPlayerUnitAndName( _unitName ) -- Check if we have a unit which is a player. if _unit and _playername then -- Results table. local _playerResults = {} -- Calculate average points for all players. for playerName, playerGrades in pairs( self.playerscores ) do if playerGrades then -- Loop over all grades local Paverage = 0 local n = 0 for _, _grade in pairs( playerGrades ) do local grade = _grade -- #AIRBOSS.LSOgrade -- Add up only final scores for the average. if grade.finalscore then -- grade.points>=0 then Paverage = Paverage + grade.finalscore n = n + 1 else -- Case when the player just leaves after an unfinished pass, e.g bolter, without landing. -- But this should now be solved by deleteing all unfinished results. end end -- We dont want to devide by zero. if n > 0 then _playerResults[playerName] = Paverage / n end end end -- Message text. local text = string.format( "Greenie Board (top ten):" ) local i = 1 for _playerName, _points in UTILS.spairs( _playerResults, function( t, a, b ) return t[b] < t[a] end ) do -- Text. text = text .. string.format( "\n[%d] %s %.1f||", i, _playerName, _points ) -- All player grades. local playerGrades = self.playerscores[_playerName] -- Add grades of passes. We use the actual grade of each pass here and not the average after player has landed. for _, _grade in pairs( playerGrades ) do local grade = _grade -- #AIRBOSS.LSOgrade if grade.finalscore then text = text .. string.format( "%.1f|", grade.points ) elseif grade.points >= 0 then -- Only points >=0 as foul deck gives -1. text = text .. string.format( "(%.1f)", grade.points ) end end -- Display only the top ten. i = i + 1 if i > 10 then break end end -- If no results yet. if i == 1 then text = text .. "\nNo results yet." end -- Send message. local playerData = self.players[_playername] -- #AIRBOSS.PlayerData if playerData.client then MESSAGE:New( text, 30, nil, true ):ToClient( playerData.client ) end end end --- Display top 10 player scores. -- @param #AIRBOSS self -- @param #string _unitName Name fo the player unit. function AIRBOSS:_DisplayPlayerGrades( _unitName ) self:F( _unitName ) -- Get player unit and name. local _unit, _playername = self:_GetPlayerUnitAndName( _unitName ) -- Check if we have a unit which is a player. if _unit and _playername then local playerData = self.players[_playername] -- #AIRBOSS.PlayerData if playerData then -- Grades of player: local text = string.format( "Your last 10 grades, %s:", _playername ) -- All player grades. local playerGrades = self.playerscores[_playername] or {} local p = 0 -- Average points. local n = 0 -- Number of final passes. local m = 0 -- Number of total passes. -- for i,_grade in pairs(playerGrades) do for i = #playerGrades, 1, -1 do -- local grade=_grade --#AIRBOSS.LSOgrade local grade = playerGrades[i] -- #AIRBOSS.LSOgrade -- Check if points >=0. For foul deck WO we give -1 and pass is not counted. if grade.points >= 0 then -- Show final points or points of pass. local points = grade.finalscore or grade.points -- Display max 10 results. if m < 10 then text = text .. string.format( "\n[%d] %s %.1f PT - %s", i, grade.grade, points, grade.details ) -- Wire trapped if any. if grade.wire and grade.wire <= 4 then text = text .. string.format( " %d-wire", grade.wire ) end -- Time in the groove if any. if grade.Tgroove and grade.Tgroove <= 360 then text = text .. string.format( " Tgroove=%.1f s", grade.Tgroove ) end end -- Add up final points. if grade.finalscore then p = p + grade.finalscore n = n + 1 end -- Total passes m = m + 1 end end if n > 0 then text = text .. string.format( "\nAverage points = %.1f", p / n ) else text = text .. string.format( "\nNo data available." ) end -- Send message. if playerData.client then MESSAGE:New( text, 30, nil, true ):ToClient( playerData.client ) end end end end --- Display last debriefing. -- @param #AIRBOSS self -- @param #string _unitName Name fo the player unit. function AIRBOSS:_DisplayDebriefing( _unitName ) self:F( _unitName ) -- Get player unit and name. local _unit, _playername = self:_GetPlayerUnitAndName( _unitName ) -- Check if we have a unit which is a player. if _unit and _playername then local playerData = self.players[_playername] -- #AIRBOSS.PlayerData if playerData then -- Debriefing text. local text = string.format( "Debriefing:" ) -- Check if data is present. if #playerData.lastdebrief > 0 then text = text .. string.format( "\n================================\n" ) for _, _data in pairs( playerData.lastdebrief ) do local step = _data.step local comment = _data.hint text = text .. string.format( "* %s:", step ) text = text .. string.format( "%s\n", comment ) end else text = text .. " Nothing to show yet." end -- Send debrief message to player self:MessageToPlayer( playerData, text, nil, "", 30, true ) end end end ----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- -- KNEEBOARD MENU ----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- --- Display marshal or pattern queue. -- @param #AIRBOSS self -- @param #string _unitname Name of the player unit. -- @param #string qname Name of the queue. function AIRBOSS:_DisplayQueue( _unitname, qname ) -- Get player unit and player name. local unit, playername = self:_GetPlayerUnitAndName( _unitname ) -- Check if we have a player. if unit and playername then -- Player data. local playerData = self.players[playername] -- #AIRBOSS.PlayerData if playerData then -- Queue to display. local queue = nil if qname == "Marshal" then queue = self.Qmarshal elseif qname == "Pattern" then queue = self.Qpattern elseif qname == "Waiting" then queue = self.Qwaiting end -- Number of group and units in queue local Nqueue, nqueue = self:_GetQueueInfo( queue, playerData.case ) local text = string.format( "%s Queue:", qname ) if #queue == 0 then text = text .. " empty" else local N = 0 if qname == "Marshal" then for i, _flight in pairs( queue ) do local flight = _flight -- #AIRBOSS.FlightGroup local charlie = self:_GetCharlieTime( flight ) local Charlie = UTILS.SecondsToClock( charlie ) local stack = flight.flag local angels = self:_GetAngels( self:_GetMarshalAltitude( stack, flight.case ) ) local _, nunit, nsec = self:_GetFlightUnits( flight, true ) local nick = self:_GetACNickname( flight.actype ) N = N + nunit text = text .. string.format( "\n[Stack %d] %s (%s*%d+%d): Case %d, Angels %d, Charlie %s", stack, flight.onboard, nick, nunit, nsec, flight.case, angels, tostring( Charlie ) ) end elseif qname == "Pattern" or qname == "Waiting" then for i, _flight in pairs( queue ) do local flight = _flight -- #AIRBOSS.FlightGroup local _, nunit, nsec = self:_GetFlightUnits( flight, true ) local nick = self:_GetACNickname( flight.actype ) local ptime = UTILS.SecondsToClock( timer.getAbsTime() - flight.time ) N = N + nunit text = text .. string.format( "\n[%d] %s (%s*%d+%d): Case %d, T=%s", i, flight.onboard, nick, nunit, nsec, flight.case, ptime ) end end text = text .. string.format( "\nTotal AC: %d (airborne %d)", N, nqueue ) end -- Send message. self:MessageToPlayer( playerData, text, nil, "", nil, true ) end end end --- Report information about carrier. -- @param #AIRBOSS self -- @param #string _unitname Name of the player unit. function AIRBOSS:_DisplayCarrierInfo( _unitname ) self:F2( _unitname ) -- Get player unit and player name. local unit, playername = self:_GetPlayerUnitAndName( _unitname ) -- Check if we have a player. if unit and playername then -- Player data. local playerData = self.players[playername] -- #AIRBOSS.PlayerData if playerData then -- Current coordinates. local coord = self:GetCoordinate() -- Carrier speed and heading. local carrierheading = self.carrier:GetHeading() local carrierspeed = UTILS.MpsToKnots( self.carrier:GetVelocityMPS() ) -- TACAN/ICLS. local tacan = "unknown" local icls = "unknown" if self.TACANon and self.TACANchannel ~= nil then tacan = string.format( "%d%s (%s)", self.TACANchannel, self.TACANmode, self.TACANmorse ) end if self.ICLSon and self.ICLSchannel ~= nil then icls = string.format( "%d (%s)", self.ICLSchannel, self.ICLSmorse ) end -- Wind on flight deck local wind = UTILS.MpsToKnots( select( 1, self:GetWindOnDeck() ) ) -- Get groups, units in queues. local Nmarshal, nmarshal = self:_GetQueueInfo( self.Qmarshal, playerData.case ) local Npattern, npattern = self:_GetQueueInfo( self.Qpattern ) local Nspinning, nspinning = self:_GetQueueInfo( self.Qspinning ) local Nwaiting, nwaiting = self:_GetQueueInfo( self.Qwaiting ) local Ntotal, ntotal = self:_GetQueueInfo( self.flights ) -- Current abs time. local Tabs = timer.getAbsTime() -- Get recovery times of carrier. local recoverytext = "Recovery time windows (max 5):" if #self.recoverytimes == 0 then recoverytext = recoverytext .. " none." else -- Loop over recovery windows. local rw = 0 for _, _recovery in pairs( self.recoverytimes ) do local recovery = _recovery -- #AIRBOSS.Recovery -- Only include current and future recovery windows. if Tabs < recovery.STOP then -- Output text. recoverytext = recoverytext .. string.format( "\n* %s - %s: Case %d (%d°)", UTILS.SecondsToClock( recovery.START ), UTILS.SecondsToClock( recovery.STOP ), recovery.CASE, recovery.OFFSET ) if recovery.WIND then recoverytext = recoverytext .. string.format( " @ %.1f kts wind", recovery.SPEED ) end rw = rw + 1 if rw >= 5 then -- Break the loop after 5 recovery times. break end end end end -- Recovery tanker TACAN text. local tankertext = nil if self.tanker then tankertext = string.format( "Recovery tanker frequency %.3f MHz\n", self.tanker.RadioFreq ) if self.tanker.TACANon then tankertext = tankertext .. string.format( "Recovery tanker TACAN %d%s (%s)", self.tanker.TACANchannel, self.tanker.TACANmode, self.tanker.TACANmorse ) else tankertext = tankertext .. "Recovery tanker TACAN n/a" end end -- Carrier FSM state. Idle is not clear enough. local state = self:GetState() if state == "Idle" then state = "Deck closed" end if self.turning then state = state .. " (currently turning)" end -- Message text. local text = string.format( "%s info:\n", self.alias ) text = text .. string.format( "================================\n" ) text = text .. string.format( "Carrier state: %s\n", state ) if self.case == 1 then text = text .. string.format( "Case %d recovery ops\n", self.case ) else local radial = self:GetRadial( self.case, true, true, false ) text = text .. string.format( "Case %d recovery ops\nMarshal radial %03d°\n", self.case, radial ) end text = text .. string.format( "BRC %03d° - FB %03d°\n", self:GetBRC(), self:GetFinalBearing( true ) ) text = text .. string.format( "Speed %.1f kts - Wind on deck %.1f kts\n", carrierspeed, wind ) text = text .. string.format( "Tower frequency %.3f MHz\n", self.TowerFreq ) text = text .. string.format( "Marshal radio %.3f MHz\n", self.MarshalFreq ) text = text .. string.format( "LSO radio %.3f MHz\n", self.LSOFreq ) text = text .. string.format( "TACAN Channel %s\n", tacan ) text = text .. string.format( "ICLS Channel %s\n", icls ) if tankertext then text = text .. tankertext .. "\n" end text = text .. string.format( "# A/C total %d (%d)\n", Ntotal, ntotal ) text = text .. string.format( "# A/C marshal %d (%d)\n", Nmarshal, nmarshal ) text = text .. string.format( "# A/C pattern %d (%d) - spinning %d (%d)\n", Npattern, npattern, Nspinning, nspinning ) text = text .. string.format( "# A/C waiting %d (%d)\n", Nwaiting, nwaiting ) text = text .. string.format( recoverytext ) self:T2( self.lid .. text ) -- Send message. self:MessageToPlayer( playerData, text, nil, "", 30, true ) else self:E( self.lid .. string.format( "ERROR: Could not get player data for player %s.", playername ) ) end end end --- Report weather conditions at the carrier location. Temperature, QFE pressure and wind data. -- @param #AIRBOSS self -- @param #string _unitname Name of the player unit. function AIRBOSS:_DisplayCarrierWeather( _unitname ) self:F2( _unitname ) -- Get player unit and player name. local unit, playername = self:_GetPlayerUnitAndName( _unitname ) -- Check if we have a player. if unit and playername then -- Message text. local text = "" -- Current coordinates. local coord = self:GetCoordinate() -- Get atmospheric data at carrier location. local T = coord:GetTemperature() local P = coord:GetPressure() -- Get wind direction (magnetic) and strength. local Wd, Ws = self:GetWind( nil, true ) -- Get Beaufort wind scale. local Bn, Bd = UTILS.BeaufortScale( Ws ) -- Wind on flight deck. local WodPA, WodPP = self:GetWindOnDeck() local WodPA = UTILS.MpsToKnots( WodPA ) local WodPP = UTILS.MpsToKnots( WodPP ) local WD = string.format( '%03d°', Wd ) local Ts = string.format( "%d°C", T ) local tT = string.format( "%d°C", T ) local tW = string.format( "%.1f knots", UTILS.MpsToKnots( Ws ) ) local tP = string.format( "%.2f inHg", UTILS.hPa2inHg( P ) ) -- Report text. text = text .. string.format( "Weather Report at Carrier %s:\n", self.alias ) text = text .. string.format( "================================\n" ) text = text .. string.format( "Temperature %s\n", tT ) text = text .. string.format( "Wind from %s at %s (%s)\n", WD, tW, Bd ) text = text .. string.format( "Wind on deck || %.1f kts, == %.1f kts\n", WodPA, WodPP ) text = text .. string.format( "QFE %.1f hPa = %s", P, tP ) -- More info only reliable if Mission uses static weather. if self.staticweather then local clouds, visibility, fog, dust = self:_GetStaticWeather() text = text .. string.format( "\nVisibility %.1f NM", UTILS.MetersToNM( visibility ) ) text = text .. string.format( "\nCloud base %d ft", UTILS.MetersToFeet( clouds.base ) ) text = text .. string.format( "\nCloud thickness %d ft", UTILS.MetersToFeet( clouds.thickness ) ) text = text .. string.format( "\nCloud density %d", clouds.density ) text = text .. string.format( "\nPrecipitation %d", clouds.iprecptns ) if fog then text = text .. string.format( "\nFog thickness %d ft", UTILS.MetersToFeet( fog.thickness ) ) text = text .. string.format( "\nFog visibility %d ft", UTILS.MetersToFeet( fog.visibility ) ) else text = text .. string.format( "\nNo fog" ) end if dust then text = text .. string.format( "\nDust density %d", dust ) else text = text .. string.format( "\nNo dust" ) end end -- Debug output. self:T2( self.lid .. text ) -- Send message to player group. self:MessageToPlayer( self.players[playername], text, nil, "", 30, true ) else self:E( self.lid .. string.format( "ERROR! Could not find player unit in CarrierWeather! Unit name = %s", _unitname ) ) end end ----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- -- HELP MENU ----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- --- Set difficulty level. -- @param #AIRBOSS self -- @param #string _unitname Name of the player unit. -- @param #AIRBOSS.Difficulty difficulty Difficulty level. function AIRBOSS:_SetDifficulty( _unitname, difficulty ) self:T2( { difficulty = difficulty, unitname = _unitname } ) -- Get player unit and player name. local unit, playername = self:_GetPlayerUnitAndName( _unitname ) -- Check if we have a player. if unit and playername then -- Player data. local playerData = self.players[playername] -- #AIRBOSS.PlayerData if playerData then playerData.difficulty = difficulty local text = string.format( "roger, your skill level is now: %s.", difficulty ) self:MessageToPlayer( playerData, text, nil, playerData.name, 5 ) else self:E( self.lid .. string.format( "ERROR: Could not get player data for player %s.", playername ) ) end -- Set hints as well. if playerData.difficulty == AIRBOSS.Difficulty.HARD then playerData.showhints = false else playerData.showhints = true end end end --- Turn player's aircraft attitude display on or off. -- @param #AIRBOSS self -- @param #string _unitname Name of the player unit. function AIRBOSS:_SetHintsOnOff( _unitname ) self:F2( _unitname ) -- Get player unit and player name. local unit, playername = self:_GetPlayerUnitAndName( _unitname ) -- Check if we have a player. if unit and playername then -- Player data. local playerData = self.players[playername] -- #AIRBOSS.PlayerData if playerData then -- Invert hints. playerData.showhints = not playerData.showhints -- Inform player. local text = "" if playerData.showhints == true then text = string.format( "roger, hints are now ON." ) else text = string.format( "affirm, hints are now OFF." ) end self:MessageToPlayer( playerData, text, nil, playerData.name, 5 ) end end end --- Turn player's aircraft attitude display on or off. -- @param #AIRBOSS self -- @param #string _unitname Name of the player unit. function AIRBOSS:_DisplayAttitude( _unitname ) self:F2( _unitname ) -- Get player unit and player name. local unit, playername = self:_GetPlayerUnitAndName( _unitname ) -- Check if we have a player. if unit and playername then -- Player data. local playerData = self.players[playername] -- #AIRBOSS.PlayerData if playerData then playerData.attitudemonitor = not playerData.attitudemonitor end end end --- Turn radio subtitles of player on or off. -- @param #AIRBOSS self -- @param #string _unitname Name of the player unit. function AIRBOSS:_SubtitlesOnOff( _unitname ) self:F2( _unitname ) -- Get player unit and player name. local unit, playername = self:_GetPlayerUnitAndName( _unitname ) -- Check if we have a player. if unit and playername then -- Player data. local playerData = self.players[playername] -- #AIRBOSS.PlayerData if playerData then playerData.subtitles = not playerData.subtitles -- Inform player. local text = "" if playerData.subtitles == true then text = string.format( "roger, subtitiles are now ON." ) elseif playerData.subtitles == false then text = string.format( "affirm, subtitiles are now OFF." ) end self:MessageToPlayer( playerData, text, nil, playerData.name, 5 ) end end end --- Turn radio subtitles of player on or off. -- @param #AIRBOSS self -- @param #string _unitname Name of the player unit. function AIRBOSS:_TrapsheetOnOff( _unitname ) self:F2( _unitname ) -- Get player unit and player name. local unit, playername = self:_GetPlayerUnitAndName( _unitname ) -- Check if we have a player. if unit and playername then -- Player data. local playerData = self.players[playername] -- #AIRBOSS.PlayerData if playerData then -- Check if option is enabled at all. local text = "" if self.trapsheet then -- Invert current setting. playerData.trapon = not playerData.trapon -- Inform player. if playerData.trapon == true then text = string.format( "roger, your trapsheets are now SAVED." ) else text = string.format( "affirm, your trapsheets are NOT SAVED." ) end else text = "negative, trap sheet data recorder is broken on this carrier." end -- Message to player. self:MessageToPlayer( playerData, text, nil, playerData.name, 5 ) end end end --- Display player status. -- @param #AIRBOSS self -- @param #string _unitName Name of the player unit. function AIRBOSS:_DisplayPlayerStatus( _unitName ) -- Get player unit and name. local _unit, _playername = self:_GetPlayerUnitAndName( _unitName ) -- Check if we have a unit which is a player. if _unit and _playername then local playerData = self.players[_playername] -- #AIRBOSS.PlayerData if playerData then -- Pattern step text. local steptext = playerData.step if playerData.step == AIRBOSS.PatternStep.HOLDING then if playerData.holding == nil then steptext = "Transit to Marshal" elseif playerData.holding == false then steptext = "Marshal (outside zone)" elseif playerData.holding == true then steptext = "Marshal Stack Holding" end end -- Stack. local stack = playerData.flag -- Stack text. local stacktext = nil if stack > 0 then local stackalt = self:_GetMarshalAltitude( stack ) local angels = self:_GetAngels( stackalt ) stacktext = string.format( "Marshal Stack %d, Angels %d\n", stack, angels ) -- Hint about TACAN bearing. if playerData.step == AIRBOSS.PatternStep.HOLDING and playerData.case > 1 then -- Get inverse magnetic radial potential offset. local radial = self:GetRadial( playerData.case, true, true, true ) stacktext = stacktext .. string.format( "Select TACAN %03d°, %d DME\n", radial, angels + 15 ) end end -- Fuel and fuel state. local fuel = playerData.unit:GetFuel() * 100 local fuelstate = self:_GetFuelState( playerData.unit ) -- Number of units in group. local _, nunitsGround = self:_GetFlightUnits( playerData, true ) local _, nunitsAirborne = self:_GetFlightUnits( playerData, false ) -- Player data. local text = string.format( "Status of player %s (%s)\n", playerData.name, playerData.callsign ) text = text .. string.format( "================================\n" ) text = text .. string.format( "Step: %s\n", steptext ) if stacktext then text = text .. stacktext end text = text .. string.format( "Recovery Case: %d\n", playerData.case ) text = text .. string.format( "Skill Level: %s\n", playerData.difficulty ) text = text .. string.format( "Modex: %s (%s)\n", playerData.onboard, self:_GetACNickname( playerData.actype ) ) text = text .. string.format( "Fuel State: %.1f lbs/1000 (%.1f %%)\n", fuelstate / 1000, fuel ) text = text .. string.format( "# units: %d (%d airborne)\n", nunitsGround, nunitsAirborne ) text = text .. string.format( "Section Lead: %s (%d/%d)", tostring( playerData.seclead ), #playerData.section + 1, self.NmaxSection + 1 ) for _, _sec in pairs( playerData.section ) do local sec = _sec -- #AIRBOSS.PlayerData text = text .. string.format( "\n- %s", sec.name ) end if playerData.step == AIRBOSS.PatternStep.INITIAL then -- Create a point 3.0 NM astern for re-entry. local zoneinitial = self:GetCoordinate():Translate( UTILS.NMToMeters( 3.5 ), self:GetRadial( 2, false, false, false ) ) -- Heading and distance to initial zone. local flyhdg = playerData.unit:GetCoordinate():HeadingTo( zoneinitial ) local flydist = UTILS.MetersToNM( playerData.unit:GetCoordinate():Get2DDistance( zoneinitial ) ) local brc = self:GetBRC() -- Help player to find its way to the initial zone. text = text .. string.format( "\nTo Initial: Fly heading %03d° for %.1f NM and turn to BRC %03d°", flyhdg, flydist, brc ) elseif playerData.step == AIRBOSS.PatternStep.PLATFORM then -- Coordinate of the platform zone. local zoneplatform = self:_GetZonePlatform( playerData.case ):GetCoordinate() -- Heading and distance to platform zone. local flyhdg = playerData.unit:GetCoordinate():HeadingTo( zoneplatform ) local flydist = UTILS.MetersToNM( playerData.unit:GetCoordinate():Get2DDistance( zoneplatform ) ) -- Get heading. local hdg = self:GetRadial( playerData.case, true, true, true ) -- Help player to find its way to the initial zone. text = text .. string.format( "\nTo Platform: Fly heading %03d° for %.1f NM and turn to %03d°", flyhdg, flydist, hdg ) end -- Send message. self:MessageToPlayer( playerData, text, nil, "", 30, true ) else self:E( self.lid .. string.format( "ERROR: playerData=nil. Unit name=%s, player name=%s", _unitName, _playername ) ) end else self:E( self.lid .. string.format( "ERROR: could not find player for unit %s", _unitName ) ) end end --- Mark current marshal zone of player by either smoke or flares. -- @param #AIRBOSS self -- @param #string _unitName Name of the player unit. -- @param #boolean flare If true, flare the zone. If false, smoke the zone. function AIRBOSS:_MarkMarshalZone( _unitName, flare ) -- Get player unit and name. local _unit, _playername = self:_GetPlayerUnitAndName( _unitName ) -- Check if we have a unit which is a player. if _unit and _playername then local playerData = self.players[_playername] -- #AIRBOSS.PlayerData if playerData then -- Get player stack and recovery case. local stack = playerData.flag local case = playerData.case local text = "" if stack > 0 then -- Get current holding zone. local zoneHolding = self:_GetZoneHolding( case, stack ) -- Get Case I commence zone at three position. local zoneThree = self:_GetZoneCommence( case, stack ) -- Pattern altitude. local patternalt = self:_GetMarshalAltitude( stack, case ) -- Flare and smoke at the ground. patternalt = 5 -- Roger! text = "roger, marking" if flare then -- Marshal WHITE flares. text = text .. string.format( "\n* Marshal zone stack %d with WHITE flares.", stack ) zoneHolding:FlareZone( FLARECOLOR.White, 45, nil, patternalt ) -- Commence RED flares. text = text .. "\n* Commence zone with RED flares." zoneThree:FlareZone( FLARECOLOR.Red, 45, nil, patternalt ) else -- Marshal WHITE smoke. text = text .. string.format( "\n* Marshal zone stack %d with WHITE smoke.", stack ) zoneHolding:SmokeZone( SMOKECOLOR.White, 45, patternalt ) -- Commence RED smoke text = text .. "\n* Commence zone with RED smoke." zoneThree:SmokeZone( SMOKECOLOR.Red, 45, patternalt ) end else text = "negative, you are currently not in a Marshal stack. No zones will be marked!" end -- Send message to player. self:MessageToPlayer( playerData, text, "MARSHAL", playerData.name ) end end end --- Mark CASE I or II/II zones by either smoke or flares. -- @param #AIRBOSS self -- @param #string _unitName Name of the player unit. -- @param #boolean flare If true, flare the zone. If false, smoke the zone. function AIRBOSS:_MarkCaseZones( _unitName, flare ) -- Get player unit and name. local _unit, _playername = self:_GetPlayerUnitAndName( _unitName ) -- Check if we have a unit which is a player. if _unit and _playername then local playerData = self.players[_playername] -- #AIRBOSS.PlayerData if playerData then -- Player's recovery case. local case = playerData.case -- Initial local text = string.format( "affirm, marking CASE %d zones", case ) -- Flare or smoke? if flare then ----------- -- Flare -- ----------- -- Case I/II: Initial if case == 1 or case == 2 then text = text .. "\n* initial with GREEN flares" self:_GetZoneInitial( case ):FlareZone( FLARECOLOR.Green, 45 ) end -- Case II/III: approach corridor if case == 2 or case == 3 then text = text .. "\n* approach corridor with GREEN flares" self:_GetZoneCorridor( case ):FlareZone( FLARECOLOR.Green, 45 ) end -- Case II/III: platform if case == 2 or case == 3 then text = text .. "\n* platform with RED flares" self:_GetZonePlatform( case ):FlareZone( FLARECOLOR.Red, 45 ) end -- Case III: dirty up if case == 3 then text = text .. "\n* dirty up with YELLOW flares" self:_GetZoneDirtyUp( case ):FlareZone( FLARECOLOR.Yellow, 45 ) end -- Case II/III: arc in/out if case == 2 or case == 3 then if math.abs( self.holdingoffset ) > 0 then self:_GetZoneArcIn( case ):FlareZone( FLARECOLOR.White, 45 ) text = text .. "\n* arc turn in with WHITE flares" self:_GetZoneArcOut( case ):FlareZone( FLARECOLOR.White, 45 ) text = text .. "\n* arc turn out with WHITE flares" end end -- Case III: bullseye if case == 3 then text = text .. "\n* bullseye with GREEN flares" self:_GetZoneBullseye( case ):FlareZone( FLARECOLOR.Green, 45 ) end -- Tarawa, LHA and LHD landing spots. if self.carriertype == AIRBOSS.CarrierType.INVINCIBLE or self.carriertype == AIRBOSS.CarrierType.HERMES or self.carriertype == AIRBOSS.CarrierType.TARAWA or self.carriertype == AIRBOSS.CarrierType.AMERICA or self.carriertype == AIRBOSS.CarrierType.JCARLOS or self.carriertype == AIRBOSS.CarrierType.CANBERRA then text = text .. "\n* abeam landing stop with RED flares" -- Abeam landing spot zone. local ALSPT = self:_GetZoneAbeamLandingSpot() ALSPT:FlareZone( FLARECOLOR.Red, 5, nil, UTILS.FeetToMeters( 110 ) ) -- Primary landing spot zone. text = text .. "\n* primary landing spot with GREEN flares" local LSPT = self:_GetZoneLandingSpot() LSPT:FlareZone( FLARECOLOR.Green, 5, nil, self.carrierparam.deckheight ) end else ----------- -- Smoke -- ----------- -- Case I/II: Initial if case == 1 or case == 2 then text = text .. "\n* initial with GREEN smoke" self:_GetZoneInitial( case ):SmokeZone( SMOKECOLOR.Green, 45 ) end -- Case II/III: Approach Corridor if case == 2 or case == 3 then text = text .. "\n* approach corridor with GREEN smoke" self:_GetZoneCorridor( case ):SmokeZone( SMOKECOLOR.Green, 45 ) end -- Case II/III: platform if case == 2 or case == 3 then text = text .. "\n* platform with RED smoke" self:_GetZonePlatform( case ):SmokeZone( SMOKECOLOR.Red, 45 ) end -- Case II/III: arc in/out if offset>0. if case == 2 or case == 3 then if math.abs( self.holdingoffset ) > 0 then self:_GetZoneArcIn( case ):SmokeZone( SMOKECOLOR.Blue, 45 ) text = text .. "\n* arc turn in with BLUE smoke" self:_GetZoneArcOut( case ):SmokeZone( SMOKECOLOR.Blue, 45 ) text = text .. "\n* arc turn out with BLUE smoke" end end -- Case III: dirty up if case == 3 then text = text .. "\n* dirty up with ORANGE smoke" self:_GetZoneDirtyUp( case ):SmokeZone( SMOKECOLOR.Orange, 45 ) end -- Case III: bullseye if case == 3 then text = text .. "\n* bullseye with GREEN smoke" self:_GetZoneBullseye( case ):SmokeZone( SMOKECOLOR.Green, 45 ) end end -- Send message to player. self:MessageToPlayer( playerData, text, "MARSHAL", playerData.name ) end end end --- LSO radio check. Will broadcase LSO message at given LSO frequency. -- @param #AIRBOSS self -- @param #string _unitName Name fo the player unit. function AIRBOSS:_LSORadioCheck( _unitName ) self:F( _unitName ) -- Get player unit and name. local _unit, _playername = self:_GetPlayerUnitAndName( _unitName ) -- Check if we have a unit which is a player. if _unit and _playername then local playerData = self.players[_playername] -- #AIRBOSS.PlayerData if playerData then -- Broadcase LSO radio check message on LSO radio. self:RadioTransmission( self.LSORadio, self.LSOCall.RADIOCHECK, nil, nil, nil, true ) end end end --- Marshal radio check. Will broadcase Marshal message at given Marshal frequency. -- @param #AIRBOSS self -- @param #string _unitName Name fo the player unit. function AIRBOSS:_MarshalRadioCheck( _unitName ) self:F( _unitName ) -- Get player unit and name. local _unit, _playername = self:_GetPlayerUnitAndName( _unitName ) -- Check if we have a unit which is a player. if _unit and _playername then local playerData = self.players[_playername] -- #AIRBOSS.PlayerData if playerData then -- Broadcase Marshal radio check message on Marshal radio. self:RadioTransmission( self.MarshalRadio, self.MarshalCall.RADIOCHECK, nil, nil, nil, true ) end end end ------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------ -- Persistence Functions ------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------ --- Save trapsheet data. -- @param #AIRBOSS self -- @param #AIRBOSS.PlayerData playerData Player data table. -- @param #AIRBOSS.LSOgrade grade LSO grad data. function AIRBOSS:_SaveTrapSheet( playerData, grade ) -- Nothing to save. if playerData.trapsheet == nil or #playerData.trapsheet == 0 or not io then return end --- Function that saves data to file local function _savefile( filename, data ) local f = io.open( filename, "wb" ) if f then f:write( data ) f:close() else self:E( self.lid .. string.format( "ERROR: could not save trap sheet to file %s.\nFile may contain invalid characters.", tostring( filename ) ) ) end end -- Set path or default. local path = self.trappath if lfs then path = path or lfs.writedir() end -- Create unused file name. local filename = nil for i = 1, 9999 do -- Create file name if self.trapprefix then filename = string.format( "%s_%s-%04d.csv", self.trapprefix, playerData.actype, i ) else local name = UTILS.ReplaceIllegalCharacters( playerData.name, "_" ) filename = string.format( "AIRBOSS-%s_Trapsheet-%s_%s-%04d.csv", self.alias, name, playerData.actype, i ) end -- Set path. if path ~= nil then filename = path .. "\\" .. filename end -- Check if file exists. local _exists = UTILS.FileExists( filename ) if not _exists then break end end -- Info local text = string.format( "Saving player %s trapsheet to file %s", playerData.name, filename ) self:I( self.lid .. text ) -- Header line local data = "#Time,Rho,X,Z,Alt,AoA,GSE,LUE,Vtot,Vy,Gamma,Pitch,Roll,Yaw,Step,Grade,Points,Details\n" local g0 = playerData.trapsheet[1] -- #AIRBOSS.GrooveData local T0 = g0.Time -- for _,_groove in ipairs(playerData.trapsheet) do for i = 1, #playerData.trapsheet do -- local groove=_groove --#AIRBOSS.GrooveData local groove = playerData.trapsheet[i] local t = groove.Time - T0 local a = UTILS.MetersToNM( groove.Rho or 0 ) local b = -groove.X or 0 local c = groove.Z or 0 local d = UTILS.MetersToFeet( groove.Alt or 0 ) local e = groove.AoA or 0 local f = groove.GSE or 0 local g = -groove.LUE or 0 local h = UTILS.MpsToKnots( groove.Vel or 0 ) local i = (groove.Vy or 0) * 196.85 local j = groove.Gamma or 0 local k = groove.Pitch or 0 local l = groove.Roll or 0 local m = groove.Yaw or 0 local n = self:_GS( groove.Step, -1 ) or "n/a" local o = groove.Grade or "n/a" local p = groove.GradePoints or 0 local q = groove.GradeDetail or "n/a" -- t a b c d e f g h i j k l m n o p q data = data .. string.format( "%.2f,%.3f,%.1f,%.1f,%.1f,%.2f,%.2f,%.2f,%.1f,%.1f,%.1f,%.1f,%.1f,%.1f,%s,%s,%.1f,%s\n", t, a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q ) end -- Save file. _savefile( filename, data ) end --- On before "Save" event. Checks if io and lfs are available. -- @param #AIRBOSS self -- @param #string From From state. -- @param #string Event Event. -- @param #string To To state. -- @param #string path (Optional) Path where the file is saved. Default is the DCS root installation folder or your "Saved Games\\DCS" folder if the lfs module is desanitized. -- @param #string filename (Optional) File name for saving the player grades. Default is "AIRBOSS-_LSOgrades.csv". function AIRBOSS:onbeforeSave( From, Event, To, path, filename ) -- Check io module is available. if not io then self:E( self.lid .. "ERROR: io not desanitized. Can't save player grades." ) return false end -- Check default path. if path == nil and not lfs then self:E( self.lid .. "WARNING: lfs not desanitized. Results will be saved in DCS installation root directory rather than your \"Saved Games\\DCS\" folder." ) end return true end --- On after "Save" event. Player data is saved to file. -- @param #AIRBOSS self -- @param #string From From state. -- @param #string Event Event. -- @param #string To To state. -- @param #string path Path where the file is saved. If nil, file is saved in the DCS root installtion directory or your "Saved Games" folder if lfs was desanitized. -- @param #string filename (Optional) File name for saving the player grades. Default is "AIRBOSS-_LSOgrades.csv". function AIRBOSS:onafterSave( From, Event, To, path, filename ) --- Function that saves data to file local function _savefile( filename, data ) local f = assert( io.open( filename, "wb" ) ) f:write( data ) f:close() end -- Set path or default. if lfs then path = path or lfs.writedir() end -- Set file name. filename = filename or string.format( "AIRBOSS-%s_LSOgrades.csv", self.alias ) -- Set path. if path ~= nil then filename = path .. "\\" .. filename end -- Header line local scores = "Name,Pass,Points Final,Points Pass,Grade,Details,Wire,Tgroove,Case,Wind,Modex,Airframe,Carrier Type,Carrier Name,Theatre,Mission Time,Mission Date,OS Date\n" -- Loop over all players. local n = 0 for playername, grades in pairs( self.playerscores ) do -- Loop over player grades table. for i, _grade in pairs( grades ) do local grade = _grade -- #AIRBOSS.LSOgrade -- Check some stuff that could be nil. local wire = "n/a" if grade.wire and grade.wire <= 4 then wire = tostring( grade.wire ) end local Tgroove = "n/a" if grade.Tgroove and grade.Tgroove <= 360 and grade.case < 3 then Tgroove = tostring( UTILS.Round( grade.Tgroove, 1 ) ) end local finalscore = "n/a" if grade.finalscore then finalscore = tostring( UTILS.Round( grade.finalscore, 1 ) ) end -- Compile grade line. scores = scores .. string.format( "%s,%d,%s,%.1f,%s,%s,%s,%s,%d,%s,%s,%s,%s,%s,%s,%s,%s,%s\n", playername, i, finalscore, grade.points, grade.grade, grade.details, wire, Tgroove, grade.case, grade.wind, grade.modex, grade.airframe, grade.carriertype, grade.carriername, grade.theatre, grade.mitime, grade.midate, grade.osdate ) n = n + 1 end end -- Info local text = string.format( "Saving %d player LSO grades to file %s", n, filename ) self:I( self.lid .. text ) -- Save file. _savefile( filename, scores ) end --- On before "Load" event. Checks if the file that the player grades from exists. -- @param #AIRBOSS self -- @param #string From From state. -- @param #string Event Event. -- @param #string To To state. -- @param #string path (Optional) Path where the file is loaded from. Default is the DCS installation root directory or your "Saved Games\\DCS" folder if lfs was desanizized. -- @param #string filename (Optional) File name for saving the player grades. Default is "AIRBOSS-_LSOgrades.csv". function AIRBOSS:onbeforeLoad( From, Event, To, path, filename ) --- Function that check if a file exists. local function _fileexists( name ) local f = io.open( name, "r" ) if f ~= nil then io.close( f ) return true else return false end end -- Check io module is available. if not io then self:E( self.lid .. "WARNING: io not desanitized. Can't load player grades." ) return false end -- Check default path. if path == nil and not lfs then self:E( self.lid .. "WARNING: lfs not desanitized. Results will be saved in DCS installation root directory rather than your \"Saved Games\\DCS\" folder." ) end -- Set path or default. if lfs then path = path or lfs.writedir() end -- Set file name. filename = filename or string.format( "AIRBOSS-%s_LSOgrades.csv", self.alias ) -- Set path. if path ~= nil then filename = path .. "\\" .. filename end -- Check if file exists. local exists = _fileexists( filename ) if exists then return true else self:E( self.lid .. string.format( "WARNING: Player LSO grades file %s does not exist.", filename ) ) return false end end --- On after "Load" event. Loads grades of all players from file. -- @param #AIRBOSS self -- @param #string From From state. -- @param #string Event Event. -- @param #string To To state. -- @param #string path Path where the file is loaded from. Default is the DCS root installation folder or your "Saved Games\\DCS" folder if lfs was desanizied. -- @param #string filename (Optional) File name for saving the player grades. Default is "AIRBOSS-_LSOgrades.csv". function AIRBOSS:onafterLoad( From, Event, To, path, filename ) --- Function that load data from a file. local function _loadfile( filename ) local f = assert( io.open( filename, "rb" ) ) local data = f:read( "*all" ) f:close() return data end -- Set path or default. if lfs then path = path or lfs.writedir() end -- Set file name. filename = filename or string.format( "AIRBOSS-%s_LSOgrades.csv", self.alias ) -- Set path. if path ~= nil then filename = path .. "\\" .. filename end -- Info message. local text = string.format( "Loading player LSO grades from file %s", filename ) MESSAGE:New( text, 10 ):ToAllIf( self.Debug ) self:I( self.lid .. text ) -- Load asset data from file. local data = _loadfile( filename ) -- Split by line break. local playergrades = UTILS.Split( data, "\n" ) -- Remove first header line. table.remove( playergrades, 1 ) -- Init player scores table. self.playerscores = {} -- Loop over all lines. local n = 0 for _, gradeline in pairs( playergrades ) do -- Parameters are separated by commata. local gradedata = UTILS.Split( gradeline, "," ) -- Debug info. self:T2( gradedata ) -- Grade table local grade = {} -- #AIRBOSS.LSOgrade --- Line format: -- playername, i, grade.finalscore, grade.points, grade.grade, grade.details, wire, Tgroove, case, -- time, wind, airframe, modex, carriertype, carriername, theatre, date local playername = gradedata[1] if gradedata[3] ~= nil and gradedata[3] ~= "n/a" then grade.finalscore = tonumber( gradedata[3] ) end grade.points = tonumber( gradedata[4] ) grade.grade = tostring( gradedata[5] ) grade.details = tostring( gradedata[6] ) if gradedata[7] ~= nil and gradedata[7] ~= "n/a" then grade.wire = tonumber( gradedata[7] ) end if gradedata[8] ~= nil and gradedata[8] ~= "n/a" then grade.Tgroove = tonumber( gradedata[8] ) end grade.case = tonumber( gradedata[9] ) -- new grade.wind = gradedata[10] or "n/a" grade.modex = gradedata[11] or "n/a" grade.airframe = gradedata[12] or "n/a" grade.carriertype = gradedata[13] or "n/a" grade.carriername = gradedata[14] or "n/a" grade.theatre = gradedata[15] or "n/a" grade.mitime = gradedata[16] or "n/a" grade.midate = gradedata[17] or "n/a" grade.osdate = gradedata[18] or "n/a" -- Init player table if necessary. self.playerscores[playername] = self.playerscores[playername] or {} -- Add grade to table. table.insert( self.playerscores[playername], grade ) n = n + 1 -- Debug info. self:T2( { playername, self.playerscores[playername] } ) end -- Info message. local text = string.format( "Loaded %d player LSO grades from file %s", n, filename ) self:I( self.lid .. text ) end --- On after "LSOGrade" event. -- @param #AIRBOSS self -- @param #string From From state. -- @param #string Event Event. -- @param #string To To state. -- @param #AIRBOSS.PlayerData playerData Player Data. -- @param #AIRBOSS.LSOgrade grade LSO grade. function AIRBOSS:onafterLSOGrade(From, Event, To, playerData, grade) if self.funkmanSocket then -- Extract used info for FunkMan. We need to be careful with the amount of data send via UDP socket. local trapsheet={} ; trapsheet.X={} ; trapsheet.Z={} ; trapsheet.AoA={} ; trapsheet.Alt={} -- Loop over trapsheet and extract used values. for i = 1, #playerData.trapsheet do local ts=playerData.trapsheet[i] --#AIRBOSS.GrooveData table.insert(trapsheet.X, UTILS.Round(ts.X, 1)) table.insert(trapsheet.Z, UTILS.Round(ts.Z, 1)) table.insert(trapsheet.AoA, UTILS.Round(ts.AoA, 2)) table.insert(trapsheet.Alt, UTILS.Round(ts.Alt, 1)) end local result={} result.command=SOCKET.DataType.LSOGRADE result.name=playerData.name result.trapsheet=trapsheet result.airframe=grade.airframe result.mitime=grade.mitime result.midate=grade.midate result.wind=grade.wind result.carriertype=grade.carriertype result.carriername=grade.carriername result.carrierrwy=grade.carrierrwy result.landingdist=self.carrierparam.landingdist result.theatre=grade.theatre result.case=playerData.case result.Tgroove=grade.Tgroove result.wire=grade.wire result.grade=grade.grade result.points=grade.points result.details=grade.details -- Debug info. self:T(self.lid.."Result onafterLSOGrade") self:T(result) -- Send result. self.funkmanSocket:SendTable(result) end end ------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------ ------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------ ------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------