General fixes (#1673)

* General minor

Code formatting and minor typo/document fixes.

* Update Marker.lua

Code formatting and minor typo/document fixes. Note specifically the correction of "self.tocoaliton" to "self.tocoalition".

Moose Development/Moose/AI/AI_A2A_Cap.lua

@@ -40,8 +40,8 @@
 --
 -- ![Process](..\Presentations\AI_CAP\Dia10.JPG)
 --
--- Until a fuel or damage treshold has been reached by the AI, or when the AI is commanded to RTB.
+-- Until a fuel or damage threshold has been reached by the AI, or when the AI is commanded to RTB.
--- When the fuel treshold has been reached, the airplane will fly towards the nearest friendly airbase and will land.
+-- When the fuel threshold has been reached, the airplane will fly towards the nearest friendly airbase and will land.
 --
 -- ![Process](..\Presentations\AI_CAP\Dia13.JPG)
 --
@@ -71,7 +71,7 @@
 --   * **@{AI.AI_Patrol#AI_PATROL_ZONE.Detected}**: The AI has detected new targets.
 --   * **@{#AI_A2A_CAP.Destroy}**: The AI has destroyed a bogey @{Wrapper.Unit}.
 --   * **@{#AI_A2A_CAP.Destroyed}**: The AI has destroyed all bogeys @{Wrapper.Unit}s assigned in the CAS task.
---   * **Status** ( Group ): The AI is checking status (fuel and damage). When the tresholds have been reached, the AI will RTB.
+--   * **Status** ( Group ): The AI is checking status (fuel and damage). When the thresholds have been reached, the AI will RTB.
 --
 -- ## 3. Set the Range of Engagement
 --

Moose Development/Moose/AI/AI_A2A_Gci.lua

@@ -42,8 +42,8 @@
 --
 -- ![Process](..\Presentations\AI_GCI\Dia10.JPG)
 --
--- Until a fuel or damage treshold has been reached by the AI, or when the AI is commanded to RTB.
+-- Until a fuel or damage threshold has been reached by the AI, or when the AI is commanded to RTB.
--- When the fuel treshold has been reached, the airplane will fly towards the nearest friendly airbase and will land.
+-- When the fuel threshold has been reached, the airplane will fly towards the nearest friendly airbase and will land.
 --
 -- ![Process](..\Presentations\AI_GCI\Dia13.JPG)
 --
@@ -73,7 +73,7 @@
 --   * **@{AI.AI_Patrol#AI_PATROL_ZONE.Detected}**: The AI has detected new targets.
 --   * **@{#AI_A2A_GCI.Destroy}**: The AI has destroyed a bogey @{Wrapper.Unit}.
 --   * **@{#AI_A2A_GCI.Destroyed}**: The AI has destroyed all bogeys @{Wrapper.Unit}s assigned in the CAS task.
---   * **Status** ( Group ): The AI is checking status (fuel and damage). When the tresholds have been reached, the AI will RTB.
+--   * **Status** ( Group ): The AI is checking status (fuel and damage). When the thresholds have been reached, the AI will RTB.
 --
 -- ## 3. Set the Range of Engagement
 --

Moose Development/Moose/AI/AI_A2A_Patrol.lua

@@ -39,8 +39,8 @@
 -- 
 -- ![Process](..\Presentations\AI_PATROL\Dia10.JPG)
 -- 
--- Until a fuel or damage treshold has been reached by the AI, or when the AI is commanded to RTB.
+-- Until a fuel or damage threshold has been reached by the AI, or when the AI is commanded to RTB.
--- When the fuel treshold has been reached, the airplane will fly towards the nearest friendly airbase and will land.
+-- When the fuel threshold has been reached, the airplane will fly towards the nearest friendly airbase and will land.
 -- 
 -- ![Process](..\Presentations\AI_PATROL\Dia11.JPG)
 -- 
@@ -68,7 +68,7 @@
 --   * **RTB** ( Group ): Route the AI to the home base.
 --   * **Detect** ( Group ): The AI is detecting targets.
 --   * **Detected** ( Group ): The AI has detected new targets.
---   * **Status** ( Group ): The AI is checking status (fuel and damage). When the tresholds have been reached, the AI will RTB.
+--   * **Status** ( Group ): The AI is checking status (fuel and damage). When the thresholds have been reached, the AI will RTB.
 --    
 -- ## 3. Set or Get the AI controllable
 -- 
@@ -100,8 +100,8 @@
 -- ## 6. Manage the "out of fuel" in the AI_A2A_PATROL
 -- 
 -- When the AI is out of fuel, it is required that a new AI is started, before the old AI can return to the home base.
--- Therefore, with a parameter and a calculation of the distance to the home base, the fuel treshold is calculated.
+-- Therefore, with a parameter and a calculation of the distance to the home base, the fuel threshold is calculated.
--- When the fuel treshold is reached, the AI will continue for a given time its patrol task in orbit, 
+-- When the fuel threshold is reached, the AI will continue for a given time its patrol task in orbit, 
 -- while a new AI is targetted to the AI_A2A_PATROL.
 -- Once the time is finished, the old AI will return to the base.
 -- Use the method @{#AI_A2A_PATROL.ManageFuel}() to have this proces in place.
@@ -109,7 +109,7 @@
 -- ## 7. Manage "damage" behaviour of the AI in the AI_A2A_PATROL
 -- 
 -- When the AI is damaged, it is required that a new Patrol is started. However, damage cannon be foreseen early on. 
--- Therefore, when the damage treshold is reached, the AI will return immediately to the home base (RTB).
+-- Therefore, when the damage threshold is reached, the AI will return immediately to the home base (RTB).
 -- Use the method @{#AI_A2A_PATROL.ManageDamage}() to have this proces in place.
 -- 
 -- ===

Moose Development/Moose/AI/AI_A2G_Dispatcher.lua

@@ -3243,17 +3243,17 @@ do -- AI_A2G_DISPATCHER
     return self
   end
   
-  --- Set the default fuel treshold when defenders will RTB or Refuel in the air.
+  --- Set the default fuel threshold when defenders will RTB or Refuel in the air.
-  -- The fuel treshold is by default set to 15%, which means that an aircraft will stay in the air until 15% of its fuel is remaining.
+  -- The fuel threshold is by default set to 15%, which means that an aircraft will stay in the air until 15% of its fuel is remaining.
   -- @param #AI_A2G_DISPATCHER self
-  -- @param #number FuelThreshold A decimal number between 0 and 1, that expresses the % of the treshold of fuel remaining in the tank when the plane will go RTB or Refuel.
+  -- @param #number FuelThreshold A decimal number between 0 and 1, that expresses the % of the threshold of fuel remaining in the tank when the plane will go RTB or Refuel.
   -- @return #AI_A2G_DISPATCHER
   -- @usage
   -- 
   --   -- Now Setup the A2G dispatcher, and initialize it using the Detection object.
   --   A2GDispatcher = AI_A2G_DISPATCHER:New( Detection )  
   --   
-  --   -- Now Setup the default fuel treshold.
+  --   -- Now Setup the default fuel threshold.
   --   A2GDispatcher:SetDefaultFuelThreshold( 0.30 ) -- Go RTB when only 30% of fuel remaining in the tank.
   --   
   function AI_A2G_DISPATCHER:SetDefaultFuelThreshold( FuelThreshold )
@@ -3264,18 +3264,18 @@ do -- AI_A2G_DISPATCHER
   end  
 
 
-  --- Set the fuel treshold for the squadron when defenders will RTB or Refuel in the air.
+  --- Set the fuel threshold for the squadron when defenders will RTB or Refuel in the air.
-  -- The fuel treshold is by default set to 15%, which means that an aircraft will stay in the air until 15% of its fuel is remaining.
+  -- The fuel threshold is by default set to 15%, which means that an aircraft will stay in the air until 15% of its fuel is remaining.
   -- @param #AI_A2G_DISPATCHER self
   -- @param #string SquadronName The name of the squadron.
-  -- @param #number FuelThreshold A decimal number between 0 and 1, that expresses the % of the treshold of fuel remaining in the tank when the plane will go RTB or Refuel.
+  -- @param #number FuelThreshold A decimal number between 0 and 1, that expresses the % of the threshold of fuel remaining in the tank when the plane will go RTB or Refuel.
   -- @return #AI_A2G_DISPATCHER
   -- @usage
   -- 
   --   -- Now Setup the A2G dispatcher, and initialize it using the Detection object.
   --   A2GDispatcher = AI_A2G_DISPATCHER:New( Detection )  
   --   
-  --   -- Now Setup the default fuel treshold.
+  --   -- Now Setup the default fuel threshold.
   --   A2GDispatcher:SetSquadronRefuelThreshold( "SquadronName", 0.30 ) -- Go RTB when only 30% of fuel remaining in the tank.
   --   
   function AI_A2G_DISPATCHER:SetSquadronFuelThreshold( SquadronName, FuelThreshold )
@@ -3295,7 +3295,7 @@ do -- AI_A2G_DISPATCHER
   --   -- Now Setup the A2G dispatcher, and initialize it using the Detection object.
   --   A2GDispatcher = AI_A2G_DISPATCHER:New( Detection )  
   --   
-  --   -- Now Setup the default fuel treshold.
+  --   -- Now Setup the default fuel threshold.
   --   A2GDispatcher:SetDefaultFuelThreshold( 0.30 ) -- Go RTB when only 30% of fuel remaining in the tank.
   --   
   --   -- Now Setup the default tanker.
@@ -3318,7 +3318,7 @@ do -- AI_A2G_DISPATCHER
   --   -- Now Setup the A2G dispatcher, and initialize it using the Detection object.
   --   A2GDispatcher = AI_A2G_DISPATCHER:New( Detection )  
   --   
-  --   -- Now Setup the squadron fuel treshold.
+  --   -- Now Setup the squadron fuel threshold.
   --   A2GDispatcher:SetSquadronRefuelThreshold( "SquadronName", 0.30 ) -- Go RTB when only 30% of fuel remaining in the tank.
   --   
   --   -- Now Setup the squadron tanker.
@@ -3421,7 +3421,7 @@ do -- AI_A2G_DISPATCHER
   -- @param #AI_A2G_DISPATCHER self
   function AI_A2G_DISPATCHER:CountDefendersEngaged( AttackerDetection, AttackerCount )
 
-    -- First, count the active AIGroups Units, targetting the DetectedSet
+    -- First, count the active AIGroups Units, targeting the DetectedSet
     local DefendersEngaged = 0
     local DefendersTotal = 0
     

Moose Development/Moose/AI/AI_A2G_SEAD.lua

@@ -42,8 +42,8 @@
 -- 
 -- ![Process](..\Presentations\AI_GCI\Dia10.JPG)
 -- 
--- Until a fuel or damage treshold has been reached by the AI, or when the AI is commanded to RTB.
+-- Until a fuel or damage threshold has been reached by the AI, or when the AI is commanded to RTB.
--- When the fuel treshold has been reached, the airplane will fly towards the nearest friendly airbase and will land.
+-- When the fuel threshold has been reached, the airplane will fly towards the nearest friendly airbase and will land.
 -- 
 -- ![Process](..\Presentations\AI_GCI\Dia13.JPG)
 -- 

Moose Development/Moose/AI/AI_Air.lua

@@ -370,11 +370,11 @@ end
 
 
 --- When the AI is out of fuel, it is required that a new AI is started, before the old AI can return to the home base.
--- Therefore, with a parameter and a calculation of the distance to the home base, the fuel treshold is calculated.
+-- Therefore, with a parameter and a calculation of the distance to the home base, the fuel threshold is calculated.
--- When the fuel treshold is reached, the AI will continue for a given time its patrol task in orbit, while a new AIControllable is targetted to the AI_AIR.
+-- When the fuel threshold is reached, the AI will continue for a given time its patrol task in orbit, while a new AIControllable is targetted to the AI_AIR.
 -- Once the time is finished, the old AI will return to the base.
 -- @param #AI_AIR self
--- @param #number FuelThresholdPercentage The treshold in percentage (between 0 and 1) when the AIControllable is considered to get out of fuel.
+-- @param #number FuelThresholdPercentage The threshold in percentage (between 0 and 1) when the AIControllable is considered to get out of fuel.
 -- @param #number OutOfFuelOrbitTime The amount of seconds the out of fuel AIControllable will orbit before returning to the base.
 -- @return #AI_AIR self
 function AI_AIR:SetFuelThreshold( FuelThresholdPercentage, OutOfFuelOrbitTime )
@@ -387,14 +387,14 @@ function AI_AIR:SetFuelThreshold( FuelThresholdPercentage, OutOfFuelOrbitTime )
   return self
 end
 
---- When the AI is damaged beyond a certain treshold, it is required that the AI returns to the home base.
+--- When the AI is damaged beyond a certain threshold, it is required that the AI returns to the home base.
 -- However, damage cannot be foreseen early on. 
--- Therefore, when the damage treshold is reached, 
+-- Therefore, when the damage threshold is reached, 
 -- the AI will return immediately to the home base (RTB).
 -- Note that for groups, the average damage of the complete group will be calculated.
--- So, in a group of 4 airplanes, 2 lost and 2 with damage 0.2, the damage treshold will be 0.25.
+-- So, in a group of 4 airplanes, 2 lost and 2 with damage 0.2, the damage threshold will be 0.25.
 -- @param #AI_AIR self
--- @param #number PatrolDamageThreshold The treshold in percentage (between 0 and 1) when the AI is considered to be damaged.
+-- @param #number PatrolDamageThreshold The threshold in percentage (between 0 and 1) when the AI is considered to be damaged.
 -- @return #AI_AIR self
 function AI_AIR:SetDamageThreshold( PatrolDamageThreshold )
 
@@ -476,7 +476,7 @@ function AI_AIR:onafterStatus()
       
       local Fuel = self.Controllable:GetFuelMin()
       
-      -- If the fuel in the controllable is below the treshold percentage,
+      -- If the fuel in the controllable is below the threshold percentage,
       -- then send for refuel in case of a tanker, otherwise RTB.
       if Fuel < self.FuelThresholdPercentage then
       

Moose Development/Moose/AI/AI_Air_Dispatcher.lua

@@ -10,11 +10,11 @@
 --    * Setup (CAS) Controlled Air Support squadrons, to attack closeby enemy ground units near friendly installations.
 --    * Setup (BAI) Battleground Air Interdiction squadrons to attack remote enemy ground units and targets.
 --    * Define and use a detection network controlled by recce.
---    * Define AIR defense squadrons at airbases, farps and carriers.
+--    * Define AIR defense squadrons at airbases, FARPs and carriers.
 --    * Enable airbases for AIR defenses.
 --    * Add different planes and helicopter templates to squadrons.
 --    * Assign squadrons to execute a specific engagement type depending on threat level of the detected ground enemy unit composition.
---    * Add multiple squadrons to different airbases, farps or carriers.
+--    * Add multiple squadrons to different airbases, FARPs or carriers.
 --    * Define different ranges to engage upon.
 --    * Establish an automatic in air refuel process for planes using refuel tankers.
 --    * Setup default settings for all squadrons and AIR defenses.
@@ -40,7 +40,7 @@
 -- 
 -- AI_AIR_DISPATCHER is the main AIR defense class that models the AIR defense system.
 -- 
--- Before you start using the AI_AIR_DISPATCHER, ask youself the following questions.
+-- Before you start using the AI_AIR_DISPATCHER, ask yourself the following questions.
 -- 
 -- 
 -- ## 1. Which coalition am I modeling an AIR defense system for? blue or red?
@@ -128,7 +128,7 @@
 -- Depending on the defense type, different payloads will be needed. See further points on squadron definition.
 -- 
 -- 
--- ## 7. Where will the Squadrons be located? On Airbases? On Carrier Ships? On Farps?
+-- ## 7. Where will the Squadrons be located? On Airbases? On Carrier Ships? On FARPs?
 -- 
 -- Squadrons are placed at the **home base** on an **airfield**, **carrier** or **farp**.
 -- Carefully plan where each Squadron will be located as part of the defense system required for mission effective defenses.
@@ -354,7 +354,7 @@ do -- AI_AIR_DISPATCHER
   -- **DetectionSetGroup** is then calling `FilterStart()`, which is starting the dynamic filtering or inclusion of these groups. 
   -- Note that any destroy or new spawn of a group having a name, starting with the above prefix, will be removed or added to the set.
   -- 
-  -- Then a new detection object is created from the class `DETECTION_AREAS`. A grouping radius of 1000 meters (1km) is choosen.
+  -- Then a new detection object is created from the class `DETECTION_AREAS`. A grouping radius of 1000 meters (1km) is chosen.
   -- 
   -- The `Detection` object is then passed to the @{#AI_AIR_DISPATCHER.New}() method to indicate the reconnaissance network 
   -- configuration and setup the AIR defense detection mechanism.
@@ -647,7 +647,7 @@ do -- AI_AIR_DISPATCHER
   --   * @{#AI_AIR_DISPATCHER.SetSquadronLandingAtRunway}() will despawn the returning aircraft directly after landing at the runway.
   --   * @{#AI_AIR_DISPATCHER.SetSquadronLandingAtEngineShutdown}() will despawn the returning aircraft when the aircraft has returned to its parking spot and has turned off its engines.
   -- 
-  -- You can use these methods to minimize the airbase coodination overhead and to increase the airbase efficiency.
+  -- You can use these methods to minimize the airbase coordination overhead and to increase the airbase efficiency.
   -- When there are lots of aircraft returning for landing, at the same airbase, the takeoff process will be halted, which can cause a complete failure of the
   -- A2A defense system, as no new CAP or GCI planes can takeoff.
   -- Note that the method @{#AI_AIR_DISPATCHER.SetSquadronLandingNearAirbase}() will only work for returning aircraft, not for damaged or out of fuel aircraft.
@@ -724,13 +724,13 @@ do -- AI_AIR_DISPATCHER
   -- 
   -- Use the method @{#AI_AIR_DISPATCHER.SetSquadronEngageLimit}() to limit the amount of aircraft that will engage with the enemy, per squadron.
   --
-  -- ## 4. Set the **fuel treshold**.
+  -- ## 4. Set the **fuel threshold**.
   -- 
-  -- When aircraft get **out of fuel** to a certain %-tage, which is by default **15% (0.15)**, there are two possible actions that can be taken:
+  -- When aircraft get **out of fuel** to a certain %, which is by default **15% (0.15)**, there are two possible actions that can be taken:
   --  - The aircraft will go RTB, and will be replaced with a new aircraft if possible.
   --  - The aircraft will refuel at a tanker, if a tanker has been specified for the squadron.
   -- 
-  -- Use the method @{#AI_AIR_DISPATCHER.SetSquadronFuelThreshold}() to set the **squadron fuel treshold** of the aircraft for all squadrons.
+  -- Use the method @{#AI_AIR_DISPATCHER.SetSquadronFuelThreshold}() to set the **squadron fuel threshold** of the aircraft for all squadrons.
   -- 
   -- ## 6. Other configuration options
   -- 
@@ -786,17 +786,17 @@ do -- AI_AIR_DISPATCHER
   -- 
   -- Use the method @{#AI_AIR_DISPATCHER.SetDefaultGrouping}() to set the **default grouping** of spawned airplanes for all squadrons.
   -- 
-  -- ## 10.5. Default RTB fuel treshold.
+  -- ## 10.5. Default RTB fuel threshold.
   -- 
-  -- When an airplane gets **out of fuel** to a certain %-tage, which is **15% (0.15)**, it will go RTB, and will be replaced with a new airplane when applicable.
+  -- When an airplane gets **out of fuel** to a certain %, which is **15% (0.15)**, it will go RTB, and will be replaced with a new airplane when applicable.
   -- 
-  -- Use the method @{#AI_AIR_DISPATCHER.SetDefaultFuelThreshold}() to set the **default fuel treshold** of spawned airplanes for all squadrons.
+  -- Use the method @{#AI_AIR_DISPATCHER.SetDefaultFuelThreshold}() to set the **default fuel threshold** of spawned airplanes for all squadrons.
   -- 
-  -- ## 10.6. Default RTB damage treshold.
+  -- ## 10.6. Default RTB damage threshold.
   -- 
-  -- When an airplane is **damaged** to a certain %-tage, which is **40% (0.40)**, it will go RTB, and will be replaced with a new airplane when applicable.
+  -- When an airplane is **damaged** to a certain %, which is **40% (0.40)**, it will go RTB, and will be replaced with a new airplane when applicable.
   -- 
-  -- Use the method @{#AI_AIR_DISPATCHER.SetDefaultDamageThreshold}() to set the **default damage treshold** of spawned airplanes for all squadrons.
+  -- Use the method @{#AI_AIR_DISPATCHER.SetDefaultDamageThreshold}() to set the **default damage threshold** of spawned airplanes for all squadrons.
   -- 
   -- ## 10.7. Default settings for **patrol**.
   -- 
@@ -829,7 +829,7 @@ do -- AI_AIR_DISPATCHER
   -- 
   -- In the mission editor, setup a group with task Refuelling. A tanker unit of the correct coalition will be automatically selected.
   -- Then, use the method @{#AI_AIR_DISPATCHER.SetDefaultTanker}() to set the tanker for the dispatcher.
-  -- Use the method @{#AI_AIR_DISPATCHER.SetDefaultFuelThreshold}() to set the %-tage left in the defender airplane tanks when a refuel action is needed.
+  -- Use the method @{#AI_AIR_DISPATCHER.SetDefaultFuelThreshold}() to set the % left in the defender airplane tanks when a refuel action is needed.
   -- 
   -- When the tanker specified is alive and in the air, the tanker will be used for refuelling.
   -- 
@@ -843,7 +843,7 @@ do -- AI_AIR_DISPATCHER
   --      A2ADispatcher:SetSquadronCapInterval("Sochi", 2, 30, 600, 1 ) 
   --      A2ADispatcher:SetSquadronGci( "Sochi", 900, 1200 )
   --      
-  --      -- Set the default tanker for refuelling to "Tanker", when the default fuel treshold has reached 90% fuel left.
+  --      -- Set the default tanker for refuelling to "Tanker", when the default fuel threshold has reached 90% fuel left.
   --      A2ADispatcher:SetDefaultFuelThreshold( 0.9 )
   --      A2ADispatcher:SetDefaultTanker( "Tanker" )
   --  
@@ -883,9 +883,6 @@ do -- AI_AIR_DISPATCHER
   -- However, the squadron will still stay alive. Any airplane that is airborne will continue its operations until all airborne airplanes
   -- of the squadron will be destroyed. This to keep consistency of air operations not to confuse the players.
   --
-  -- 
-  -- 
-  -- 
   -- @field #AI_AIR_DISPATCHER
   AI_AIR_DISPATCHER = {
     ClassName = "AI_AIR_DISPATCHER",
@@ -949,7 +946,6 @@ do -- AI_AIR_DISPATCHER
   --- @field #AI_AIR_DISPATCHER.DefenseQueue DefenseQueue
   AI_AIR_DISPATCHER.DefenseQueue = {}
 
-  
   --- Defense approach types
   -- @type #AI_AIR_DISPATCHER.DefenseApproach
   AI_AIR_DISPATCHER.DefenseApproach = {
@@ -958,9 +954,9 @@ do -- AI_AIR_DISPATCHER
   }
 
   --- AI_AIR_DISPATCHER constructor.
-  -- This is defining the AIR DISPATCHER for one coaliton.
+  -- This is defining the AIR DISPATCHER for one coalition.
   -- The Dispatcher works with a @{Functional.Detection#DETECTION_BASE} object that is taking of the detection of targets using the EWR units.
-  -- The Detection object is polymorphic, depending on the type of detection object choosen, the detection will work differently.
+  -- The Detection object is polymorphic, depending on the type of detection object chosen, the detection will work differently.
   -- @param #AI_AIR_DISPATCHER self
   -- @param Functional.Detection#DETECTION_BASE Detection The DETECTION object that will detects targets using the the Early Warning Radar network.
   -- @return #AI_AIR_DISPATCHER self
@@ -977,7 +973,7 @@ do -- AI_AIR_DISPATCHER
   --     Detection = DETECTION_AREAS:New( DetectionSetGroup, 30000 )
   --
   --     -- Now Setup the AIR dispatcher, and initialize it using the Detection object.
-  --   AIRDispatcher = AI_AIR_DISPATCHER:New( Detection )  --   
+  --     AIRDispatcher = AI_AIR_DISPATCHER:New( Detection )
   --
   function AI_AIR_DISPATCHER:New( Detection )
 
@@ -1435,17 +1431,17 @@ do -- AI_AIR_DISPATCHER
   end  
 
 
-  --- Set the default damage treshold when defenders will RTB.
+  --- Set the default damage threshold when defenders will RTB.
-  -- The default damage treshold is by default set to 40%, which means that when the airplane is 40% damaged, it will go RTB.
+  -- The default damage threshold is by default set to 40%, which means that when the airplane is 40% damaged, it will go RTB.
   -- @param #AI_AIR_DISPATCHER self
-  -- @param #number DamageThreshold A decimal number between 0 and 1, that expresses the %-tage of the damage treshold before going RTB.
+  -- @param #number DamageThreshold A decimal number between 0 and 1, that expresses the % of the damage threshold before going RTB.
   -- @return #AI_AIR_DISPATCHER
   -- @usage
   -- 
   --   -- Now Setup the AIR dispatcher, and initialize it using the Detection object.
   --   AIRDispatcher = AI_AIR_DISPATCHER:New( Detection )  
   --   
-  --   -- Now Setup the default damage treshold.
+  --   -- Now Setup the default damage threshold.
   --   AIRDispatcher:SetDefaultDamageThreshold( 0.90 ) -- Go RTB when the airplane 90% damaged.
   --   
   function AI_AIR_DISPATCHER:SetDefaultDamageThreshold( DamageThreshold )
@@ -1989,7 +1985,7 @@ do -- AI_AIR_DISPATCHER
 
   --- Defines the default amount of extra planes that will take-off as part of the defense system.
   -- @param #AI_AIR_DISPATCHER self
-  -- @param #number Overhead The %-tage of Units that dispatching command will allocate to intercept in surplus of detected amount of units.
+  -- @param #number Overhead The % of Units that dispatching command will allocate to intercept in surplus of detected amount of units.
   -- The default overhead is 1, so equal balance. The @{#AI_AIR_DISPATCHER.SetOverhead}() method can be used to tweak the defense strength,
   -- taking into account the plane types of the squadron. For example, a MIG-31 with full long-distance AIR missiles payload, may still be less effective than a F-15C with short missiles...
   -- So in this case, one may want to use the Overhead method to allocate more defending planes as the amount of detected attacking planes.
@@ -2028,7 +2024,7 @@ do -- AI_AIR_DISPATCHER
   --- Defines the amount of extra planes that will take-off as part of the defense system.
   -- @param #AI_AIR_DISPATCHER self
   -- @param #string SquadronName The name of the squadron.
-  -- @param #number Overhead The %-tage of Units that dispatching command will allocate to intercept in surplus of detected amount of units.
+  -- @param #number Overhead The % of Units that dispatching command will allocate to intercept in surplus of detected amount of units.
   -- The default overhead is 1, so equal balance. The @{#AI_AIR_DISPATCHER.SetOverhead}() method can be used to tweak the defense strength,
   -- taking into account the plane types of the squadron. For example, a MIG-31 with full long-distance AIR missiles payload, may still be less effective than a F-15C with short missiles...
   -- So in this case, one may want to use the Overhead method to allocate more defending planes as the amount of detected attacking planes.
@@ -2068,7 +2064,7 @@ do -- AI_AIR_DISPATCHER
   --- Gets the overhead of planes as part of the defense system, in comparison with the attackers.
   -- @param #AI_AIR_DISPATCHER self
   -- @param #string SquadronName The name of the squadron.
-  -- @return #number The %-tage of Units that dispatching command will allocate to intercept in surplus of detected amount of units.
+  -- @return #number The % of Units that dispatching command will allocate to intercept in surplus of detected amount of units.
   -- The default overhead is 1, so equal balance. The @{#AI_AIR_DISPATCHER.SetOverhead}() method can be used to tweak the defense strength,
   -- taking into account the plane types of the squadron. For example, a MIG-31 with full long-distance AIR missiles payload, may still be less effective than a F-15C with short missiles...
   -- So in this case, one may want to use the Overhead method to allocate more defending planes as the amount of detected attacking planes.
@@ -2674,17 +2670,17 @@ do -- AI_AIR_DISPATCHER
     return self
   end
   
-  --- Set the default fuel treshold when defenders will RTB or Refuel in the air.
+  --- Set the default fuel threshold when defenders will RTB or Refuel in the air.
-  -- The fuel treshold is by default set to 15%, which means that an airplane will stay in the air until 15% of its fuel has been consumed.
+  -- The fuel threshold is by default set to 15%, which means that an airplane will stay in the air until 15% of its fuel has been consumed.
   -- @param #AI_AIR_DISPATCHER self
-  -- @param #number FuelThreshold A decimal number between 0 and 1, that expresses the %-tage of the treshold of fuel remaining in the tank when the plane will go RTB or Refuel.
+  -- @param #number FuelThreshold A decimal number between 0 and 1, that expresses the % of the threshold of fuel remaining in the tank when the plane will go RTB or Refuel.
   -- @return #AI_AIR_DISPATCHER
   -- @usage
   -- 
   --   -- Now Setup the AIR dispatcher, and initialize it using the Detection object.
   --   AIRDispatcher = AI_AIR_DISPATCHER:New( Detection )  
   --   
-  --   -- Now Setup the default fuel treshold.
+  --   -- Now Setup the default fuel threshold.
   --   AIRDispatcher:SetDefaultFuelThreshold( 0.30 ) -- Go RTB when only 30% of fuel remaining in the tank.
   --   
   function AI_AIR_DISPATCHER:SetDefaultFuelThreshold( FuelThreshold )
@@ -2695,18 +2691,18 @@ do -- AI_AIR_DISPATCHER
   end  
 
 
-  --- Set the fuel treshold for the squadron when defenders will RTB or Refuel in the air.
+  --- Set the fuel threshold for the squadron when defenders will RTB or Refuel in the air.
-  -- The fuel treshold is by default set to 15%, which means that an airplane will stay in the air until 15% of its fuel has been consumed.
+  -- The fuel threshold is by default set to 15%, which means that an airplane will stay in the air until 15% of its fuel has been consumed.
   -- @param #AI_AIR_DISPATCHER self
   -- @param #string SquadronName The name of the squadron.
-  -- @param #number FuelThreshold A decimal number between 0 and 1, that expresses the %-tage of the treshold of fuel remaining in the tank when the plane will go RTB or Refuel.
+  -- @param #number FuelThreshold A decimal number between 0 and 1, that expresses the % of the threshold of fuel remaining in the tank when the plane will go RTB or Refuel.
   -- @return #AI_AIR_DISPATCHER
   -- @usage
   -- 
   --   -- Now Setup the AIR dispatcher, and initialize it using the Detection object.
   --   AIRDispatcher = AI_AIR_DISPATCHER:New( Detection )  
   --   
-  --   -- Now Setup the default fuel treshold.
+  --   -- Now Setup the default fuel threshold.
   --   AIRDispatcher:SetSquadronRefuelThreshold( "SquadronName", 0.30 ) -- Go RTB when only 30% of fuel remaining in the tank.
   --   
   function AI_AIR_DISPATCHER:SetSquadronFuelThreshold( SquadronName, FuelThreshold )
@@ -2726,7 +2722,7 @@ do -- AI_AIR_DISPATCHER
   --   -- Now Setup the AIR dispatcher, and initialize it using the Detection object.
   --   AIRDispatcher = AI_AIR_DISPATCHER:New( Detection )  
   --   
-  --   -- Now Setup the default fuel treshold.
+  --   -- Now Setup the default fuel threshold.
   --   AIRDispatcher:SetDefaultFuelThreshold( 0.30 ) -- Go RTB when only 30% of fuel remaining in the tank.
   --   
   --   -- Now Setup the default tanker.
@@ -2749,7 +2745,7 @@ do -- AI_AIR_DISPATCHER
   --   -- Now Setup the AIR dispatcher, and initialize it using the Detection object.
   --   AIRDispatcher = AI_AIR_DISPATCHER:New( Detection )  
   --   
-  --   -- Now Setup the squadron fuel treshold.
+  --   -- Now Setup the squadron fuel threshold.
   --   AIRDispatcher:SetSquadronRefuelThreshold( "SquadronName", 0.30 ) -- Go RTB when only 30% of fuel remaining in the tank.
   --   
   --   -- Now Setup the squadron tanker.
@@ -2847,7 +2843,7 @@ do -- AI_AIR_DISPATCHER
   -- @param #AI_AIR_DISPATCHER self
   function AI_AIR_DISPATCHER:CountDefendersEngaged( AttackerDetection, AttackerCount )
 
-    -- First, count the active AIGroups Units, targetting the DetectedSet
+    -- First, count the active AIGroups Units, targeting the DetectedSet
     local DefendersEngaged = 0
     local DefendersTotal = 0
     

Moose Development/Moose/AI/AI_Air_Engage.lua

@@ -42,8 +42,8 @@
 -- 
 -- ![Process](..\Presentations\AI_GCI\Dia10.JPG)
 -- 
--- Until a fuel or damage treshold has been reached by the AI, or when the AI is commanded to RTB.
+-- Until a fuel or damage threshold has been reached by the AI, or when the AI is commanded to RTB.
--- When the fuel treshold has been reached, the airplane will fly towards the nearest friendly airbase and will land.
+-- When the fuel threshold has been reached, the airplane will fly towards the nearest friendly airbase and will land.
 -- 
 -- ![Process](..\Presentations\AI_GCI\Dia13.JPG)
 -- 

Moose Development/Moose/AI/AI_Air_Patrol.lua

@@ -39,8 +39,8 @@
 -- 
 -- ![Process](..\Presentations\AI_CAP\Dia10.JPG)
 -- 
--- Until a fuel or damage treshold has been reached by the AI, or when the AI is commanded to RTB.
+-- Until a fuel or damage threshold has been reached by the AI, or when the AI is commanded to RTB.
--- When the fuel treshold has been reached, the airplane will fly towards the nearest friendly airbase and will land.
+-- When the fuel threshold has been reached, the airplane will fly towards the nearest friendly airbase and will land.
 -- 
 -- ![Process](..\Presentations\AI_CAP\Dia13.JPG)
 -- 
@@ -70,7 +70,7 @@
 --   * **@{AI.AI_Patrol#AI_PATROL_ZONE.Detected}**: The AI has detected new targets.
 --   * **@{#AI_AIR_PATROL.Destroy}**: The AI has destroyed a bogey @{Wrapper.Unit}.
 --   * **@{#AI_AIR_PATROL.Destroyed}**: The AI has destroyed all bogeys @{Wrapper.Unit}s assigned in the CAS task.
---   * **Status** ( Group ): The AI is checking status (fuel and damage). When the tresholds have been reached, the AI will RTB.
+--   * **Status** ( Group ): The AI is checking status (fuel and damage). When the thresholds have been reached, the AI will RTB.
 --
 -- ## 3. Set the Range of Engagement
 -- 

Moose Development/Moose/AI/AI_BAI.lua

@@ -49,7 +49,7 @@
 -- Upon started, The AI will **Route** itself towards the random 3D point within a patrol zone, 
 -- using a random speed within the given altitude and speed limits.
 -- Upon arrival at the 3D point, a new random 3D point will be selected within the patrol zone using the given limits.
--- This cycle will continue until a fuel or damage treshold has been reached by the AI, or when the AI is commanded to RTB.
+-- This cycle will continue until a fuel or damage threshold has been reached by the AI, or when the AI is commanded to RTB.
 -- 
 -- ![Route Event](..\Presentations\AI_BAI\Dia5.JPG)
 -- 
@@ -87,7 +87,7 @@
 -- It will keep patrolling there, until it is notified to RTB or move to another BOMB Zone.
 -- It can be notified to go RTB through the **RTB** event.
 -- 
--- When the fuel treshold has been reached, the airplane will fly towards the nearest friendly airbase and will land.
+-- When the fuel threshold has been reached, the airplane will fly towards the nearest friendly airbase and will land.
 -- 
 -- ![Engage Event](..\Presentations\AI_BAI\Dia12.JPG)
 --
@@ -117,7 +117,7 @@
 --   * **@{AI.AI_Patrol#AI_PATROL_ZONE.Detected}**: The AI has detected new targets.
 --   * **@{#AI_BAI_ZONE.Destroy}**: The AI has destroyed a target @{Wrapper.Unit}.
 --   * **@{#AI_BAI_ZONE.Destroyed}**: The AI has destroyed all target @{Wrapper.Unit}s assigned in the BOMB task.
---   * **Status**: The AI is checking status (fuel and damage). When the tresholds have been reached, the AI will RTB.
+--   * **Status**: The AI is checking status (fuel and damage). When the thresholds have been reached, the AI will RTB.
 -- 
 -- ## 3. Modify the Engage Zone behaviour to pinpoint a **map object** or **scenery object**
 -- 
@@ -602,7 +602,7 @@ function AI_BAI_ZONE:onafterEngage( Controllable, From, Event, To,
 
     self:SetRefreshTimeInterval( 2 )
     self:SetDetectionActivated()
-    self:__Target( -2 ) -- Start Targetting
+    self:__Target( -2 ) -- Start targeting
   end
 end
 

Moose Development/Moose/AI/AI_CAP.lua

@@ -4,7 +4,7 @@
 -- 
 --   * Patrol AI airplanes within a given zone.
 --   * Trigger detected events when enemy airplanes are detected.
---   * Manage a fuel treshold to RTB on time.
+--   * Manage a fuel threshold to RTB on time.
 --   * Engage the enemy when detected.
 -- 
 --
@@ -65,8 +65,8 @@
 -- 
 -- ![Process](..\Presentations\AI_CAP\Dia10.JPG)
 -- 
--- Until a fuel or damage treshold has been reached by the AI, or when the AI is commanded to RTB.
+-- Until a fuel or damage threshold has been reached by the AI, or when the AI is commanded to RTB.
--- When the fuel treshold has been reached, the airplane will fly towards the nearest friendly airbase and will land.
+-- When the fuel threshold has been reached, the airplane will fly towards the nearest friendly airbase and will land.
 -- 
 -- ![Process](..\Presentations\AI_CAP\Dia13.JPG)
 -- 
@@ -96,7 +96,7 @@
 --   * **@{AI.AI_Patrol#AI_PATROL_ZONE.Detected}**: The AI has detected new targets.
 --   * **@{#AI_CAP_ZONE.Destroy}**: The AI has destroyed a bogey @{Wrapper.Unit}.
 --   * **@{#AI_CAP_ZONE.Destroyed}**: The AI has destroyed all bogeys @{Wrapper.Unit}s assigned in the CAS task.
---   * **Status** ( Group ): The AI is checking status (fuel and damage). When the tresholds have been reached, the AI will RTB.
+--   * **Status** ( Group ): The AI is checking status (fuel and damage). When the thresholds have been reached, the AI will RTB.
 --
 -- ## 3. Set the Range of Engagement
 -- 

Moose Development/Moose/AI/AI_CAS.lua

@@ -49,7 +49,7 @@
 -- Upon started, The AI will **Route** itself towards the random 3D point within a patrol zone, 
 -- using a random speed within the given altitude and speed limits.
 -- Upon arrival at the 3D point, a new random 3D point will be selected within the patrol zone using the given limits.
--- This cycle will continue until a fuel or damage treshold has been reached by the AI, or when the AI is commanded to RTB.
+-- This cycle will continue until a fuel or damage threshold has been reached by the AI, or when the AI is commanded to RTB.
 -- 
 -- ![Route Event](..\Presentations\AI_CAS\Dia5.JPG)
 -- 
@@ -87,7 +87,7 @@
 -- It will keep patrolling there, until it is notified to RTB or move to another CAS Zone.
 -- It can be notified to go RTB through the **RTB** event.
 -- 
--- When the fuel treshold has been reached, the airplane will fly towards the nearest friendly airbase and will land.
+-- When the fuel threshold has been reached, the airplane will fly towards the nearest friendly airbase and will land.
 -- 
 -- ![Engage Event](..\Presentations\AI_CAS\Dia12.JPG)
 --
@@ -117,7 +117,7 @@
 --   * **@{AI.AI_Patrol#AI_PATROL_ZONE.Detected}**: The AI has detected new targets.
 --   * **@{#AI_CAS_ZONE.Destroy}**: The AI has destroyed a target @{Wrapper.Unit}.
 --   * **@{#AI_CAS_ZONE.Destroyed}**: The AI has destroyed all target @{Wrapper.Unit}s assigned in the CAS task.
---   * **Status**: The AI is checking status (fuel and damage). When the tresholds have been reached, the AI will RTB.
+--   * **Status**: The AI is checking status (fuel and damage). When the thresholds have been reached, the AI will RTB.
 -- 
 -- ===
 -- 
@@ -520,7 +520,7 @@ function AI_CAS_ZONE:onafterEngage( Controllable, From, Event, To,
     
     self:SetRefreshTimeInterval( 2 )
     self:SetDetectionActivated()
-    self:__Target( -2 ) -- Start Targetting
+    self:__Target( -2 ) -- Start targeting
   end
 end
 

Moose Development/Moose/AI/AI_Patrol.lua

@@ -4,7 +4,7 @@
 -- 
 --   * Patrol AI airplanes within a given zone.
 --   * Trigger detected events when enemy airplanes are detected.
---   * Manage a fuel treshold to RTB on time.
+--   * Manage a fuel threshold to RTB on time.
 -- 
 -- ===
 -- 
@@ -72,8 +72,8 @@
 -- 
 -- ![Process](..\Presentations\AI_PATROL\Dia10.JPG)
 -- 
--- Until a fuel or damage treshold has been reached by the AI, or when the AI is commanded to RTB.
+-- Until a fuel or damage threshold has been reached by the AI, or when the AI is commanded to RTB.
--- When the fuel treshold has been reached, the airplane will fly towards the nearest friendly airbase and will land.
+-- When the fuel threshold has been reached, the airplane will fly towards the nearest friendly airbase and will land.
 -- 
 -- ![Process](..\Presentations\AI_PATROL\Dia11.JPG)
 -- 
@@ -101,7 +101,7 @@
 --   * **RTB** ( Group ): Route the AI to the home base.
 --   * **Detect** ( Group ): The AI is detecting targets.
 --   * **Detected** ( Group ): The AI has detected new targets.
---   * **Status** ( Group ): The AI is checking status (fuel and damage). When the tresholds have been reached, the AI will RTB.
+--   * **Status** ( Group ): The AI is checking status (fuel and damage). When the thresholds have been reached, the AI will RTB.
 --    
 -- ## 3. Set or Get the AI controllable
 -- 
@@ -133,8 +133,8 @@
 -- ## 6. Manage the "out of fuel" in the AI_PATROL_ZONE
 -- 
 -- When the AI is out of fuel, it is required that a new AI is started, before the old AI can return to the home base.
--- Therefore, with a parameter and a calculation of the distance to the home base, the fuel treshold is calculated.
+-- Therefore, with a parameter and a calculation of the distance to the home base, the fuel threshold is calculated.
--- When the fuel treshold is reached, the AI will continue for a given time its patrol task in orbit, 
+-- When the fuel threshold is reached, the AI will continue for a given time its patrol task in orbit, 
 -- while a new AI is targetted to the AI_PATROL_ZONE.
 -- Once the time is finished, the old AI will return to the base.
 -- Use the method @{#AI_PATROL_ZONE.ManageFuel}() to have this proces in place.
@@ -142,7 +142,7 @@
 -- ## 7. Manage "damage" behaviour of the AI in the AI_PATROL_ZONE
 -- 
 -- When the AI is damaged, it is required that a new AIControllable is started. However, damage cannon be foreseen early on. 
--- Therefore, when the damage treshold is reached, the AI will return immediately to the home base (RTB).
+-- Therefore, when the damage threshold is reached, the AI will return immediately to the home base (RTB).
 -- Use the method @{#AI_PATROL_ZONE.ManageDamage}() to have this proces in place.
 -- 
 -- ===
@@ -581,11 +581,11 @@ function AI_PATROL_ZONE:ClearDetectedUnits()
 end
 
 --- When the AI is out of fuel, it is required that a new AI is started, before the old AI can return to the home base.
--- Therefore, with a parameter and a calculation of the distance to the home base, the fuel treshold is calculated.
+-- Therefore, with a parameter and a calculation of the distance to the home base, the fuel threshold is calculated.
--- When the fuel treshold is reached, the AI will continue for a given time its patrol task in orbit, while a new AIControllable is targetted to the AI_PATROL_ZONE.
+-- When the fuel threshold is reached, the AI will continue for a given time its patrol task in orbit, while a new AIControllable is targetted to the AI_PATROL_ZONE.
 -- Once the time is finished, the old AI will return to the base.
 -- @param #AI_PATROL_ZONE self
--- @param #number PatrolFuelThresholdPercentage The treshold in percentage (between 0 and 1) when the AIControllable is considered to get out of fuel.
+-- @param #number PatrolFuelThresholdPercentage The threshold in percentage (between 0 and 1) when the AIControllable is considered to get out of fuel.
 -- @param #number PatrolOutOfFuelOrbitTime The amount of seconds the out of fuel AIControllable will orbit before returning to the base.
 -- @return #AI_PATROL_ZONE self
 function AI_PATROL_ZONE:ManageFuel( PatrolFuelThresholdPercentage, PatrolOutOfFuelOrbitTime )
@@ -596,14 +596,14 @@ function AI_PATROL_ZONE:ManageFuel( PatrolFuelThresholdPercentage, PatrolOutOfFu
   return self
 end
 
---- When the AI is damaged beyond a certain treshold, it is required that the AI returns to the home base.
+--- When the AI is damaged beyond a certain threshold, it is required that the AI returns to the home base.
 -- However, damage cannot be foreseen early on. 
--- Therefore, when the damage treshold is reached, 
+-- Therefore, when the damage threshold is reached, 
 -- the AI will return immediately to the home base (RTB).
 -- Note that for groups, the average damage of the complete group will be calculated.
--- So, in a group of 4 airplanes, 2 lost and 2 with damage 0.2, the damage treshold will be 0.25.
+-- So, in a group of 4 airplanes, 2 lost and 2 with damage 0.2, the damage threshold will be 0.25.
 -- @param #AI_PATROL_ZONE self
--- @param #number PatrolDamageThreshold The treshold in percentage (between 0 and 1) when the AI is considered to be damaged.
+-- @param #number PatrolDamageThreshold The threshold in percentage (between 0 and 1) when the AI is considered to be damaged.
 -- @return #AI_PATROL_ZONE self
 function AI_PATROL_ZONE:ManageDamage( PatrolDamageThreshold )
 

Moose Development/Moose/Cargo/Cargo.lua

@@ -194,7 +194,7 @@
 --    * is of type `Workmaterials`
 --    * will report when a carrier is within 500 meters
 --    * will board to carriers when the carrier is within 500 meters from the cargo object
---    * will dissapear when the cargo is within 25 meters from the carrier during boarding
+--    * will disappear when the cargo is within 25 meters from the carrier during boarding
 -- 
 -- So the overall syntax of the #CARGO naming tag and arguments are:
 -- 
@@ -220,7 +220,7 @@
 --    * is of type `Workmaterials`
 --    * will report when a carrier is within 500 meters
 --    * will board to carriers when the carrier is within 500 meters from the cargo object
---    * will dissapear when the cargo is within 25 meters from the carrier during boarding
+--    * will disappear when the cargo is within 25 meters from the carrier during boarding
 -- 
 -- So the overall syntax of the #CARGO naming tag and arguments are:
 -- 

Moose Development/Moose/Core/Database.lua

@@ -903,7 +903,7 @@ function DATABASE:_RegisterPlayers()
   return self
 end
 
---- Private method that registers all Groups and Units within in the mission.
+--- Private method that registers all Groups and Units within the mission.
 -- @param #DATABASE self
 -- @return #DATABASE self
 function DATABASE:_RegisterGroupsAndUnits()
@@ -944,7 +944,7 @@ function DATABASE:_RegisterGroupsAndUnits()
   return self
 end
 
---- Private method that registers all Units of skill Client or Player within in the mission.
+--- Private method that registers all Units of skill Client or Player within the mission.
 -- @param #DATABASE self
 -- @return #DATABASE self
 function DATABASE:_RegisterClients()
@@ -957,7 +957,8 @@ function DATABASE:_RegisterClients()
   return self
 end
 
---- @param #DATABASE self
+--- Private method that registers all Statics within the mission.
+-- @param #DATABASE self
 function DATABASE:_RegisterStatics()
 
   local CoalitionsData = { GroupsRed = coalition.getStaticObjects( coalition.side.RED ), GroupsBlue = coalition.getStaticObjects( coalition.side.BLUE ), GroupsNeutral = coalition.getStaticObjects( coalition.side.NEUTRAL ) }

Moose Development/Moose/Core/Event.lua

@@ -32,11 +32,11 @@
 --
 -- ![Objects](..\Presentations\EVENT\Dia5.JPG)
 --
--- There are 5 levels of kind of objects that the _EVENTDISPATCHER services:
+-- There are 5 types/levels of objects that the _EVENTDISPATCHER services:
 --
 --  * _DATABASE object: The core of the MOOSE objects. Any object that is created, deleted or updated, is done in this database.
---  * SET_ derived classes: Subsets of the _DATABASE object. These subsets are updated by the _EVENTDISPATCHER as the second priority.
+--  * SET_ derived classes: These are subsets of the _DATABASE object. These subsets are updated by the _EVENTDISPATCHER as the second priority.
---  * UNIT objects: UNIT objects can subscribe to DCS events. Each DCS event will be directly published to teh subscribed UNIT object.
+--  * UNIT objects: UNIT objects can subscribe to DCS events. Each DCS event will be directly published to the subscribed UNIT object.
 --  * GROUP objects: GROUP objects can subscribe to DCS events. Each DCS event will be directly published to the subscribed GROUP object.
 --  * Any other object: Various other objects can subscribe to DCS events. Each DCS event triggered will be published to each subscribed object.
 --
@@ -131,6 +131,8 @@
 --    * Weapon data: Certain events populate weapon information.
 --    * Place data: Certain events populate place information.
 --
+-- Example code snippet:
+--
 --      --- This function is an Event Handling function that will be called when Tank1 is Dead.
 --      -- EventData is an EVENTDATA structure.
 --      -- We use the EventData.IniUnit to smoke the tank Green.
@@ -150,6 +152,7 @@
 -- In case a STATIC object is involved, the documentation indicates which fields will and won't not be populated.
 -- The fields **IniObjectCategory** and **TgtObjectCategory** contain the indicator which **kind of object is involved** in the event.
 -- You can use the enumerator **Object.Category.UNIT** and **Object.Category.STATIC** to check on IniObjectCategory and TgtObjectCategory.
+--
 -- Example code snippet:
 --
 --      if Event.IniObjectCategory == Object.Category.UNIT then

Moose Development/Moose/Core/Fsm.lua

@@ -21,8 +21,8 @@
 -- A FSM can only be in one of a finite number of states.
 -- The machine is in only one state at a time; the state it is in at any given time is called the **current state**.
 -- It can change from one state to another when initiated by an **__internal__ or __external__ triggering event**, which is called a **transition**.
--- An **FSM implementation** is defined by **a list of its states**, **its initial state**, and **the triggering events** for **each possible transition**.
+-- A **FSM implementation** is defined by **a list of its states**, **its initial state**, and **the triggering events** for **each possible transition**.
--- An FSM implementation is composed out of **two parts**, a set of **state transition rules**, and an implementation set of **state transition handlers**, implementing those transitions.
+-- A FSM implementation is composed out of **two parts**, a set of **state transition rules**, and an implementation set of **state transition handlers**, implementing those transitions.
 --
 -- The FSM class supports a **hierarchical implementation of a Finite State Machine**,
 -- that is, it allows to **embed existing FSM implementations in a master FSM**.
@@ -34,21 +34,21 @@
 -- orders him to destroy x targets and account the results.
 -- Other examples of ready made FSM could be:
 --
---   * route a plane to a zone flown by a human
+--   * Route a plane to a zone flown by a human.
---   * detect targets by an AI and report to humans
+--   * Detect targets by an AI and report to humans.
---   * account for destroyed targets by human players
+--   * Account for destroyed targets by human players.
---   * handle AI infantry to deploy from or embark to a helicopter or airplane or vehicle 
+--   * Handle AI infantry to deploy from or embark to a helicopter or airplane or vehicle.
---   * let an AI patrol a zone
+--   * Let an AI patrol a zone.
 --
--- The **MOOSE framework** uses extensively the FSM class and derived FSM\_ classes,
+-- The **MOOSE framework** extensively uses the FSM class and derived FSM\_ classes,
 -- because **the goal of MOOSE is to simplify mission design complexity for mission building**.
 -- By efficiently utilizing the FSM class and derived classes, MOOSE allows mission designers to quickly build processes.
 -- **Ready made FSM-based implementations classes** exist within the MOOSE framework that **can easily be re-used,
 -- and tailored** by mission designers through **the implementation of Transition Handlers**.
 -- Each of these FSM implementation classes start either with:
 --
---   * an acronym **AI\_**, which indicates an FSM implementation directing **AI controlled** @{GROUP} and/or @{UNIT}. These AI\_ classes derive the @{#FSM_CONTROLLABLE} class.
+--   * an acronym **AI\_**, which indicates a FSM implementation directing **AI controlled** @{GROUP} and/or @{UNIT}. These AI\_ classes derive the @{#FSM_CONTROLLABLE} class.
---   * an acronym **TASK\_**, which indicates an FSM implementation executing a @{TASK} executed by Groups of players. These TASK\_ classes derive the @{#FSM_TASK} class.
+--   * an acronym **TASK\_**, which indicates a FSM implementation executing a @{TASK} executed by Groups of players. These TASK\_ classes derive the @{#FSM_TASK} class.
 --   * an acronym **ACT\_**, which indicates an Sub-FSM implementation, directing **Humans actions** that need to be done in a @{TASK}, seated in a @{CLIENT} (slot) or a @{UNIT} (CA join). These ACT\_ classes derive the @{#FSM_PROCESS} class.
 --
 -- Detailed explanations and API specifics are further below clarified and FSM derived class specifics are described in those class documentation sections.
@@ -59,7 +59,7 @@
 -- I've reworked this development (taken the concept), and created a **hierarchical state machine** out of it, embedded within the DCS simulator.
 -- Additionally, I've added extendability and created an API that allows seamless FSM implementation.
 --
--- The following derived classes are available in the MOOSE framework, that implement a specialised form of a FSM:
+-- The following derived classes are available in the MOOSE framework, that implement a specialized form of a FSM:
 --
 --   * @{#FSM_TASK}: Models Finite State Machines for @{Task}s.
 --   * @{#FSM_PROCESS}: Models Finite State Machines for @{Task} actions, which control @{Client}s.

Moose Development/Moose/Core/Menu.lua

@@ -778,7 +778,7 @@ end
 
 do
   -- This local variable is used to cache the menus registered under groups.
-  -- Menus don't dissapear when groups for players are destroyed and restarted.
+  -- Menus don't disappear when groups for players are destroyed and restarted.
   -- So every menu for a client created must be tracked so that program logic accidentally does not create.
   -- the same menus twice during initialization logic.
   -- These menu classes are handling this logic with this variable.

Moose Development/Moose/Core/Spawn.lua

@@ -1373,7 +1373,7 @@ function SPAWN:SpawnWithIndex( SpawnIndex, NoBirth )
           SpawnTemplate.modulation = self.SpawnInitModu
         end
 
-        -- Set country, coaliton and categroy.
+        -- Set country, coalition and category.
         SpawnTemplate.CategoryID = self.SpawnInitCategory or SpawnTemplate.CategoryID
         SpawnTemplate.CountryID = self.SpawnInitCountry or SpawnTemplate.CountryID
         SpawnTemplate.CoalitionID = self.SpawnInitCoalition or SpawnTemplate.CoalitionID
@@ -2360,7 +2360,7 @@ end
 -- The known AIRBASE objects are automatically imported at mission start by MOOSE.
 -- Therefore, there isn't any New() constructor defined for AIRBASE objects.
 --
--- Ships and Farps are added within the mission, and are therefore not known.
+-- Ships and FARPs are added within the mission, and are therefore not known.
 -- For these AIRBASE objects, there isn't an @{Wrapper.Airbase#AIRBASE} enumeration defined.
 -- You need to provide the **exact name** of the airbase as the parameter to the @{Wrapper.Airbase#AIRBASE.FindByName}() method!
 --

Moose Development/Moose/Core/Zone.lua

@@ -9,7 +9,7 @@
 --   * Create polygon zones.
 --   * Create moving zones around a unit.
 --   * Create moving zones around a group.
---   * Provide the zone behaviour. Some zones are static, while others are moveable.
+--   * Provide the zone behavior. Some zones are static, while others are moveable.
 --   * Enquiry if a coordinate is within a zone.
 --   * Smoke zones.
 --   * Set a zone probability to control zone selection.
@@ -20,10 +20,10 @@
 --   * Draw zones (circular and polygon) on the F10 map.
 --
 --
--- There are essentially two core functions that zones accomodate:
+-- There are essentially two core functions that zones accommodate:
 --
 --   * Test if an object is within the zone boundaries.
---   * Provide the zone behaviour. Some zones are static, while others are moveable.
+--   * Provide the zone behavior. Some zones are static, while others are moveable.
 --
 -- The object classes are using the zone classes to test the zone boundaries, which can take various forms:
 --
@@ -53,7 +53,6 @@
 -- @module Core.Zone
 -- @image Core_Zones.JPG
 
-
 --- @type ZONE_BASE
 -- @field #string ZoneName Name of the zone.
 -- @field #number ZoneProbability A value between 0 and 1. 0 = 0% and 1 = 100% probability.
@@ -61,7 +60,6 @@
 -- @field #table Color Table with four entries, e.g. {1, 0, 0, 0.15}. First three are RGB color code. Fourth is the transparency Alpha value.
 -- @extends Core.Fsm#FSM
 
-
 --- This class is an abstract BASE class for derived classes, and is not meant to be instantiated.
 --
 -- ## Each zone has a name:
@@ -108,10 +106,9 @@ ZONE_BASE = {
   ZoneName = "",
   ZoneProbability = 1,
   DrawID = nil,
-  Color={}
+  Color = {},
 }
 
-
 --- The ZONE_BASE.BoundingSquare
 -- @type ZONE_BASE.BoundingSquare
 -- @field DCS#Distance x1 The lower x coordinate (left down)
@@ -119,7 +116,6 @@ ZONE_BASE = {
 -- @field DCS#Distance x2 The higher x coordinate (right up)
 -- @field DCS#Distance y2 The higher y coordinate (right up)
 
-
 --- ZONE_BASE constructor
 -- @param #ZONE_BASE self
 -- @param #string ZoneName Name of the zone.
@@ -133,8 +129,6 @@ function ZONE_BASE:New( ZoneName )
   return self
 end
 
-
-
 --- Returns the name of the zone.
 -- @param #ZONE_BASE self
 -- @return #string The name of the zone.
@@ -144,7 +138,6 @@ function ZONE_BASE:GetName()
   return self.ZoneName
 end
 
-
 --- Sets the name of the zone.
 -- @param #ZONE_BASE self
 -- @param #string ZoneName The name of the zone.
@@ -201,7 +194,6 @@ function ZONE_BASE:IsPointVec3InZone( PointVec3 )
   return InZone
 end
 
-
 --- Returns the @{DCS#Vec2} coordinate of the zone.
 -- @param #ZONE_BASE self
 -- @return #nil.
@@ -225,7 +217,6 @@ function ZONE_BASE:GetPointVec2()
   return PointVec2
 end
 
-
 --- Returns the @{DCS#Vec3} of the zone.
 -- @param #ZONE_BASE self
 -- @param DCS#Distance Height The height to add to the land height where the center of the zone is located.
@@ -288,7 +279,6 @@ function ZONE_BASE:GetCoordinate( Height ) --R2.1
   return self.Coordinate
 end
 
-
 --- Define a random @{DCS#Vec2} within the zone.
 -- @param #ZONE_BASE self
 -- @return DCS#Vec2 The Vec2 coordinates.
@@ -325,7 +315,6 @@ function ZONE_BASE:BoundZone()
 
 end
 
-
 --- Set color of zone.
 -- @param #ZONE_BASE self
 -- @param #table RGBcolor RGB color table. Default `{1, 0, 0}`.
@@ -394,7 +383,6 @@ function ZONE_BASE:GetDrawID()
   return self.DrawID
 end
 
-
 --- Smokes the zone boundaries in a color.
 -- @param #ZONE_BASE self
 -- @param Utilities.Utils#SMOKECOLOR SmokeColor The smoke color.
@@ -459,7 +447,6 @@ function ZONE_BASE:GetZoneMaybe()
   end
 end
 
-
 --- The ZONE_RADIUS class, defined by a zone name, a location and a radius.
 -- @type ZONE_RADIUS
 -- @field DCS#Vec2 Vec2 The current location of the zone.
@@ -655,7 +642,6 @@ function ZONE_RADIUS:BoundZone( Points, CountryID, UnBound )
   return self
 end
 
-
 --- Smokes the zone boundaries in a color.
 -- @param #ZONE_RADIUS self
 -- @param Utilities.Utils#SMOKECOLOR SmokeColor The smoke color.
@@ -687,7 +673,6 @@ function ZONE_RADIUS:SmokeZone( SmokeColor, Points, AddHeight, AngleOffset )
   return self
 end
 
-
 --- Flares the zone boundaries in a color.
 -- @param #ZONE_RADIUS self
 -- @param Utilities.Utils#FLARECOLOR FlareColor The flare color.
@@ -784,10 +769,6 @@ function ZONE_RADIUS:GetVec3( Height )
   return Vec3
 end
 
-
-
-
-
 --- Scan the zone for the presence of units of the given ObjectCategories.
 -- Note that after a zone has been scanned, the zone can be evaluated by:
 --
@@ -820,7 +801,7 @@ function ZONE_RADIUS:Scan( ObjectCategories, UnitCategories )
     params = {
       point = ZoneCoord:GetVec3(),
       radius = ZoneRadius,
-      }
+    },
   }
 
   local function EvaluateZone( ZoneObject )
@@ -893,7 +874,6 @@ function ZONE_RADIUS:GetScannedUnits()
   return self.ScanData.Units
 end
 
-
 --- Get a set of scanned units.
 -- @param #ZONE_RADIUS self
 -- @return Core.Set#SET_UNIT Set of units and statics inside the zone.
@@ -947,7 +927,6 @@ function ZONE_RADIUS:GetScannedSetGroup()
   return self.ScanSetGroup
 end
 
-
 --- Count the number of different coalitions inside the zone.
 -- @param #ZONE_RADIUS self
 -- @return #number Counted coalitions.
@@ -1000,7 +979,6 @@ function ZONE_RADIUS:GetScannedCoalition( Coalition )
   end
 end
 
-
 --- Get scanned scenery type
 -- @param #ZONE_RADIUS self
 -- @return #table Table of DCS scenery type objects.
@@ -1008,7 +986,6 @@ function ZONE_RADIUS:GetScannedSceneryType( SceneryType )
   return self.ScanData.Scenery[SceneryType]
 end
 
-
 --- Get scanned scenery table
 -- @param #ZONE_RADIUS self
 -- @return #table Table of DCS scenery objects.
@@ -1016,9 +993,8 @@ function ZONE_RADIUS:GetScannedScenery()
   return self.ScanData.Scenery
 end
 
-
 --- Is All in Zone of Coalition?
--- Check if only the specifed coalition is inside the zone and noone else.
+-- Check if only the specified coalition is inside the zone and noone else.
 -- @param #ZONE_RADIUS self
 -- @param #number Coalition Coalition ID of the coalition which is checked to be the only one in the zone.
 -- @return #boolean True, if **only** that coalition is inside the zone and no one else.
@@ -1031,7 +1007,6 @@ function ZONE_RADIUS:IsAllInZoneOfCoalition( Coalition )
   return self:CountScannedCoalitions() == 1 and self:GetScannedCoalition( Coalition ) == true
 end
 
-
 --- Is All in Zone of Other Coalition?
 -- Check if only one coalition is inside the zone and the specified coalition is not the one.
 -- You first need to use the @{#ZONE_RADIUS.Scan} method to scan the zone before it can be evaluated!
@@ -1048,23 +1023,23 @@ function ZONE_RADIUS:IsAllInZoneOfOtherCoalition( Coalition )
   return self:CountScannedCoalitions() == 1 and self:GetScannedCoalition( Coalition ) == nil
 end
 
-
 --- Is Some in Zone of Coalition?
--- Check if more than one coaltion is inside the zone and the specifed coalition is one of them.
+-- Check if more than one coalition is inside the zone and the specified coalition is one of them.
 -- You first need to use the @{#ZONE_RADIUS.Scan} method to scan the zone before it can be evaluated!
 -- Note that once a zone has been scanned, multiple evaluations can be done on the scan result set.
 -- @param #ZONE_RADIUS self
--- @param #number Coalition ID of the coaliton which is checked to be inside the zone.
+-- @param #number Coalition ID of the coalition which is checked to be inside the zone.
 -- @return #boolean True if more than one coalition is inside the zone and the specified coalition is one of them.
 -- @usage
+--
 --    self.Zone:Scan()
 --    local IsAttacked = self.Zone:IsSomeInZoneOfCoalition( self.Coalition )
+--
 function ZONE_RADIUS:IsSomeInZoneOfCoalition( Coalition )
 
   return self:CountScannedCoalitions() > 1 and self:GetScannedCoalition( Coalition ) == true
 end
 
-
 --- Is None in Zone of Coalition?
 -- You first need to use the @{#ZONE_RADIUS.Scan} method to scan the zone before it can be evaluated!
 -- Note that once a zone has been scanned, multiple evaluations can be done on the scan result set.
@@ -1072,30 +1047,30 @@ end
 -- @param Coalition
 -- @return #boolean
 -- @usage
+--
 --    self.Zone:Scan()
 --    local IsOccupied = self.Zone:IsNoneInZoneOfCoalition( self.Coalition )
+--
 function ZONE_RADIUS:IsNoneInZoneOfCoalition( Coalition )
 
   return self:GetScannedCoalition( Coalition ) == nil
 end
 
-
 --- Is None in Zone?
 -- You first need to use the @{#ZONE_RADIUS.Scan} method to scan the zone before it can be evaluated!
 -- Note that once a zone has been scanned, multiple evaluations can be done on the scan result set.
 -- @param #ZONE_RADIUS self
 -- @return #boolean
 -- @usage
+--
 --    self.Zone:Scan()
 --    local IsEmpty = self.Zone:IsNoneInZone()
+--
 function ZONE_RADIUS:IsNoneInZone()
 
   return self:CountScannedCoalitions() == 0
 end
 
-
-
-
 --- Searches the zone
 -- @param #ZONE_RADIUS self
 -- @param ObjectCategories A list of categories, which are members of Object.Category
@@ -1114,12 +1089,11 @@ function ZONE_RADIUS:SearchZone( EvaluateFunction, ObjectCategories )
       params = {
         point = ZoneCoord:GetVec3(),
         radius = ZoneRadius / 2,
-      }
+      },
     }
 
   local function EvaluateZone( ZoneDCSUnit )
 
-
     local ZoneUnit = UNIT:Find( ZoneDCSUnit )
 
     return EvaluateFunction( ZoneUnit )
@@ -1211,7 +1185,6 @@ function ZONE_RADIUS:GetRandomVec3( inner, outer )
   return { x = Vec2.x, y = self.y, z = Vec2.y }
 end
 
-
 --- Returns a @{Core.Point#POINT_VEC3} object reflecting a random 3D location within the zone.
 -- @param #ZONE_RADIUS self
 -- @param #number inner (optional) Minimal distance from the center of the zone. Default is 0.
@@ -1227,7 +1200,6 @@ function ZONE_RADIUS:GetRandomPointVec3( inner, outer )
   return PointVec3
 end
 
-
 --- Returns a @{Core.Point#COORDINATE} object reflecting a random 3D location within the zone.
 -- @param #ZONE_RADIUS self
 -- @param #number inner (optional) Minimal distance from the center of the zone. Default is 0.
@@ -1243,12 +1215,9 @@ function ZONE_RADIUS:GetRandomCoordinate( inner, outer )
   return Coordinate
 end
 
-
-
 --- @type ZONE
 -- @extends #ZONE_RADIUS
 
-
 --- The ZONE class, defined by the zone name as defined within the Mission Editor.
 -- This class implements the inherited functions from @{#ZONE_RADIUS} taking into account the own zone format and properties.
 --
@@ -1281,7 +1250,6 @@ ZONE = {
   ClassName = "ZONE",
 }
 
-
 --- Constructor of ZONE taking the zone name.
 -- @param #ZONE self
 -- @param #string ZoneName The name of the zone as defined within the mission editor.
@@ -1328,13 +1296,10 @@ function ZONE:FindByName( ZoneName )
   return ZoneFound
 end
 
-
-
 --- @type ZONE_UNIT
 -- @field Wrapper.Unit#UNIT ZoneUNIT
 -- @extends Core.Zone#ZONE_RADIUS
 
-
 --- # ZONE_UNIT class, extends @{Zone#ZONE_RADIUS}
 --
 -- The ZONE_UNIT class defined by a zone attached to a @{Wrapper.Unit#UNIT} with a radius and optional offsets.
@@ -1386,7 +1351,6 @@ function ZONE_UNIT:New( ZoneName, ZoneUNIT, Radius, Offset)
   return self
 end
 
-
 --- Returns the current location of the @{Wrapper.Unit#UNIT}.
 -- @param #ZONE_UNIT self
 -- @return DCS#Vec2 The location of the zone based on the @{Wrapper.Unit#UNIT}location and the offset, if any.
@@ -1473,7 +1437,6 @@ end
 --- @type ZONE_GROUP
 -- @extends #ZONE_RADIUS
 
-
 --- The ZONE_GROUP class defines by a zone around a @{Wrapper.Group#GROUP} with a radius. The current leader of the group defines the center of the zone.
 -- This class implements the inherited functions from @{Core.Zone#ZONE_RADIUS} taking into account the own zone format and properties.
 --
@@ -1501,7 +1464,6 @@ function ZONE_GROUP:New( ZoneName, ZoneGROUP, Radius )
   return self
 end
 
-
 --- Returns the current location of the @{Wrapper.Group}.
 -- @param #ZONE_GROUP self
 -- @return DCS#Vec2 The location of the zone based on the @{Wrapper.Group} location.
@@ -1555,12 +1517,10 @@ function ZONE_GROUP:GetRandomPointVec2( inner, outer )
   return PointVec2
 end
 
-
 --- @type ZONE_POLYGON_BASE
 -- --@field #ZONE_POLYGON_BASE.ListVec2 Polygon The polygon defined by an array of @{DCS#Vec2}.
 -- @extends #ZONE_BASE
 
-
 --- The ZONE_POLYGON_BASE class defined by a sequence of @{Wrapper.Group#GROUP} waypoints within the Mission Editor, forming a polygon.
 -- This class implements the inherited functions from @{Core.Zone#ZONE_RADIUS} taking into account the own zone format and properties.
 -- This class is an abstract BASE class for derived classes, and is not meant to be instantiated.
@@ -1698,7 +1658,6 @@ function ZONE_POLYGON_BASE:GetVertexCoordinate(Index)
   return nil
 end
 
-
 --- Get a list of verticies of the polygon.
 -- @param #ZONE_POLYGON_BASE self
 -- @return <DCS#Vec2> List of DCS#Vec2 verticies defining the edges of the polygon.
@@ -1794,7 +1753,6 @@ function ZONE_POLYGON_BASE:BoundZone( UnBound )
   return self
 end
 
-
 --- Draw the zone on the F10 map.  **NOTE** Currently, only polygons with **exactly four points** are supported!
 -- @param #ZONE_POLYGON_BASE self
 -- @param #number Coalition Coalition: All=-1, Neutral=0, Red=1, Blue=2. Default -1=All.
@@ -1814,7 +1772,6 @@ function ZONE_POLYGON_BASE:DrawZone(Coalition, Color, Alpha, FillColor, FillAlph
   FillColor = FillColor or Color
   FillAlpha = FillAlpha or self:GetColorAlpha()
 
-
   if #self._.Polygon == 4 then
 
     local Coord2 = COORDINATE:NewFromVec2( self._.Polygon[2] )
@@ -1832,7 +1789,6 @@ function ZONE_POLYGON_BASE:DrawZone(Coalition, Color, Alpha, FillColor, FillAlph
 
   end
 
-
   return self
 end
 
@@ -1867,7 +1823,6 @@ function ZONE_POLYGON_BASE:SmokeZone( SmokeColor, Segments )
   return self
 end
 
-
 --- Flare the zone boundaries in a color.
 -- @param #ZONE_POLYGON_BASE self
 -- @param Utilities.Utils#FLARECOLOR FlareColor The flare color.
@@ -1903,9 +1858,6 @@ function ZONE_POLYGON_BASE:FlareZone( FlareColor, Segments, Azimuth, AddHeight )
   return self
 end
 
-
-
-
 --- Returns if a location is within the zone.
 -- Source learned and taken from: https://www.ecse.rpi.edu/Homepages/wrf/Research/Short_Notes/pnpoly.html
 -- @param #ZONE_POLYGON_BASE self
@@ -1924,8 +1876,7 @@ function ZONE_POLYGON_BASE:IsVec2InZone( Vec2 )
   while Next <= #self._.Polygon do
     self:T( { Next, Prev, self._.Polygon[Next], self._.Polygon[Prev] } )
     if (((self._.Polygon[Next].y > Vec2.y) ~= (self._.Polygon[Prev].y > Vec2.y)) and
-         ( Vec2.x < ( self._.Polygon[Prev].x - self._.Polygon[Next].x ) * ( Vec2.y - self._.Polygon[Next].y ) / ( self._.Polygon[Prev].y - self._.Polygon[Next].y ) + self._.Polygon[Next].x )
+        (Vec2.x < (self._.Polygon[Prev].x - self._.Polygon[Next].x) * (Vec2.y - self._.Polygon[Next].y) / (self._.Polygon[Prev].y - self._.Polygon[Next].y) + self._.Polygon[Next].x)) then
-       ) then
       InPolygon = not InPolygon
     end
     self:T2( { InPolygon = InPolygon } )
@@ -1989,7 +1940,6 @@ function ZONE_POLYGON_BASE:GetRandomPointVec3()
   return PointVec3
 end
 
-
 --- Return a @{Core.Point#COORDINATE} object representing a random 3D point at landheight within the zone.
 -- @param #ZONE_POLYGON_BASE self
 -- @return Core.Point#COORDINATE
@@ -2003,7 +1953,6 @@ function ZONE_POLYGON_BASE:GetRandomCoordinate()
   return Coordinate
 end
 
-
 --- Get the bounding square the zone.
 -- @param #ZONE_POLYGON_BASE self
 -- @return #ZONE_POLYGON_BASE.BoundingSquare The bounding square.
@@ -2069,7 +2018,6 @@ end
 --- @type ZONE_POLYGON
 -- @extends #ZONE_POLYGON_BASE
 
-
 --- The ZONE_POLYGON class defined by a sequence of @{Wrapper.Group#GROUP} waypoints within the Mission Editor, forming a polygon.
 -- This class implements the inherited functions from @{Core.Zone#ZONE_RADIUS} taking into account the own zone format and properties.
 --
@@ -2117,7 +2065,6 @@ function ZONE_POLYGON:New( ZoneName, ZoneGroup )
   return self
 end
 
-
 --- Constructor to create a ZONE_POLYGON instance, taking the zone name and the **name** of the @{Wrapper.Group#GROUP} defined within the Mission Editor.
 -- The @{Wrapper.Group#GROUP} waypoints define the polygon corners. The first and the last point are automatically connected by ZONE_POLYGON.
 -- @param #ZONE_POLYGON self
@@ -2138,7 +2085,6 @@ function ZONE_POLYGON:NewFromGroupName( GroupName )
   return self
 end
 
-
 --- Find a polygon zone in the _DATABASE using the name of the polygon zone.
 -- @param #ZONE_POLYGON self
 -- @param #string ZoneName The name of the polygon zone.
@@ -2154,7 +2100,6 @@ do -- ZONE_AIRBASE
   --- @type ZONE_AIRBASE
   -- @extends #ZONE_RADIUS
 
-
   --- The ZONE_AIRBASE class defines by a zone around a @{Wrapper.Airbase#AIRBASE} with a radius.
   -- This class implements the inherited functions from @{Core.Zone#ZONE_RADIUS} taking into account the own zone format and properties.
   --
@@ -2163,8 +2108,6 @@ do -- ZONE_AIRBASE
     ClassName = "ZONE_AIRBASE",
   }
 
-
-
   --- Constructor to create a ZONE_AIRBASE instance, taking the zone name, a zone @{Wrapper.Airbase#AIRBASE} and a radius.
   -- @param #ZONE_AIRBASE self
   -- @param #string AirbaseName Name of the airbase.
@@ -2247,5 +2190,4 @@ do -- ZONE_AIRBASE
     return PointVec2
   end
 
-
 end

Moose Development/Moose/Functional/Artillery.lua

@@ -73,7 +73,7 @@
 -- @field Core.Point#COORDINATE RearmingPlaceCoord Coordinates of the rearming place. If the place is more than 100 m away from the ARTY group, the group will go there.
 -- @field #boolean RearmingArtyOnRoad If true, ARTY group will move to rearming place using mainly roads. Default false.
 -- @field Core.Point#COORDINATE InitialCoord Initial coordinates of the ARTY group.
--- @field #boolean report Arty group sends messages about their current state or target to its coaliton.
+-- @field #boolean report Arty group sends messages about their current state or target to its coalition.
 -- @field #table ammoshells Table holding names of the shell types which are included when counting the ammo. Default is {"weapons.shells"} which include most shells.
 -- @field #table ammorockets Table holding names of the rocket types which are included when counting the ammo. Default is {"weapons.nurs"} which includes most unguided rockets.
 -- @field #table ammomissiles Table holding names of the missile types which are included when counting the ammo. Default is {"weapons.missiles"} which includes some guided missiles.

Moose Development/Moose/Functional/RAT.lua

@@ -69,7 +69,7 @@
 -- @field #string category Category of aircarft: "plane" or "heli".
 -- @field #number groupsize Number of aircraft in group.
 -- @field #string friendly Possible departure/destination airport: all=blue+red+neutral, same=spawn+neutral, spawnonly=spawn, blue=blue+neutral, blueonly=blue, red=red+neutral, redonly=red.
--- @field #table ctable Table with the valid coalitons from choice self.friendly.
+-- @field #table ctable Table with the valid coalitions from choice self.friendly.
 -- @field #table aircraft Table which holds the basic aircraft properties (speed, range, ...).
 -- @field #number Vcruisemax Max cruise speed in m/s (250 m/s = 900 km/h = 486 kt) set by user.
 -- @field #number Vclimb Default climb rate in ft/min.
@@ -348,7 +348,7 @@ RAT={
   category = nil,           -- Category of aircarft: "plane" or "heli".
   groupsize=nil,            -- Number of aircraft in the group.
   friendly = "same",        -- Possible departure/destination airport: same=spawn+neutral, spawnonly=spawn, blue=blue+neutral, blueonly=blue, red=red+neutral, redonly=red, neutral.
-  ctable = {},              -- Table with the valid coalitons from choice self.friendly.
+  ctable = {},              -- Table with the valid coalitions from choice self.friendly.
   aircraft = {},            -- Table which holds the basic aircraft properties (speed, range, ...).
   Vcruisemax=nil,           -- Max cruise speed in set by user.
   Vclimb=1500,              -- Default climb rate in ft/min.
@@ -657,7 +657,7 @@ end
 -- @param #RAT self
 -- @param #number naircraft (Optional) Number of aircraft to spawn. Default is one aircraft.
 -- @return #boolean True if spawning was successful or nil if nothing was spawned.
--- @usage yak:Spawn(5) will spawn five aircraft. By default aircraft will spawn at neutral and red airports if the template group is part of the red coaliton.
+-- @usage yak:Spawn(5) will spawn five aircraft. By default aircraft will spawn at neutral and red airports if the template group is part of the red coalition.
 function RAT:Spawn(naircraft)
 
   -- Make sure that this function is only been called once per RAT object.

Moose Development/Moose/Functional/Warehouse.lua

@@ -50,7 +50,7 @@
 -- @field #boolean Report If true, send status messages to coalition.
 -- @field Wrapper.Static#STATIC warehouse The phyical warehouse structure.
 -- @field #string alias Alias of the warehouse. Name its called when sending messages.
--- @field Core.Zone#ZONE zone Zone around the warehouse. If this zone is captured, the warehouse and all its assets goes to the capturing coaliton.
+-- @field Core.Zone#ZONE zone Zone around the warehouse. If this zone is captured, the warehouse and all its assets goes to the capturing coalition.
 -- @field Wrapper.Airbase#AIRBASE airbase Airbase the warehouse belongs to.
 -- @field #string airbasename Name of the airbase associated to the warehouse.
 -- @field Core.Point#COORDINATE road Closest point to warehouse on road.
@@ -764,7 +764,7 @@
 --     warehouseBatumi:Load("D:\\My Warehouse Data\\")
 --     warehouseBatumi:Start()
 --
--- This sequence loads all assets from file. If a warehouse was captured in the last mission, it also respawns the static warehouse structure with the right coaliton.
+-- This sequence loads all assets from file. If a warehouse was captured in the last mission, it also respawns the static warehouse structure with the right coalition.
 -- However, it due to DCS limitations it is not possible to set the airbase coalition. This has to be done manually in the mission editor. Or alternatively, one could
 -- spawn some ground units via a self request and let them capture the airbase.
 --
@@ -1811,7 +1811,7 @@ WAREHOUSE.version="1.0.2"
 -- DONE: Add shipping lanes between warehouses.
 -- DONE: Handle cases with immobile units <== should be handled by dispatcher classes.
 -- DONE: Handle cases for aircraft carriers and other ships. Place warehouse on carrier possible? On others probably not - exclude them?
--- DONE: Add general message function for sending to coaliton or debug.
+-- DONE: Add general message function for sending to coalition or debug.
 -- DONE: Fine tune event handlers.
 -- DONE: Improve generalized attributes.
 -- DONE: If warehouse is destroyed, all asssets are gone.
@@ -3155,7 +3155,7 @@ end
 -- @param MinAssets (Optional) Minimum number of assets the warehouse should have. Default 0.
 -- @param #string Descriptor (Optional) Descriptor describing the selected assets which should be in stock. See @{#WAREHOUSE.Descriptor} for possible values.
 -- @param DescriptorValue (Optional) Descriptor value selecting the type of assets which should be in stock.
--- @param DCS#Coalition.side Coalition (Optional) Coalition side of the warehouse. Default is the same coaliton as the present warehouse. Set to false for any coalition.
+-- @param DCS#Coalition.side Coalition (Optional) Coalition side of the warehouse. Default is the same coalition as the present warehouse. Set to false for any coalition.
 -- @param Core.Point#COORDINATE RefCoordinate (Optional) Coordinate to which the closest warehouse is searched. Default is the warehouse calling this function.
 -- @return #WAREHOUSE The the nearest warehouse object. Or nil if no warehouse is found.
 -- @return #number The distance to the nearest warehouse in meters. Or nil if no warehouse is found.
@@ -3267,7 +3267,7 @@ function WAREHOUSE:onafterStart(From, Event, To)
 
   -- Short info.
   local text=string.format("Starting warehouse %s alias %s:\n",self.warehouse:GetName(), self.alias)
-  text=text..string.format("Coaliton = %s\n", self:GetCoalitionName())
+  text=text..string.format("Coalition = %s\n", self:GetCoalitionName())
   text=text..string.format("Country  = %s\n", self:GetCountryName())
   text=text..string.format("Airbase  = %s (category=%d)\n", self:GetAirbaseName(), self:GetAirbaseCategory())
   env.info(text)
@@ -8460,7 +8460,7 @@ function WAREHOUSE:_GetStockAssetsText(messagetoall)
 end
 
 --- Create or update mark text at warehouse, which is displayed in F10 map showing how many assets of each type are in stock.
--- Only the coaliton of the warehouse owner is able to see it.
+-- Only the coalition of the warehouse owner is able to see it.
 -- @param #WAREHOUSE self
 -- @return #string Text about warehouse stock
 function WAREHOUSE:_UpdateWarehouseMarkText()

Moose Development/Moose/Functional/ZoneCaptureCoalition.lua

@@ -804,7 +804,7 @@ do -- ZONE_CAPTURE_COALITION
     return IsEmpty
   end
 
-  --- Check if zone is "Guarded", i.e. only one (the defending) coaliton is present inside the zone.
+  --- Check if zone is "Guarded", i.e. only one (the defending) coalition is present inside the zone.
   -- @param #ZONE_CAPTURE_COALITION self
   -- @return #boolean self:IsAllInZoneOfCoalition( self.Coalition )
   function ZONE_CAPTURE_COALITION:IsGuarded()
@@ -826,7 +826,7 @@ do -- ZONE_CAPTURE_COALITION
     return IsCaptured
   end
   
-  --- Check if zone is "Attacked", i.e. another coaliton entered the zone.
+  --- Check if zone is "Attacked", i.e. another coalition entered the zone.
   -- @param #ZONE_CAPTURE_COALITION self
   -- @return #boolean self:IsSomeInZoneOfCoalition( self.Coalition )
   function ZONE_CAPTURE_COALITION:IsAttacked()
@@ -906,7 +906,6 @@ do -- ZONE_CAPTURE_COALITION
 -- Misc Functions
 -------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
 
-  
   --- Update Mark on F10 map.
   -- @param #ZONE_CAPTURE_COALITION self
   function ZONE_CAPTURE_COALITION:Mark()
@@ -925,7 +924,7 @@ do -- ZONE_CAPTURE_COALITION
         Coord:RemoveMark(self.MarkBlue)
       end
 
-      -- Create new marks for each coaliton.
+      -- Create new marks for each coalition.
       if self.Coalition == coalition.side.BLUE then
         self.MarkBlue = Coord:MarkToCoalitionBlue( "Coalition: Blue\nGuard Zone: " .. ZoneName .. "\nStatus: " .. State )
         self.MarkRed  = Coord:MarkToCoalitionRed(  "Coalition: Blue\nCapture Zone: " .. ZoneName .. "\nStatus: " .. State )

Moose Development/Moose/Functional/ZoneGoalCoalition.lua

@@ -24,7 +24,6 @@ do -- ZoneGoal
   -- @field #table ObjectCategories Table of object categories that are able to hold a zone. Default is UNITS and STATICS.
   -- @extends Functional.ZoneGoal#ZONE_GOAL
 
-
   --- ZONE_GOAL_COALITION models processes that have a Goal with a defined achievement involving a Zone for a Coalition.
   -- Derived classes implement the ways how the achievements can be realized.
   --
@@ -44,7 +43,7 @@ do -- ZoneGoal
   ZONE_GOAL_COALITION = {
     ClassName = "ZONE_GOAL_COALITION",
     Coalition = nil,
-    PreviousCoaliton = nil,
+    PreviousCoalition = nil,
     UnitCategories = nil,
     ObjectCategories = nil,
   }
@@ -61,7 +60,7 @@ do -- ZoneGoal
   function ZONE_GOAL_COALITION:New( Zone, Coalition, UnitCategories )
 
     if not Zone then
-      BASE:E("ERROR: No Zone specified in ZONE_GOAL_COALITON!")
+      BASE:E( "ERROR: No Zone specified in ZONE_GOAL_COALITION!" )
       return nil
     end
 
@@ -79,7 +78,6 @@ do -- ZoneGoal
     return self
   end
 
-
   --- Set the owning coalition of the zone.
   -- @param #ZONE_GOAL_COALITION self
   -- @param DCSCoalition.DCSCoalition#coalition Coalition The coalition ID, e.g. *coalition.side.RED*.
@@ -127,14 +125,13 @@ do -- ZoneGoal
     return self.Coalition
   end
 
-  --- Get the previous coaliton, i.e. the one owning the zone before the current one. 
+  --- Get the previous coalition, i.e. the one owning the zone before the current one. 
   -- @param #ZONE_GOAL_COALITION self
   -- @return DCSCoalition.DCSCoalition#coalition Coalition.
   function ZONE_GOAL_COALITION:GetPreviousCoalition()
     return self.PreviousCoalition
   end
 
-  
   --- Get the owning coalition name of the zone.
   -- @param #ZONE_GOAL_COALITION self
   -- @return #string Coalition name.
@@ -142,7 +139,6 @@ do -- ZoneGoal
     return UTILS.GetCoalitionName( self.Coalition )
   end
 
-
   --- Check status Coalition ownership.
   -- @param #ZONE_GOAL_COALITION self
   -- @return #ZONE_GOAL_COALITION

Moose Development/Moose/Ops/Airboss.lua

@@ -6058,7 +6058,7 @@ function AIRBOSS:_RefuelAI( flight )
     -- Guide AI to divert field --
     ------------------------------
 
-    -- Closest Airfield of the coaliton.
+    -- 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.

Moose Development/Moose/Tasking/Mission.lua

@@ -132,7 +132,7 @@ MISSION = {
 -- @param #string MissionName Name of the mission. This name will be used to reference the status of each mission by the players.
 -- @param #string MissionPriority String indicating the "priority" of the Mission. e.g. "Primary", "Secondary". It is free format and up to the Mission designer to choose. There are no rules behind this field.
 -- @param #string MissionBriefing String indicating the mission briefing to be shown when a player joins a @{CLIENT}.
--- @param DCS#coaliton.side MissionCoalition Side of the coalition, i.e. and enumerator @{#DCS.coalition.side} corresponding to RED, BLUE or NEUTRAL.
+-- @param DCS#coalition.side MissionCoalition Side of the coalition, i.e. and enumerator @{#DCS.coalition.side} corresponding to RED, BLUE or NEUTRAL.
 -- @return #MISSION self
 function MISSION:New( CommandCenter, MissionName, MissionPriority, MissionBriefing, MissionCoalition )
 

Moose Development/Moose/Tasking/Task.lua

@@ -82,7 +82,7 @@
 -- 
 -- ![Mission](../Tasking/Report_Statistics_Progress.JPG)
 -- 
--- A statistic report on the progress of the mission. Each task achievement will increase the %-tage to 100% as a goal to complete the task.
+-- A statistic report on the progress of the mission. Each task achievement will increase the % to 100% as a goal to complete the task.
 -- 
 -- ## 1.3) Join a Task.
 -- 

Moose Development/Moose/Utilities/Utils.lua

@@ -1353,7 +1353,7 @@ function UTILS.CheckMemory( output )
   return mem
 end
 
---- Get the coalition name from its numerical ID, e.g. coaliton.side.RED.
+--- Get the coalition name from its numerical ID, e.g. coalition.side.RED.
 -- @param #number Coalition The coalition ID.
 -- @return #string The coalition name, i.e. "Neutral", "Red" or "Blue" (or "Unknown").
 function UTILS.GetCoalitionName( Coalition )

Moose Development/Moose/Wrapper/Controllable.lua

@@ -11,14 +11,11 @@
 -- @module Wrapper.Controllable
 -- @image Wrapper_Controllable.JPG
 
-
 --- @type CONTROLLABLE
 -- @field DCS#Controllable DCSControllable The DCS controllable class.
 -- @field #string ControllableName The name of the controllable.
 -- @extends Wrapper.Positionable#POSITIONABLE
 
-
-
 --- Wrapper class to handle the "DCS Controllable objects", which are Groups and Units:
 --
 --  * Support all DCS Controllable APIs.
@@ -62,10 +59,10 @@
 --   * @{#CONTROLLABLE.TaskHoldPosition}: (AIR) Hold position at the current position of the first unit of the controllable.
 --   * @{#CONTROLLABLE.TaskLand}: (AIR HELICOPTER) Landing at the ground. For helicopters only.
 --   * @{#CONTROLLABLE.TaskLandAtZone}: (AIR) Land the controllable at a @{Core.Zone#ZONE_RADIUS).
---   * @{#CONTROLLABLE.TaskOrbitCircle}: (AIR) Orbit at the current position of the first unit of the controllable at a specified alititude.
+--   * @{#CONTROLLABLE.TaskOrbitCircle}: (AIR) Orbit at the current position of the first unit of the controllable at a specified altitude.
---   * @{#CONTROLLABLE.TaskOrbitCircleAtVec2}: (AIR) Orbit at a specified position at a specified alititude during a specified duration with a specified speed.
+--   * @{#CONTROLLABLE.TaskOrbitCircleAtVec2}: (AIR) Orbit at a specified position at a specified altitude during a specified duration with a specified speed.
 --   * @{#CONTROLLABLE.TaskRefueling}: (AIR) Refueling from the nearest tanker. No parameters.
---   * @{#CONTROLLABLE.TaskRoute}: (AIR + GROUND) Return a Misson task to follow a given route defined by Points.
+--   * @{#CONTROLLABLE.TaskRoute}: (AIR + GROUND) Return a Mission task to follow a given route defined by Points.
 --   * @{#CONTROLLABLE.TaskRouteToVec2}: (AIR + GROUND) Make the Controllable move to a given point.
 --   * @{#CONTROLLABLE.TaskRouteToVec3}: (AIR + GROUND) Make the Controllable move to a given point.
 --   * @{#CONTROLLABLE.TaskRouteToZone}: (AIR + GROUND) Route the controllable to a given zone.
@@ -86,7 +83,7 @@
 --
 -- ## 2.3) Task preparation
 --
--- There are certain task methods that allow to tailor the task behaviour:
+-- There are certain task methods that allow to tailor the task behavior:
 --
 --   * @{#CONTROLLABLE.TaskWrappedAction}: Return a WrappedAction Task taking a Command.
 --   * @{#CONTROLLABLE.TaskCombo}: Return a Combo Task taking an array of Tasks.
@@ -133,7 +130,7 @@
 --
 -- # 5) Option methods
 --
--- Controllable **Option methods** change the behaviour of the Controllable while being alive.
+-- Controllable **Option methods** change the behavior of the Controllable while being alive.
 --
 -- ## 5.1) Rule of Engagement:
 --
@@ -215,7 +212,6 @@ end
 
 -- Get methods
 
-
 --- Returns the health. Dead controllables have health <= 1.0.
 -- @param #CONTROLLABLE self
 -- @return #number The controllable health value (unit or group average).
@@ -274,7 +270,7 @@ function CONTROLLABLE:GetLife0()
 end
 
 --- Returns relative minimum amount of fuel (from 0.0 to 1.0) a unit or group has in its internal tanks.
--- This method returns nil to ensure polymorphic behaviour! This method needs to be overridden by GROUP or UNIT.
+-- This method returns nil to ensure polymorphic behavior! This method needs to be overridden by GROUP or UNIT.
 -- @param #CONTROLLABLE self
 -- @return #nil The CONTROLLABLE is not existing or alive.
 function CONTROLLABLE:GetFuelMin()
@@ -284,7 +280,7 @@ function CONTROLLABLE:GetFuelMin()
 end
 
 --- Returns relative average amount of fuel (from 0.0 to 1.0) a unit or group has in its internal tanks.
--- This method returns nil to ensure polymorphic behaviour! This method needs to be overridden by GROUP or UNIT.
+-- This method returns nil to ensure polymorphic behavior! This method needs to be overridden by GROUP or UNIT.
 -- @param #CONTROLLABLE self
 -- @return #nil The CONTROLLABLE is not existing or alive.
 function CONTROLLABLE:GetFuelAve()
@@ -294,7 +290,7 @@ function CONTROLLABLE:GetFuelAve()
 end
 
 --- Returns relative amount of fuel (from 0.0 to 1.0) the unit has in its internal tanks.
--- This method returns nil to ensure polymorphic behaviour! This method needs to be overridden by GROUP or UNIT.
+-- This method returns nil to ensure polymorphic behavior! This method needs to be overridden by GROUP or UNIT.
 -- @param #CONTROLLABLE self
 -- @return #nil The CONTROLLABLE is not existing or alive.
 function CONTROLLABLE:GetFuel()
@@ -302,7 +298,6 @@ function CONTROLLABLE:GetFuel()
   return nil
 end
 
-
 -- Tasks
 
 --- Clear all tasks from the controllable.
@@ -321,7 +316,6 @@ function CONTROLLABLE:ClearTasks()
   return nil
 end
 
-
 --- Popping current Task from the controllable.
 -- @param #CONTROLLABLE self
 -- @return Wrapper.Controllable#CONTROLLABLE self
@@ -440,7 +434,6 @@ function CONTROLLABLE:HasTask() --R2.2
   return HasTaskResult
 end
 
-
 --- Return a condition section for a controlled task.
 -- @param #CONTROLLABLE self
 -- @param DCS#Time time DCS mission time.
@@ -485,8 +478,8 @@ function CONTROLLABLE:TaskControlled( DCSTask, DCSStopCondition )
     id = 'ControlledTask',
     params = {
       task = DCSTask,
-      stopCondition = DCSStopCondition
+      stopCondition = DCSStopCondition,
-    }
+    },
   }
 
   return DCSTaskControlled
@@ -501,8 +494,8 @@ function CONTROLLABLE:TaskCombo( DCSTasks )
   local DCSTaskCombo = {
     id = 'ComboTask',
     params = {
-      tasks = DCSTasks
+      tasks = DCSTasks,
-    }
+    },
   }
 
   return DCSTaskCombo
@@ -540,9 +533,6 @@ function CONTROLLABLE:SetTaskWaypoint( Waypoint, Task )
   return Waypoint.task
 end
 
-
-
-
 --- Executes a command action for the CONTROLLABLE.
 -- @param #CONTROLLABLE self
 -- @param DCS#Command DCSCommand The command to be executed.
@@ -567,10 +557,11 @@ end
 -- @param #number ToWayPoint
 -- @return DCS#Task
 -- @usage
--- --- This test demonstrates the use(s) of the SwitchWayPoint method of the GROUP class.
+--
+--   -- This test demonstrates the use(s) of the SwitchWayPoint method of the GROUP class.
 --   HeliGroup = GROUP:FindByName( "Helicopter" )
 --
--- --- Route the helicopter back to the FARP after 60 seconds.
+--   -- Route the helicopter back to the FARP after 60 seconds.
 --   -- We use the SCHEDULER class to do this.
 --   SCHEDULER:New( nil,
 --     function( HeliGroup )
@@ -619,7 +610,6 @@ function CONTROLLABLE:CommandStopRoute( StopRoute )
   return CommandStopRoute
 end
 
-
 --- Give an uncontrolled air controllable the start command.
 -- @param #CONTROLLABLE self
 -- @param #number delay (Optional) Delay before start command in seconds.
@@ -640,7 +630,7 @@ end
 -- @param Core.Radio#BEACON.Type Type Beacon type (VOR, DME, TACAN, RSBN, ILS etc).
 -- @param Core.Radio#BEACON.System System Beacon system (VOR, DME, TACAN, RSBN, ILS etc).
 -- @param #number Frequency Frequency in Hz the beacon is running on. Use @{#UTILS.TACANToFrequency} to generate a frequency for TACAN beacons.
--- @param #number UnitID The ID of the unit the beacon is attached to. Usefull if more units are in one group.
+-- @param #number UnitID The ID of the unit the beacon is attached to. Useful if more units are in one group.
 -- @param #number Channel Channel the beacon is using. For, e.g. TACAN beacons.
 -- @param #string ModeChannel The TACAN mode of the beacon, i.e. "X" or "Y".
 -- @param #boolean AA If true, create and Air-Air beacon. IF nil, automatically set if CONTROLLABLE depending on whether unit is and aircraft or not.
@@ -666,7 +656,7 @@ function CONTROLLABLE:CommandActivateBeacon(Type, System, Frequency, UnitID, Cha
       ["AA"] = AA,
       ["callsign"] = Callsign,
       ["bearing"] = Bearing,
-    }
+    },
   }
 
   if Delay and Delay > 0 then
@@ -695,7 +685,7 @@ function CONTROLLABLE:CommandActivateICLS(Channel, UnitID, Callsign, Delay)
       ["channel"] = Channel,
       ["unitId"] = UnitID,
       ["callsign"] = Callsign,
-    }
+    },
   }
 
   if Delay and Delay > 0 then
@@ -707,7 +697,6 @@ function CONTROLLABLE:CommandActivateICLS(Channel, UnitID, Callsign, Delay)
   return self
 end
 
-
 --- Deactivate the active beacon of the CONTROLLABLE.
 -- @param #CONTROLLABLE self
 -- @param #number Delay (Optional) Delay in seconds before the beacon is deactivated.
@@ -780,8 +769,8 @@ function CONTROLLABLE:CommandEPLRS(SwitchOnOff, Delay)
     id = 'EPLRS',
     params = {
       value = SwitchOnOff,
-      groupId=self:GetID()
+      groupId = self:GetID(),
-    }
+    },
   }
 
   if Delay and Delay > 0 then
@@ -798,7 +787,7 @@ end
 -- @param #CONTROLLABLE self
 -- @param #number Frequency Radio frequency in MHz.
 -- @param #number Modulation Radio modulation. Default `radio.modulation.AM`.
--- @param #number Delay (Optional) Delay in seconds before the frequncy is set. Default is immediately.
+-- @param #number Delay (Optional) Delay in seconds before the frequency is set. Default is immediately.
 -- @return #CONTROLLABLE self
 function CONTROLLABLE:CommandSetFrequency( Frequency, Modulation, Delay )
 
@@ -807,7 +796,7 @@ function CONTROLLABLE:CommandSetFrequency(Frequency, Modulation, Delay)
     params = {
       frequency = Frequency * 1000000,
       modulation = Modulation or radio.modulation.AM,
-    }
+    },
   }
 
   if Delay and Delay > 0 then
@@ -819,7 +808,6 @@ function CONTROLLABLE:CommandSetFrequency(Frequency, Modulation, Delay)
   return self
 end
 
-
 --- Set EPLRS data link on/off.
 -- @param #CONTROLLABLE self
 -- @param #boolean SwitchOnOff If true (or nil) switch EPLRS on. If false switch off.
@@ -836,14 +824,13 @@ function CONTROLLABLE:TaskEPLRS(SwitchOnOff, idx)
     id = 'EPLRS',
     params = {
       value = SwitchOnOff,
-      groupId=self:GetID()
+      groupId = self:GetID(),
-    }
+    },
   }
 
   return self:TaskWrappedAction( CommandEPLRS, idx or 1 )
 end
 
-
 -- TASKS FOR AIR CONTROLLABLES
 
 --- (AIR) Attack a Controllable.
@@ -851,7 +838,7 @@ end
 -- @param Wrapper.Group#GROUP AttackGroup The Group to be attacked.
 -- @param #number WeaponType (optional) Bitmask of weapon types those allowed to use. If parameter is not defined that means no limits on weapon usage.
 -- @param DCS#AI.Task.WeaponExpend WeaponExpend (optional) Determines how much weapon will be released at each attack. If parameter is not defined the unit / controllable will choose expend on its own discretion.
--- @param #number AttackQty (optional) This parameter limits maximal quantity of attack. The aicraft/controllable will not make more attack than allowed even if the target controllable not destroyed and the aicraft/controllable still have ammo. If not defined the aircraft/controllable will attack target until it will be destroyed or until the aircraft/controllable will run out of ammo.
+-- @param #number AttackQty (optional) This parameter limits maximal quantity of attack. The aircraft/controllable will not make more attack than allowed even if the target controllable not destroyed and the aircraft/controllable still have ammo. If not defined the aircraft/controllable will attack target until it will be destroyed or until the aircraft/controllable will run out of ammo.
 -- @param DCS#Azimuth Direction (optional) Desired ingress direction from the target to the attacking aircraft. Controllable/aircraft will make its attacks from the direction. Of course if there is no way to attack from the direction due the terrain controllable/aircraft will choose another direction.
 -- @param DCS#Distance Altitude (optional) Desired attack start altitude. Controllable/aircraft will make its attacks from the altitude. If the altitude is too low or too high to use weapon aircraft/controllable will choose closest altitude to the desired attack start altitude. If the desired altitude is defined controllable/aircraft will not attack from safe altitude.
 -- @param #boolean AttackQtyLimit (optional) The flag determines how to interpret attackQty parameter. If the flag is true then attackQty is a limit on maximal attack quantity for "AttackGroup" and "AttackUnit" tasks. If the flag is false then attackQty is a desired attack quantity for "Bombing" and "BombingRunway" tasks.
@@ -899,7 +886,7 @@ end
 -- @param Wrapper.Unit#UNIT AttackUnit The UNIT to be attacked
 -- @param #boolean GroupAttack (Optional) If true, all units in the group will attack the Unit when found. Default false.
 -- @param DCS#AI.Task.WeaponExpend WeaponExpend (Optional) Determines how many weapons will be released at each attack. If parameter is not defined the unit / controllable will choose expend on its own discretion.
--- @param #number AttackQty (Optional) Limits maximal quantity of attack. The aicraft/controllable will not make more attacks than allowed even if the target controllable not destroyed and the aicraft/controllable still have ammo. If not defined the aircraft/controllable will attack target until it will be destroyed or until the aircraft/controllable will run out of ammo.
+-- @param #number AttackQty (Optional) Limits maximal quantity of attack. The aircraft/controllable will not make more attacks than allowed even if the target controllable not destroyed and the aircraft/controllable still have ammo. If not defined the aircraft/controllable will attack target until it will be destroyed or until the aircraft/controllable will run out of ammo.
 -- @param DCS#Azimuth Direction (Optional) Desired ingress direction from the target to the attacking aircraft. Controllable/aircraft will make its attacks from the direction.
 -- @param #number Altitude (Optional) The (minimum) altitude in meters from where to attack. Default is altitude of unit to attack but at least 1000 m.
 -- @param #number WeaponType (optional) The WeaponType. See [DCS Enumerator Weapon Type](https://wiki.hoggitworld.com/view/DCS_enum_weapon_flag) on Hoggit.
@@ -919,19 +906,18 @@ function CONTROLLABLE:TaskAttackUnit(AttackUnit, GroupAttack, WeaponExpend, Atta
       attackQtyLimit   = AttackQty and true or false,
       attackQty        = AttackQty,
       weaponType       = WeaponType or 1073741822,
-    }
+    },
   }
 
   return DCSTask
 end
 
-
 --- (AIR) Delivering weapon at the point on the ground.
 -- @param #CONTROLLABLE self
 -- @param DCS#Vec2 Vec2 2D-coordinates of the point to deliver weapon at.
 -- @param #boolean GroupAttack (optional) If true, all units in the group will attack the Unit when found.
 -- @param DCS#AI.Task.WeaponExpend WeaponExpend (optional) Determines how much weapon will be released at each attack. If parameter is not defined the unit / controllable will choose expend on its own discretion.
--- @param #number AttackQty (optional) This parameter limits maximal quantity of attack. The aicraft/controllable will not make more attack than allowed even if the target controllable not destroyed and the aicraft/controllable still have ammo. If not defined the aircraft/controllable will attack target until it will be destroyed or until the aircraft/controllable will run out of ammo.
+-- @param #number AttackQty (optional) This parameter limits maximal quantity of attack. The aircraft/controllable will not make more attack than allowed even if the target controllable not destroyed and the aircraft/controllable still have ammo. If not defined the aircraft/controllable will attack target until it will be destroyed or until the aircraft/controllable will run out of ammo.
 -- @param DCS#Azimuth Direction (optional) Desired ingress direction from the target to the attacking aircraft. Controllable/aircraft will make its attacks from the direction. Of course if there is no way to attack from the direction due the terrain controllable/aircraft will choose another direction.
 -- @param #number Altitude (optional) The altitude from where to attack.
 -- @param #number WeaponType (optional) The WeaponType.
@@ -966,7 +952,7 @@ end
 -- @param DCS#Vec2 Vec2 2D-coordinates of the point to deliver weapon at.
 -- @param #boolean GroupAttack (Optional) If true, all units in the group will attack the Unit when found.
 -- @param DCS#AI.Task.WeaponExpend WeaponExpend (Optional) Determines how much weapon will be released at each attack. If parameter is not defined the unit will choose expend on its own discretion.
--- @param #number AttackQty (Optional) This parameter limits maximal quantity of attack. The aicraft/controllable will not make more attack than allowed even if the target controllable not destroyed and the aicraft/controllable still have ammo. If not defined the aircraft/controllable will attack target until it will be destroyed or until the aircraft/controllable will run out of ammo.
+-- @param #number AttackQty (Optional) This parameter limits maximal quantity of attack. The aircraft/controllable will not make more attack than allowed even if the target controllable not destroyed and the aircraft/controllable still have ammo. If not defined the aircraft/controllable will attack target until it will be destroyed or until the aircraft/controllable will run out of ammo.
 -- @param DCS#Azimuth Direction (Optional) Desired ingress direction from the target to the attacking aircraft. Controllable/aircraft will make its attacks from the direction. Of course if there is no way to attack from the direction due the terrain controllable/aircraft will choose another direction.
 -- @param #number Altitude (Optional) The altitude [meters] from where to attack. Default 30 m.
 -- @param #number WeaponType (Optional) The WeaponType. Default Auto=1073741822.
@@ -994,13 +980,12 @@ function CONTROLLABLE:TaskAttackMapObject( Vec2, GroupAttack, WeaponExpend, Atta
   return DCSTask
 end
 
-
 --- (AIR) Delivering weapon via CarpetBombing (all bombers in formation release at same time) at the point on the ground.
 -- @param #CONTROLLABLE self
 -- @param DCS#Vec2 Vec2 2D-coordinates of the point to deliver weapon at.
 -- @param #boolean GroupAttack (optional) If true, all units in the group will attack the Unit when found.
 -- @param DCS#AI.Task.WeaponExpend WeaponExpend (optional) Determines how much weapon will be released at each attack. If parameter is not defined the unit will choose expend on its own discretion.
--- @param #number AttackQty (optional) This parameter limits maximal quantity of attack. The aicraft/controllable will not make more attack than allowed even if the target controllable not destroyed and the aicraft/controllable still have ammo. If not defined the aircraft/controllable will attack target until it will be destroyed or until the aircraft/controllable will run out of ammo.
+-- @param #number AttackQty (optional) This parameter limits maximal quantity of attack. The aircraft/controllable will not make more attack than allowed even if the target controllable not destroyed and the aircraft/controllable still have ammo. If not defined the aircraft/controllable will attack target until it will be destroyed or until the aircraft/controllable will run out of ammo.
 -- @param DCS#Azimuth Direction (optional) Desired ingress direction from the target to the attacking aircraft. Controllable/aircraft will make its attacks from the direction. Of course if there is no way to attack from the direction due the terrain controllable/aircraft will choose another direction.
 -- @param #number Altitude (optional) The altitude from where to attack.
 -- @param #number WeaponType (optional) The WeaponType.
@@ -1025,14 +1010,12 @@ function CONTROLLABLE:TaskCarpetBombing(Vec2, GroupAttack, WeaponExpend, AttackQ
       direction        = Direction and math.rad(Direction) or 0,
       altitudeEnabled  = Altitude and true or false,
       altitude         = Altitude,
-      }
+    },
   }
 
   return DCSTask
 end
 
-
-
 --- (AIR) Following another airborne controllable.
 -- The unit / controllable will follow lead unit of another controllable, wingmens of both controllables will continue following their leaders.
 -- Used to support CarpetBombing Task
@@ -1049,14 +1032,13 @@ function CONTROLLABLE:TaskFollowBigFormation(FollowControllable, Vec3, LastWaypo
       groupId          = FollowControllable:GetID(),
       pos              = Vec3,
       lastWptIndexFlag = LastWaypointIndex and true or false,
-      lastWptIndex     = LastWaypointIndex
+      lastWptIndex     = LastWaypointIndex,
-    }
+    },
   }
 
   return DCSTask
 end
 
-
 --- (AIR HELICOPTER) Move the controllable to a Vec2 Point, wait for a defined duration and embark infantry groups.
 -- @param #CONTROLLABLE self
 -- @param Core.Point#COORDINATE Coordinate The point where to pickup the troops.
@@ -1099,13 +1081,12 @@ function CONTROLLABLE:TaskEmbarking(Coordinate, GroupSetForEmbarking, Duration,
       duration           = Duration,
       distributionFlag   = Distribution and true or false,
       distribution       = Distribution,
-    }
+    },
   }
 
   return DCSTask
 end
 
-
 --- Used in conjunction with the embarking task for a transport helicopter group. The Ground units will move to the specified location and wait to be picked up by a helicopter.
 -- The helicopter will then fly them to their dropoff point defined by another task for the ground forces; DisembarkFromTransport task.
 -- The controllable has to be an infantry group!
@@ -1123,13 +1104,12 @@ function CONTROLLABLE:TaskEmbarkToTransport(Coordinate, Radius, UnitType)
        y            = Coordinate.z,
        zoneRadius   = Radius or 200,
        selectedType = UnitType,
-     }
+     },
    }
 
   return EmbarkToTransport
 end
 
-
 --- Specifies the location infantry groups that is being transported by helicopters will be unloaded at. Used in conjunction with the EmbarkToTransport task.
 -- @param #CONTROLLABLE self
 -- @param Core.Point#COORDINATE Coordinate Coordinates where AI is expecting to be picked up.
@@ -1155,14 +1135,13 @@ function CONTROLLABLE:TaskDisembarking(Coordinate, GroupSetToDisembark)
       x = Coordinate.x,
       y = Coordinate.z,
       groupsForEmbarking = g4e, -- This is no bug, the entry is really "groupsForEmbarking" even if we disembark the troops.
-    }
+    },
   }
 
   return Disembarking
 end
 
-
+--- (AIR) Orbit at a specified position at a specified altitude during a specified duration with a specified speed.
---- (AIR) Orbit at a specified position at a specified alititude during a specified duration with a specified speed.
 -- @param #CONTROLLABLE self
 -- @param DCS#Vec2 Point The point to hold the position.
 -- @param #number Altitude The altitude AGL in meters to hold the position.
@@ -1177,8 +1156,8 @@ function CONTROLLABLE:TaskOrbitCircleAtVec2( Point, Altitude, Speed )
       pattern  = AI.Task.OrbitPattern.CIRCLE,
       point    = Point,
       speed    = Speed,
-      altitude = Altitude + land.getHeight( Point )
+      altitude = Altitude + land.getHeight( Point ),
-    }
+    },
   }
 
   return DCSTask
@@ -1210,13 +1189,13 @@ function CONTROLLABLE:TaskOrbit(Coord, Altitude, Speed, CoordRaceTrack)
       point2   = P2,
       speed    = Speed or UTILS.KnotsToMps(250),
       altitude = Altitude or Coord.y,
-    }
+    },
   }
 
   return Task
 end
 
---- (AIR) Orbit at the current position of the first unit of the controllable at a specified alititude.
+--- (AIR) Orbit at the current position of the first unit of the controllable at a specified altitude.
 -- @param #CONTROLLABLE self
 -- @param #number Altitude The altitude [m] to hold the position.
 -- @param #number Speed The speed [m/s] flying when holding the position.
@@ -1235,8 +1214,6 @@ function CONTROLLABLE:TaskOrbitCircle( Altitude, Speed, Coordinate )
   return nil
 end
 
-
-
 --- (AIR) Hold position at the current position of the first unit of the controllable.
 -- @param #CONTROLLABLE self
 -- @param #number Duration The maximum duration in seconds to hold the position.
@@ -1247,7 +1224,6 @@ function CONTROLLABLE:TaskHoldPosition()
   return self:TaskOrbitCircle( 30, 10 )
 end
 
-
 --- (AIR) Delivering weapon on the runway. See [hoggit](https://wiki.hoggitworld.com/view/DCS_task_bombingRunway)
 --
 -- Make sure the aircraft has the following role:
@@ -1284,7 +1260,6 @@ function CONTROLLABLE:TaskBombingRunway(Airbase, WeaponType, WeaponExpend, Attac
   return DCSTask
 end
 
-
 --- (AIR) Refueling from the nearest tanker. No parameters.
 -- @param #CONTROLLABLE self
 -- @return DCS#Task The DCS task structure.
@@ -1292,13 +1267,12 @@ function CONTROLLABLE:TaskRefueling()
 
   local DCSTask = {
     id = 'Refueling',
-    params={}
+    params = {},
   }
 
   return DCSTask
 end
 
-
 --- (AIR HELICOPTER) Landing at the ground. For helicopters only.
 -- @param #CONTROLLABLE self
 -- @param DCS#Vec2 Vec2 The point where to land.
@@ -1333,8 +1307,6 @@ function CONTROLLABLE:TaskLandAtZone( Zone, Duration, RandomPoint )
   return DCSTask
 end
 
-
-
 --- (AIR) Following another airborne controllable.
 -- The unit / controllable will follow lead unit of another controllable, wingmens of both controllables will continue following their leaders.
 -- If another controllable is on land the unit / controllable will orbit around.
@@ -1371,14 +1343,13 @@ function CONTROLLABLE:TaskFollow( FollowControllable, Vec3, LastWaypointIndex )
       lastWptIndexFlag                = LastWaypointIndexFlag,
       lastWptIndex                    = LastWaypointIndex,
       lastWptIndexFlagChangedManually = lastWptIndexFlagChangedManually,
-    }
+    },
   }
 
   self:T3( { DCSTask } )
   return DCSTask
 end
 
-
 --- (AIR) Escort another airborne controllable.
 -- The unit / controllable will follow lead unit of another controllable, wingmens of both controllables will continue following their leaders.
 -- The unit / controllable will also protect that controllable from threats of specified types.
@@ -1419,7 +1390,6 @@ function CONTROLLABLE:TaskEscort( FollowControllable, Vec3, LastWaypointIndex, E
   return DCSTask
 end
 
-
 -- GROUND TASKS
 
 --- (GROUND) Fire at a VEC2 point until ammunition is finished.
@@ -1443,8 +1413,8 @@ function CONTROLLABLE:TaskFireAtPoint( Vec2, Radius, AmmoCount, WeaponType, Alti
       radius           = Radius,
       expendQty        = 100, -- dummy value
       expendQtyEnabled = false,
-      alt_type         = ASL and 0 or 1
+      alt_type         = ASL and 0 or 1,
-    }
+    },
   }
 
   if AmmoCount then
@@ -1473,7 +1443,6 @@ function CONTROLLABLE:TaskHold()
   return DCSTask
 end
 
-
 -- TASKS FOR AIRBORNE AND GROUND UNITS/CONTROLLABLES
 
 --- (AIR + GROUND) The task makes the controllable/unit a FAC and orders the FAC to control the target (enemy ground controllable) destruction.
@@ -1503,7 +1472,7 @@ function CONTROLLABLE:TaskFAC_AttackGroup( AttackGroup, WeaponType, Designation,
       modulation  = Modulation or radio.modulation.AM,
       callname    = CallsignName,
       number      = CallsignNumber,
-    }
+    },
   }
 
   return DCSTask
@@ -1526,14 +1495,12 @@ function CONTROLLABLE:EnRouteTaskEngageTargets( Distance, TargetTypes, Priority
       maxDist        = Distance,
       targetTypes    = TargetTypes or {"Air"},
       priority       = Priority or 0,
-    }
+    },
   }
 
   return DCSTask
 end
 
-
-
 --- (AIR) Engaging a targets of defined types at circle-shaped zone.
 -- @param #CONTROLLABLE self
 -- @param DCS#Vec2 Vec2 2D-coordinates of the zone.
@@ -1550,20 +1517,19 @@ function CONTROLLABLE:EnRouteTaskEngageTargetsInZone( Vec2, Radius, TargetTypes,
       zoneRadius  = Radius,
       targetTypes = TargetTypes or {"Air"},
       priority    = Priority or 0
-    }
+    },
   }
 
   return DCSTask
 end
 
-
 --- (AIR) Engaging a controllable. The task does not assign the target controllable to the unit/controllable to attack now; it just allows the unit/controllable to engage the target controllable as well as other assigned targets.
 -- @param #CONTROLLABLE self
 -- @param Wrapper.Controllable#CONTROLLABLE AttackGroup The Controllable to be attacked.
 -- @param #number Priority All en-route tasks have the priority parameter. This is a number (less value - higher priority) that determines actions related to what task will be performed first.
 -- @param #number WeaponType (optional) Bitmask of weapon types those allowed to use. If parameter is not defined that means no limits on weapon usage.
 -- @param DCS#AI.Task.WeaponExpend WeaponExpend (optional) Determines how much weapon will be released at each attack. If parameter is not defined the unit / controllable will choose expend on its own discretion.
--- @param #number AttackQty (optional) This parameter limits maximal quantity of attack. The aicraft/controllable will not make more attack than allowed even if the target controllable not destroyed and the aicraft/controllable still have ammo. If not defined the aircraft/controllable will attack target until it will be destroyed or until the aircraft/controllable will run out of ammo.
+-- @param #number AttackQty (optional) This parameter limits maximal quantity of attack. The aircraft/controllable will not make more attack than allowed even if the target controllable not destroyed and the aircraft/controllable still have ammo. If not defined the aircraft/controllable will attack target until it will be destroyed or until the aircraft/controllable will run out of ammo.
 -- @param DCS#Azimuth Direction (optional) Desired ingress direction from the target to the attacking aircraft. Controllable/aircraft will make its attacks from the direction. Of course if there is no way to attack from the direction due the terrain controllable/aircraft will choose another direction.
 -- @param DCS#Distance Altitude (optional) Desired attack start altitude. Controllable/aircraft will make its attacks from the altitude. If the altitude is too low or too high to use weapon aircraft/controllable will choose closest altitude to the desired attack start altitude. If the desired altitude is defined controllable/aircraft will not attack from safe altitude.
 -- @param #boolean AttackQtyLimit (optional) The flag determines how to interpret attackQty parameter. If the flag is true then attackQty is a limit on maximal attack quantity for "AttackGroup" and "AttackUnit" tasks. If the flag is false then attackQty is a desired attack quantity for "Bombing" and "BombingRunway" tasks.
@@ -1605,14 +1571,13 @@ function CONTROLLABLE:EnRouteTaskEngageGroup( AttackGroup, Priority, WeaponType,
   return DCSTask
 end
 
-
 --- (AIR) Search and attack the Unit.
 -- @param #CONTROLLABLE self
 -- @param Wrapper.Unit#UNIT EngageUnit The UNIT.
 -- @param #number Priority (optional) All en-route tasks have the priority parameter. This is a number (less value - higher priority) that determines actions related to what task will be performed first.
 -- @param #boolean GroupAttack (optional) If true, all units in the group will attack the Unit when found.
 -- @param DCS#AI.Task.WeaponExpend WeaponExpend (optional) Determines how much weapon will be released at each attack. If parameter is not defined the unit / controllable will choose expend on its own discretion.
--- @param #number AttackQty (optional) This parameter limits maximal quantity of attack. The aicraft/controllable will not make more attack than allowed even if the target controllable not destroyed and the aicraft/controllable still have ammo. If not defined the aircraft/controllable will attack target until it will be destroyed or until the aircraft/controllable will run out of ammo.
+-- @param #number AttackQty (optional) This parameter limits maximal quantity of attack. The aircraft/controllable will not make more attack than allowed even if the target controllable not destroyed and the aircraft/controllable still have ammo. If not defined the aircraft/controllable will attack target until it will be destroyed or until the aircraft/controllable will run out of ammo.
 -- @param DCS#Azimuth Direction (optional) Desired ingress direction from the target to the attacking aircraft. Controllable/aircraft will make its attacks from the direction. Of course if there is no way to attack from the direction due the terrain controllable/aircraft will choose another direction.
 -- @param DCS#Distance Altitude (optional) Desired altitude to perform the unit engagement.
 -- @param #boolean Visible (optional) Unit must be visible.
@@ -1641,8 +1606,6 @@ function CONTROLLABLE:EnRouteTaskEngageUnit( EngageUnit, Priority, GroupAttack,
   return DCSTask
 end
 
-
-
 --- (AIR) Aircraft will act as an AWACS for friendly units (will provide them with information about contacts). No parameters.
 -- @param #CONTROLLABLE self
 -- @return DCS#Task The DCS task structure.
@@ -1656,7 +1619,6 @@ function CONTROLLABLE:EnRouteTaskAWACS( )
   return DCSTask
 end
 
-
 --- (AIR) Aircraft will act as a tanker for friendly units. No parameters.
 -- @param #CONTROLLABLE self
 -- @return DCS#Task The DCS task structure.
@@ -1670,7 +1632,6 @@ function CONTROLLABLE:EnRouteTaskTanker( )
   return DCSTask
 end
 
-
 -- En-route tasks for ground units/controllables
 
 --- (GROUND) Ground unit (EW-radar) will act as an EWR for friendly units (will provide them with information about contacts). No parameters.
@@ -1686,7 +1647,6 @@ function CONTROLLABLE:EnRouteTaskEWR( )
   return DCSTask
 end
 
-
 -- En-route tasks for airborne and ground units/controllables
 
 --- (AIR + GROUND) The task makes the controllable/unit a FAC and lets the FAC to choose the target (enemy ground controllable) as well as other assigned targets.
@@ -1709,13 +1669,12 @@ function CONTROLLABLE:EnRouteTaskFAC_EngageGroup( AttackGroup, Priority, WeaponT
       designation = Designation,
       datalink    = Datalink and Datalink or false,
       priority    = Priority or 0,
-    }
+    },
   }
 
   return DCSTask
 end
 
-
 --- (AIR + GROUND) The task makes the controllable/unit a FAC and lets the FAC to choose a targets (enemy ground controllable) around as well as other assigned targets.
 -- The killer is player-controlled allied CAS-aircraft that is in contact with the FAC.
 -- If the task is assigned to the controllable lead unit will be a FAC.
@@ -1744,7 +1703,6 @@ function CONTROLLABLE:EnRouteTaskFAC( Radius, Priority )
   return DCSTask
 end
 
-
 --- This creates a Task element, with an action to call a function as part of a Wrapped Task.
 -- This Task can then be embedded at a Waypoint by calling the method @{#CONTROLLABLE.SetTaskWaypoint}.
 -- @param #CONTROLLABLE self
@@ -1813,8 +1771,6 @@ function CONTROLLABLE:TaskFunction( FunctionString, ... )
   return DCSTask
 end
 
-
-
 --- (AIR + GROUND) Return a mission task from a mission template.
 -- @param #CONTROLLABLE self
 -- @param #table TaskMission A table containing the mission task.
@@ -1823,13 +1779,14 @@ function CONTROLLABLE:TaskMission( TaskMission )
 
   local DCSTask = {
     id = 'Mission',
-    params = { TaskMission, },
+    params = {
+      TaskMission,
+    },
   }
 
   return DCSTask
 end
 
-
 do -- Patrol methods
 
   --- (GROUND) Patrol iteratively using the waypoints the for the (parent) group.
@@ -1863,7 +1820,6 @@ do -- Patrol methods
         end
       end
 
-     
       local Waypoint = Waypoints[1]
       local Speed = Waypoint.speed or (20 / 3.6)
       local From = FromCoord:WaypointGround( Speed )
@@ -1922,7 +1878,7 @@ do -- Patrol methods
         end
       end
       -- Loop until a waypoint has been found that is not the same as the current waypoint.
-      -- Otherwise the object zon't move or drive in circles and the algorithm would not do exactly
+      -- Otherwise the object won't move, or drive in circles, and the algorithm would not do exactly
       -- what it is supposed to do, which is making groups drive around.
       local ToWaypoint
       repeat
@@ -2021,8 +1977,7 @@ do -- Patrol methods
 
 end
 
-
+--- Return a Mission task to follow a given route defined by Points.
---- Return a Misson task to follow a given route defined by Points.
 -- @param #CONTROLLABLE self
 -- @param #table Points A table of route points.
 -- @return DCS#Task
@@ -2068,7 +2023,6 @@ do -- Route methods
       ["steer"] = 2,
     }
 
-
     local PointTo = {}
     PointTo.x = Point.x
     PointTo.y = Point.y
@@ -2084,7 +2038,6 @@ do -- Route methods
       ["steer"] = 2,
     }
 
-
     local Points = { PointFrom, PointTo }
 
     self:T3( Points )
@@ -2121,7 +2074,6 @@ do -- Route methods
       ["steer"] = 2,
     }
 
-
     local PointTo = {}
     PointTo.x = Point.x
     PointTo.y = Point.z
@@ -2139,7 +2091,6 @@ do -- Route methods
       ["steer"] = 2,
     }
 
-
     local Points = { PointFrom, PointTo }
 
     self:T3( Points )
@@ -2149,8 +2100,6 @@ do -- Route methods
     return self
   end
 
-
-
   --- Make the controllable to follow a given route.
   -- @param #CONTROLLABLE self
   -- @param #table Route A table of Route Points.
@@ -2187,7 +2136,6 @@ do -- Route methods
     return nil
   end
 
-
   --- Stops the movement of the vehicle on the route.
   -- @param #CONTROLLABLE self
   -- @return #CONTROLLABLE
@@ -2292,8 +2240,6 @@ do -- Route methods
     return self
   end
 
-
-
   --- Make a task for a GROUND Controllable to drive towards a specific point using (mostly) roads.
   -- @param #CONTROLLABLE self
   -- @param Core.Point#COORDINATE ToCoordinate A Coordinate to drive to.
@@ -2456,7 +2402,6 @@ do -- Route methods
     waypointfunction( controllable, n, N, ... )
   end
 
-
   --- Make the AIR Controllable fly towards a specific point.
   -- @param #CONTROLLABLE self
   -- @param Core.Point#COORDINATE ToCoordinate A Coordinate to drive to.
@@ -2478,7 +2423,6 @@ do -- Route methods
     return self
   end
 
-
   --- (AIR + GROUND) Route the controllable to a given zone.
   -- The controllable final destination point can be randomized.
   -- A speed can be given in km/h.
@@ -2504,7 +2448,6 @@ do -- Route methods
       PointFrom.action = Formation or "Cone"
       PointFrom.speed = 20 / 3.6
 
-
       local PointTo = {}
       local ZonePoint
 
@@ -2564,7 +2507,6 @@ do -- Route methods
       PointFrom.action = Formation or "Cone"
       PointFrom.speed = 20 / 3.6
 
-
       local PointTo = {}
 
       PointTo.x = Vec2.x
@@ -2616,7 +2558,6 @@ function CONTROLLABLE:CommandDoScript( DoScript )
   return DCSDoScript
 end
 
-
 --- Return the mission template of the controllable.
 -- @param #CONTROLLABLE self
 -- @return #table The MissionTemplate
@@ -2636,8 +2577,6 @@ function CONTROLLABLE:GetTaskRoute()
   return routines.utils.deepCopy( _DATABASE.Templates.Controllables[self.ControllableName].Template.route.points )
 end
 
-
-
 --- Return the route of a controllable by using the @{Core.Database#DATABASE} class.
 -- @param #CONTROLLABLE self
 -- @param #number Begin The route point from where the copy will start. The base route point is 0.
@@ -2689,7 +2628,6 @@ function CONTROLLABLE:CopyRoute( Begin, End, Randomize, Radius )
   return nil
 end
 
-
 --- Return the detected targets of the controllable.
 -- The optional parametes specify the detection methods that can be applied.
 -- If no detection method is given, the detection will use all the available methods by default.
@@ -2715,7 +2653,6 @@ function CONTROLLABLE:GetDetectedTargets( DetectVisual, DetectOptical, DetectRad
     local DetectionRWR = (DetectRWR and DetectRWR == true) and Controller.Detection.RWR or nil
     local DetectionDLINK = (DetectDLINK and DetectDLINK == true) and Controller.Detection.DLINK or nil
 
-
     local Params = {}
     if DetectionVisual then
       Params[#Params + 1] = DetectionVisual
@@ -2736,7 +2673,6 @@ function CONTROLLABLE:GetDetectedTargets( DetectVisual, DetectOptical, DetectRad
       Params[#Params + 1] = DetectionDLINK
     end
 
-
     self:T2( { DetectionVisual, DetectionOptical, DetectionRadar, DetectionIRST, DetectionRWR, DetectionDLINK } )
 
     return self:_GetController():getDetectedTargets( Params[1], Params[2], Params[3], Params[4], Params[5], Params[6] )
@@ -2853,7 +2789,6 @@ function CONTROLLABLE:IsGroupDetected( Group, DetectVisual, DetectOptical, Detec
   return nil
 end
 
-
 --- Return the detected targets of the controllable.
 -- The optional parametes specify the detection methods that can be applied.
 -- If **no** detection method is given, the detection will use **all** the available methods by default.
@@ -2930,7 +2865,6 @@ function CONTROLLABLE:GetDetectedGroupSet(DetectVisual, DetectOptical, DetectRad
   return groupset
 end
 
-
 -- Options
 
 --- Set option.
@@ -3199,7 +3133,6 @@ function CONTROLLABLE:OptionROTNoReactionPossible()
   return nil
 end
 
-
 --- No evasion on enemy threats.
 -- @param #CONTROLLABLE self
 -- @return #CONTROLLABLE self
@@ -3297,7 +3230,6 @@ function CONTROLLABLE:OptionROTEvadeFirePossible()
   return nil
 end
 
-
 --- Evade on fire.
 -- @param #CONTROLLABLE self
 -- @return #CONTROLLABLE self
@@ -3336,7 +3268,6 @@ function CONTROLLABLE:OptionROTVerticalPossible()
   return nil
 end
 
-
 --- Evade on fire using vertical manoeuvres.
 -- @param #CONTROLLABLE self
 -- @return #CONTROLLABLE self
@@ -3427,7 +3358,6 @@ function CONTROLLABLE:OptionAlarmStateRed()
   return nil
 end
 
-
 --- Set RTB on bingo fuel.
 -- @param #CONTROLLABLE self
 -- @param #boolean RTB true if RTB on bingo fuel (default), false if no RTB on bingo fuel.
@@ -3455,7 +3385,6 @@ function CONTROLLABLE:OptionRTBBingoFuel( RTB ) --R2.2
   return nil
 end
 
-
 --- Set RTB on ammo.
 -- @param #CONTROLLABLE self
 -- @param #boolean WeaponsFlag Weapons.flag enumerator.
@@ -3477,7 +3406,6 @@ function CONTROLLABLE:OptionRTBAmmo( WeaponsFlag )
   return nil
 end
 
-
 --- Allow to Jettison of weapons upon threat.
 -- @param #CONTROLLABLE self
 -- @return #CONTROLLABLE self
@@ -3498,7 +3426,6 @@ function CONTROLLABLE:OptionAllowJettisonWeaponsOnThreat()
   return nil
 end
 
-
 --- Keep weapons upon threat.
 -- @param #CONTROLLABLE self
 -- @return #CONTROLLABLE self
@@ -3563,7 +3490,6 @@ function CONTROLLABLE:OptionECM_OnlyLockByRadar()
   return self
 end
 
-
 --- Defines the usage of Electronic Counter Measures by airborne forces. If the AI is being detected by a radar they will enable their ECM.
 -- @param #CONTROLLABLE self
 -- @return #CONTROLLABLE self
@@ -3636,7 +3562,6 @@ function CONTROLLABLE:WayPointFunction( WayPoint, WayPointIndex, WayPointFunctio
   return self
 end
 
-
 --- Executes the WayPoint plan.
 -- The function gets a WayPoint parameter, that you can use to restart the mission at a specific WayPoint.
 -- Note that when the WayPoint parameter is used, the new start mission waypoint of the controllable will be 1!

Moose Development/Moose/Wrapper/Identifiable.lua

@@ -176,7 +176,7 @@ function IDENTIFIABLE:GetCoalitionName()
   
   if DCSIdentifiable then
   
-    -- Get coaliton ID.
+    -- Get coalition ID.
     local IdentifiableCoalition = DCSIdentifiable:getCoalition()
     self:T3( IdentifiableCoalition )
     

Moose Development/Moose/Wrapper/Marker.lua

@@ -15,7 +15,6 @@
 -- @module Wrapper.Marker
 -- @image Wrapper_Marker.png
 
-
 --- Marker class.
 -- @type MARKER
 -- @field #string ClassName Name of the class.
@@ -24,7 +23,7 @@
 -- @field #number mid Marker ID.
 -- @field Core.Point#COORDINATE coordinate Coordinate of the mark.
 -- @field #string text Text displayed in the mark panel.
--- @field #string message Message dispayed when the mark is added.
+-- @field #string message Message displayed when the mark is added.
 -- @field #boolean readonly Marker is read-only.
 -- @field #number coalition Coalition to which the marker is displayed.
 -- @extends Core.Fsm#FSM
@@ -45,8 +44,8 @@
 --     local Coordinate = AIRBASE:FindByName( "Batumi" ):GetCoordinate()
 --     mymarker = MARKER:New( Coordinate, "I am Batumi Airfield" )
 --
--- Now this does **not** show the marker yet. We still need to specifiy to whom it is shown. There are several options, i.e.
+-- Now this does **not** show the marker yet. We still need to specify to whom it is shown. There are several options, i.e.
--- show the marker to everyone, to a speficic coaliton only, or only to a specific group.
+-- show the marker to everyone, to a specific coalition only, or only to a specific group.
 --
 -- ## For Everyone
 --
@@ -54,17 +53,17 @@
 --
 --     mymarker = MARKER:New( Coordinate, "I am Batumi Airfield" ):ToAll()
 --
--- ## For a Coaliton
+-- ## For a Coalition
 --
 -- If the maker should be visible to a specific coalition, you can use the :ToCoalition() function.
 --
---     mymarker=MARKER:New(Coordinate, "I am Batumi Airfield"):ToCoaliton(coaliton.side.BLUE)
+--     mymarker = MARKER:New( Coordinate , "I am Batumi Airfield" ):ToCoalition( coalition.side.BLUE )
 --
--- ### To Blue Coaliton
+-- ### To Blue Coalition
 --
 -- ### To Red Coalition
 --
--- This would show the marker only to the Blue coaliton.
+-- This would show the marker only to the Blue coalition.
 --
 -- ## For a Group
 --
@@ -76,12 +75,12 @@
 --
 -- The marker text and coordinate can be updated easily as shown below.
 --
--- However, note that **updateing involves to remove and recreate the marker if either text or its coordinate is changed**.
+-- However, note that **updating involves to remove and recreate the marker if either text or its coordinate is changed**.
 -- *This is a DCS scripting engine limitation.*
 --
 -- ## Update Text
 --
--- If you created a marker "mymarker" as shown above, you can update the dispayed test by
+-- If you created a marker "mymarker" as shown above, you can update the displayed test by
 --
 --     mymarker:UpdateText( "I am the new text at Batumi" )
 --
@@ -116,7 +115,7 @@
 --
 -- # FSM Events
 --
--- Moose creates addditonal events, so called FSM event, when markers are added, changed, removed, and text or the coordianteis updated.
+-- Moose creates additional events, so called FSM event, when markers are added, changed, removed, and text or the coordinate is updated.
 --
 -- These events can be captured and used for processing via OnAfter functions as shown below.
 --
@@ -133,7 +132,6 @@
 --
 -- # Examples
 --
---
 -- @field #MARKER
 MARKER = {
   ClassName = "MARKER",
@@ -223,7 +221,6 @@ function MARKER:New(Coordinate, Text)
   -- @param #string To To state.
   -- @param Core.Event#EVENTDATA EventData Event data table.
 
-
   --- Triggers the FSM event "Removed".
   -- @function [parent=#MARKER] Removed
   -- @param #MARKER self
@@ -242,7 +239,6 @@ function MARKER:New(Coordinate, Text)
   -- @param #string To To state.
   -- @param Core.Event#EVENTDATA EventData Event data table.
 
-
   --- Triggers the FSM event "Changed".
   -- @function [parent=#MARKER] Changed
   -- @param #MARKER self
@@ -261,7 +257,6 @@ function MARKER:New(Coordinate, Text)
   -- @param #string To To state.
   -- @param Core.Event#EVENTDATA EventData Event data table.
 
-
   --- Triggers the FSM event "TextUpdate".
   -- @function [parent=#MARKER] TextUpdate
   -- @param #MARKER self
@@ -280,7 +275,6 @@ function MARKER:New(Coordinate, Text)
   -- @param #string To To state.
   -- @param #string Text The new text.
 
-
   --- Triggers the FSM event "CoordUpdate".
   -- @function [parent=#MARKER] CoordUpdate
   -- @param #MARKER self
@@ -299,7 +293,6 @@ function MARKER:New(Coordinate, Text)
   -- @param #string To To state.
   -- @param Core.Point#COORDINATE Coordinate The updated Coordinate.
 
-
   -- Handle events.
   self:HandleEvent( EVENTS.MarkAdded )
   self:HandleEvent( EVENTS.MarkRemoved )
@@ -344,7 +337,7 @@ function MARKER:ToAll(Delay)
   else
 
     self.toall = true
-    self.tocoaliton=nil
+    self.tocoalition = nil
     self.coalition = nil
     self.togroup = nil
     self.groupname = nil
@@ -367,7 +360,7 @@ end
 
 --- Place marker visible for a specific coalition only.
 -- @param #MARKER self
--- @param #number Coalition Coalition 1=Red, 2=Blue, 0=Neutral. See `coaliton.side.RED`.
+-- @param #number Coalition Coalition 1=Red, 2=Blue, 0=Neutral. See `coalition.side.RED`.
 -- @param #number Delay (Optional) Delay in seconds, before the marker is created.
 -- @return #MARKER self
 function MARKER:ToCoalition( Coalition, Delay )
@@ -378,7 +371,7 @@ function MARKER:ToCoalition(Coalition, Delay)
 
     self.coalition = Coalition
 
-    self.tocoaliton=true
+    self.tocoalition = true
     self.toall = false
     self.togroup = false
     self.groupname = nil
@@ -426,7 +419,6 @@ function MARKER:ToNeutral(Delay)
   return self
 end
 
-
 --- Place marker visible for a specific group only.
 -- @param #MARKER self
 -- @param Wrapper.Group#GROUP Group The group to which the marker is displayed.
@@ -448,7 +440,7 @@ function MARKER:ToGroup(Group, Delay)
         self.groupname = Group:GetName()
 
         self.togroup = true
-        self.tocoaliton=nil
+        self.tocoalition = nil
         self.coalition = nil
         self.toall = nil
 
@@ -531,7 +523,7 @@ function MARKER:Refresh(Delay)
 
       self:ToAll()
 
-    elseif self.tocoaliton then
+    elseif self.tocoalition then
 
       self:ToCoalition( self.coalition )
 
@@ -595,7 +587,6 @@ function MARKER:SetText(Text)
   return self
 end
 
-
 --- Check if marker is currently visible on the F10 map.
 -- @param #MARKER self
 -- @return #boolean True if the marker is currently visible.
@@ -770,7 +761,3 @@ function MARKER:onafterCoordUpdate(From, Event, To, Coordinate)
   self:T( self.lid .. string.format( "New Marker Coordinate in LL DMS: %s", Coordinate:ToStringLLDMS() ) )
 
 end
-
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