Nasal Flightplan: Difference between revisions

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== Background ==
== Background ==
The Nasal functions relating to the route manager system include:
The Nasal functions relating to the route manager system include:
* {{func link|flightplan()}}
* {{func link|flightplan()}} - return the active plan.
* {{func link|airwaysRoute()}}
* {{func link|airwaysRoute()}}
* {{func link|createFlightplan()}} - creates new empty plan. A path can be supplied to load a plan from xml.


Flight plans are based on waypoints, which, in C++, inherit from the {{API Link|flightgear|class|FGPositioned}} class.
Flight plans are based on waypoints, which, in C++, inherit from the {{API Link|flightgear|class|FGPositioned}} class.
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; wp_parent_name : Name of waypoint's parent.
; wp_parent_name : Name of waypoint's parent.
; wp_parent : Waypoint's parent.
; wp_parent : Waypoint's parent.
; fly_type : How to waypoint should be flown over or reacted to. One of "Hold," "flyOver," or "flyBy."
; fly_type : How to waypoint should be flown over or reacted to. One of "flyOver" or "flyBy".
; heading_course : Heading of runway.
; heading_course : Heading of runway.


== Flightplan methods and variables ==
== Flightplan methods and variables ==
 
Notice that instead of passing a leg as parameter, a waypoint can be passed.
; getWP(index) : Returns the waypoint for specified index.
; getWP(index) : Returns the leg for specified index.
; currentWP() : Return current active waypoint.
; currentWP() : Return current active leg.
; nextWP() :  
; nextWP() : Make next waypoint active.
; getPlanSize() : Returns number of waypoints
; getPlanSize() : Returns number of waypoints
; appendWP(waypoint) : Add a waypoint to the end of the flightplan.
; appendWP(leg) : Add a leg to the end of the flightplan.
; insertWP(wp, index) : Pass a waypoint object and its position.
; insertWP(leg, index) : Pass a leg object and its position.
; deleteWP(index) : Deletes the waypoint at specified index.
; deleteWP(index) : Deletes the waypoint at specified index.
; insertWPAfter() :  
; insertWPAfter() :  
; insertWaypoints(vector, index) : Pass a vector of waypoint objects, and the position to insert.
; insertWaypoints(vector, index) : Pass a vector of waypoint objects, and the position to insert.
; cleanPlan() : Clears all waypoints including destination and departure.
; cleanPlan() : Clears all waypoints except destination and departure.
; clearWPType(type) : Supply a type string, it will clear all waypoints of the type.
; clearWPType(type) : Supply a type string, it will clear all waypoints of the type.
; clone() : Return a copy of the fligthplan.
; clone() : Return a copy of the flightplan.
; pathGeod() :  
; pathGeod() : This is used for graphical display: it’s an array of coordinates which show the path of the plan. This includes holds, procedure turns, turn anticipation and more.
; finish() :  
; finish() : Finish the plan. (a call to delegate will be made)
; indexOfWP() :
; indexOfWP(wp) : Returns the index of the passed waypoint/leg.
; destination : airport object as destination.
; destination : airport object as destination.
; destination_runway : rwy object as destination and its runway implicit.
; destination_runway : rwy object as destination and its airport implicit.
; departure : airport object as departure.
; departure : airport object as departure.
; departure_runway : rwy object as departure and its runway implicit.
; departure_runway : rwy object as departure and its airport implicit.
; id :
; id : optional name of plan.
; sid : procedure object for SID.
; sid : procedure object for SID.
; star : procedure object for STAR.
; star : procedure object for STAR.
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; current : Index of current waypoint.
; current : Index of current waypoint.
; aircraftCategory : ICAO aircraft category.
; aircraftCategory : ICAO aircraft category.
; followLegTrackToFix :
; followLegTrackToFix : Specific used by some procedures. It controls whether the system will fly on an intersection course (and hence, different track) to the end of the leg, or make a corrective S-turn to get back on the leg track immediately it becomes possible.
; activate() :
; activate() : This will make the flight plan the default (the one used in route-manager).
; save(path) : Save a plan to xml. Will return true or false for success.


== Leg methods and variables ==
== Leg methods and variables ==
A leg is a wrapper for a waypoint, so it will have all waypoints variables and methods plus what is listed below.
A leg is a wrapper for a waypoint, so it will have all waypoints variables and methods plus what is listed below.
; setSpeed() :
Notice, that a leg you have gotten from a plan, but deleted in the plan, will be invalid and should not be used or modified.
; setAltitude() :
A leg you have gotten from a plan, when modified, will modify the leg inside the plan you got it from.
; path() :
; setSpeed(speed, type) : Sets the speed restriction. Setting nil type, will crash FG, setting empty type is same as setting "at". See below for type list.
; courseAndDistanceFrom() :
; setAltitude(altitude, type) : Sets the altitude restriction. Setting nil type, will crash FG, setting empty type is same as setting "at". See below for type list.
; parents :
; path() : Returns a vector of hashes containing lat and lon variables. These compromise a curved path for long non straight legs.
; index :
; courseAndDistanceFrom(coord) : Return vector with true course and distance. Coord is a geo.Coord.
; alt_cstr : Altitude restriction.
; parents : Nasal parents.
; alt_cstr_type : Altitude restriction type. Can be "at", "above", "below", "mach", "computed", "computed-mach", "delete".
; wp_owner : Will return you the owning route-structure of the WP - this could be an airway, procedure, or the flightplan if the waypoint doesn’t belong to a route structure.
; speed_cstr : Speed restriction.
; index : Returns the index of the leg in the owning route-structure.
; speed_cstr_type : Speed restriction. Can be "at", "above", "below", "mach", "computed", "computed-mach", "delete".
; alt_cstr : Read-only. Altitude restriction.
; leg_distance :
; alt_cstr_type : Read-only. Altitude restriction type. See below for list.
; leg_bearing :
; speed_cstr : Read-only. Speed restriction.
; distance_along_route :
; speed_cstr_type : Read-only. Speed restriction. See below for list.
; leg_distance : Returns distance along the leg, from the preceding waypoint.
; leg_bearing : Returns the bearing along the leg.
; distance_along_route : Return the total distance laterally along the route to the beginning of the leg.
 
For speed restrictions these types can be used:
* "at" = kt should be spot on
* "above" = kt should be higher
* "below" = kt should be under
* "computed" = predicted kt
* "computed-mach" = predicted mach
* "mach" = its in mach instead of kt
* "delete" = Cleared by ATC
 
For altitude restrictions these types can be used:
* "at" = alt should be spot on
* "above" = alt should be higher
* "below" = alt should be below
* "computed" = predicted alt
* "computed-mach" = not used for altitude
* "mach" = not used for altitude
* "delete" = Cleared by ATC


== Procedure methods and variables ==
== Procedure methods and variables ==
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* [[Route Manager]]
* [[Route Manager]]
* [[Route Manager internals]]
* [[Route Manager internals]]
* [[Howto:Control the route manager in Nasal]]


=== Documentation ===
=== Documentation ===

Revision as of 15:33, 8 February 2019

Note  Whenever possible, please refrain from modeling complex systems, like an FDM, autopilot or Route Manager with Nasal. This is primarily to help reduce Nasal overhead (especially GC overhead). It will also help to unify duplicated code. The FlightGear/SimGear code base already contains fairly generic and efficient systems and helpers, implemented in C++, that merely need to be better generalized and exposed to Nasal so that they can be used elsewhere. For example, this would enable Scripted AI Objects to use full FDM implementations and/or built-in route manager systems.

Technically, this is also the correct approach, as it allows us to easily reuse existing code that is known to be stable and working correctly, .

For details on exposing these C++ systems to Nasal, please refer to Nasal/CppBind. If in doubt, please get in touch via the mailing list or the forum first.


Because FlightGear's route manager flight plan system is exposed to Nasal, Nasal can be used to interact with flight plans. Obviously, this is very useful, especially for aircraft like airliners, which have complex route managers systems. This article shows how this can be done.

Background

The Nasal functions relating to the route manager system include:

Flight plans are based on waypoints, which, in C++, inherit from the FGPositioned (doxygen) class.

Waypoint hashes

The following are members of a waypoint ghost, as generated by, for example, airwaysRoute() :

wp_name
Name of the waypoint, returned as string.
wp_type
Waypoint type, returned as string. One of "basic," "navaid," "offset-navaid," "runway," "hdgToAlt," "dmeIntercept," "radialIntercept," or "vectors."
wp_role
Role of waypoint.
wp_lat or lat
Latitude of waypoint.
wp_lon or lon
Longitude of waypoint.
wp_parent_name
Name of waypoint's parent.
wp_parent
Waypoint's parent.
fly_type
How to waypoint should be flown over or reacted to. One of "flyOver" or "flyBy".
heading_course
Heading of runway.

Flightplan methods and variables

Notice that instead of passing a leg as parameter, a waypoint can be passed.

getWP(index)
Returns the leg for specified index.
currentWP()
Return current active leg.
nextWP()
Make next waypoint active.
getPlanSize()
Returns number of waypoints
appendWP(leg)
Add a leg to the end of the flightplan.
insertWP(leg, index)
Pass a leg object and its position.
deleteWP(index)
Deletes the waypoint at specified index.
insertWPAfter()
insertWaypoints(vector, index)
Pass a vector of waypoint objects, and the position to insert.
cleanPlan()
Clears all waypoints except destination and departure.
clearWPType(type)
Supply a type string, it will clear all waypoints of the type.
clone()
Return a copy of the flightplan.
pathGeod()
This is used for graphical display: it’s an array of coordinates which show the path of the plan. This includes holds, procedure turns, turn anticipation and more.
finish()
Finish the plan. (a call to delegate will be made)
indexOfWP(wp)
Returns the index of the passed waypoint/leg.
destination
airport object as destination.
destination_runway
rwy object as destination and its airport implicit.
departure
airport object as departure.
departure_runway
rwy object as departure and its airport implicit.
id
optional name of plan.
sid
procedure object for SID.
star
procedure object for STAR.
sid_trans
star_trans
approach
procedure object for approach.
current
Index of current waypoint.
aircraftCategory
ICAO aircraft category.
followLegTrackToFix
Specific used by some procedures. It controls whether the system will fly on an intersection course (and hence, different track) to the end of the leg, or make a corrective S-turn to get back on the leg track immediately it becomes possible.
activate()
This will make the flight plan the default (the one used in route-manager).
save(path)
Save a plan to xml. Will return true or false for success.

Leg methods and variables

A leg is a wrapper for a waypoint, so it will have all waypoints variables and methods plus what is listed below. Notice, that a leg you have gotten from a plan, but deleted in the plan, will be invalid and should not be used or modified. A leg you have gotten from a plan, when modified, will modify the leg inside the plan you got it from.

setSpeed(speed, type)
Sets the speed restriction. Setting nil type, will crash FG, setting empty type is same as setting "at". See below for type list.
setAltitude(altitude, type)
Sets the altitude restriction. Setting nil type, will crash FG, setting empty type is same as setting "at". See below for type list.
path()
Returns a vector of hashes containing lat and lon variables. These compromise a curved path for long non straight legs.
courseAndDistanceFrom(coord)
Return vector with true course and distance. Coord is a geo.Coord.
parents
Nasal parents.
wp_owner
Will return you the owning route-structure of the WP - this could be an airway, procedure, or the flightplan if the waypoint doesn’t belong to a route structure.
index
Returns the index of the leg in the owning route-structure.
alt_cstr
Read-only. Altitude restriction.
alt_cstr_type
Read-only. Altitude restriction type. See below for list.
speed_cstr
Read-only. Speed restriction.
speed_cstr_type
Read-only. Speed restriction. See below for list.
leg_distance
Returns distance along the leg, from the preceding waypoint.
leg_bearing
Returns the bearing along the leg.
distance_along_route
Return the total distance laterally along the route to the beginning of the leg.

For speed restrictions these types can be used:

  • "at" = kt should be spot on
  • "above" = kt should be higher
  • "below" = kt should be under
  • "computed" = predicted kt
  • "computed-mach" = predicted mach
  • "mach" = its in mach instead of kt
  • "delete" = Cleared by ATC

For altitude restrictions these types can be used:

  • "at" = alt should be spot on
  • "above" = alt should be higher
  • "below" = alt should be below
  • "computed" = predicted alt
  • "computed-mach" = not used for altitude
  • "mach" = not used for altitude
  • "delete" = Cleared by ATC

Procedure methods and variables

route(runway)
Returns a vector of waypoints.
transition()
Only works on STAR and SID.

Examples

# get the active flight plan (the one being used by the route manager)
var fp = flightplan();

# or create one an XML file
fp = flightplan('/path/to/xml');

# save the active flight plan
fgcommand("save-flightplan", props.Node.new({"path": 'path/to/xml'}));

# duplicate a flight-plan
var secondary = fp.clone();

var dest = airportinfo('KSFO');
var rwy = dest.runway('19L');
# the the arrival runway (and airport, automatically)
fp.destination_runway = rwy;

# or if no runway is known/specified
fp.destination = dest;

Building procedures and transitions. As mentioned above there's a couple of different ways to handle this, the examples below assume the C++ code automatically deletes and re-inserts waypoints for procedures, but that's only one possible design.

var apt = airportinfo('KSFO');
# example for SIDs, STARs are the same, approaches too
var allSids = apt.sids();

# SIDs for a specific runway - note these return SID IDs as string, for compatibility with existing code
var rwySids = apt.sids('28L');

Inserting and deleting waypoints (possibly in batches)

var fp = flightplan();
# waypoint created from lat, lon, or a navaid, or anything else?
var pos = geo.aircraft_position().apply_course_distance(getprop("/orientation/heading-deg"), 100000);
var wp = createWP(pos.lat(), pos.lon(), "EPICA");

# manually insert a waypoint at the end of the plan
fp.insertWP(wp, fp.getPlanSize());

# manually insert a waypoint at a defined position (n) into the plan
fp.insertWP(wp, n);

# route along airways, and insert a whole bunch of waypoints
# this is needed for the route-manager dialog, maybe not for a
# real FMS interface....
var segment = [<waypoint object>, <waypoint object>, <waypoint object>];
# segment is a vector of waypoints now
fp.insertWaypoints(segment, fp.getPlanSize());

aircraft.history() (3.2+)

Function to expose flight history as aircraft.history()

var hist = aircraft.history();

# get history of aircraft position/orientation collapsing
# nodes with a distance smaller than the given minimum
# edge length
debug.dump( hist.pathForHistory(<minimum-edge-length-meter>) );

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