oprf_assets/MIM-104D/Nasal/radar-logic.nas

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var clamp = func(v, min, max) { v < min ? min : v > max ? max : v }
var encode3bits = func(first, second, third) {
var integer = first;
integer = integer + 2 * second;
integer = integer + 4 * third;
return integer;
}
var versionString = getprop("sim/version/flightgear");
var version = split(".", versionString);
var major = num(version[0]);
var minor = num(version[1]);
var pica = num(version[2]);
var pickingMethod = 0;
if ((major == 2017 and minor == 2 and pica >= 1) or (major == 2017 and minor > 2) or major > 2017) {
pickingMethod = 1;
}
var FALSE = 0;
var TRUE = 1;
var AIR = 0;
var MARINE = 1;
var SURFACE = 2;
var ORDNANCE = 3;
var Contact = {
# For now only used in guided missiles, to make it compatible with Mirage 2000-5.
new: func(c, class) {
var obj = { parents : [Contact]};
#debug.benchmark("radar process1", func {
obj.rdrProp = c.getNode("radar");
obj.oriProp = c.getNode("orientation");
obj.velProp = c.getNode("velocities");
obj.posProp = c.getNode("position");
obj.heading = obj.oriProp.getNode("true-heading-deg");
#});
#debug.benchmark("radar process2", func {
obj.alt = obj.posProp.getNode("altitude-ft");
obj.lat = obj.posProp.getNode("latitude-deg");
obj.lon = obj.posProp.getNode("longitude-deg");
#});
#debug.benchmark("radar process3", func {
#As it is a geo.Coord object, we have to update lat/lon/alt ->and alt is in meters
obj.coord = geo.Coord.new();
obj.coord.set_latlon(obj.lat.getValue(), obj.lon.getValue(), obj.alt.getValue() * FT2M);
#});
#debug.benchmark("radar process4", func {
obj.pitch = obj.oriProp.getNode("pitch-deg");
obj.roll = obj.oriProp.getNode("roll-deg");
obj.speed = obj.velProp.getNode("true-airspeed-kt");
obj.vSpeed = obj.velProp.getNode("vertical-speed-fps");
obj.callsign = c.getNode("callsign", 1);
obj.shorter = c.getNode("model-shorter");
obj.orig_callsign = obj.callsign.getValue();
obj.name = c.getNode("name");
obj.sign = c.getNode("sign",1);
obj.valid = c.getNode("valid");
obj.painted = c.getNode("painted");
obj.unique = c.getNode("unique");
obj.validTree = 0;
#});
#debug.benchmark("radar process5", func {
#obj.transponderID = c.getNode("instrumentation/transponder/transmitted-id");
#});
#debug.benchmark("radar process6", func {
obj.acType = c.getNode("sim/model/ac-type");
obj.type = c.getName();
obj.index = c.getIndex();
obj.string = "ai/models/" ~ obj.type ~ "[" ~ obj.index ~ "]";
obj.shortString = obj.type ~ "[" ~ obj.index ~ "]";
#});
#debug.benchmark("radar process7", func {
obj.range = obj.rdrProp.getNode("range-nm");
obj.bearing = obj.rdrProp.getNode("bearing-deg");
obj.elevation = obj.rdrProp.getNode("elevation-deg");
obj.ubody = obj.rdrProp.getNode("velocities/uBody-fps");
obj.vbody = obj.rdrProp.getNode("velocities/vBody-fps");
obj.wbody = obj.rdrProp.getNode("velocities/wBody-fps");
#});
obj.deviation = nil;
obj.node = c;
obj.class = class;
obj.polar = [0,0];
obj.cartesian = [0,0];
return obj;
},
get_uBody: func {
var body = nil;
if (me.ubody != nil) {
body = me.ubody.getValue();
}
if(body == nil) {
body = me.get_Speed()*KT2FPS;
}
return body;
},
get_vBody: func {
var body = nil;
if (me.ubody != nil) {
body = me.vbody.getValue();
}
if(body == nil) {
body = 0;
}
return body;
},
get_wBody: func {
var body = nil;
if (me.ubody != nil) {
body = me.wbody.getValue();
}
if(body == nil) {
body = 0;
}
return body;
},
isValid: func () {
var valid = me.valid.getValue();
if (valid == nil) {
valid = FALSE;
}
if (me.callsign.getValue() != me.orig_callsign) {
valid = FALSE;
}
return valid;
},
isPainted: func () {
if (getprop("/carrier/sunk") == 1) {
return 0;
}
return isNotBehindTerrain(me.node)[0];
},
getUnique: func () {
if (me.unique == nil) {
me.unique = me.node.getNode("unique");
}
if (me.unique == nil) {
return nil;
}
var u = me.unique.getValue();
return u;
},
getElevation: func() {
var e = 0;
e = me.elevation.getValue();
if(e == nil or e == 0) {
# AI/MP has no radar properties
var self = geo.aircraft_position();
self.set_alt(self.alt()+fire_control.radar_elevation_above_terrain_m);
me.get_Coord();
var angleInv = clamp(self.distance_to(me.coord)/self.direct_distance_to(me.coord), -1, 1);
e = (self.alt()>me.coord.alt()?-1:1)*math.acos(angleInv)*R2D;
}
return e;
},
getNode: func () {
return me.node;
},
getFlareNode: func () {
return me.node.getNode("rotors/main/blade[3]/flap-deg");
},
getChaffNode: func () {
return me.node.getNode("rotors/main/blade[3]/position-deg");
},
setPolar: func(dist, angle) {
me.polar = [dist,angle];
},
setCartesian: func(x, y) {
me.cartesian = [x,y];
},
remove: func(){
if(me.validTree != 0){
me.validTree.setValue(0);
}
},
get_Coord: func(){
me.coord.set_latlon(me.lat.getValue(), me.lon.getValue(), me.alt.getValue() * FT2M);
var TgTCoord = geo.Coord.new(me.coord);
return TgTCoord;
},
get_Callsign: func(){
var n = me.callsign.getValue();
if(n != "" and n != nil) {
return n;
}
if (me.name == nil) {
me.name = me.getNode().getNode("name");
}
if (me.name == nil) {
n = "";
} else {
n = me.name.getValue();
}
if(n != "" and n != nil) {
return n;
}
n = me.sign.getValue();
if(n != "" and n != nil) {
return n;
}
return "UFO";
},
get_model: func(){
var n = "";
if (me.shorter == nil) {
me.shorter = me.node.getNode("model-shorter");
}
if (me.shorter != nil) {
n = me.shorter.getValue();
}
if(n != "" and n != nil) {
return n;
}
n = me.sign.getValue();
if(n != "" and n != nil) {
return n;
}
if (me.name == nil) {
me.name = me.getNode().getNode("name");
}
if (me.name == nil) {
n = "";
} else {
n = me.name.getValue();
}
if(n != "" and n != nil) {
return n;
}
return me.get_Callsign();
},
get_Speed: func(){
# return true airspeed
var n = me.speed.getValue();
return n;
},
get_Longitude: func(){
var n = me.lon.getValue();
return n;
},
get_Latitude: func(){
var n = me.lat.getValue();
return n;
},
get_Pitch: func(){
var n = me.pitch.getValue();
return n;
},
isVirtual: func(){
return 0;
},
get_Roll: func(){
var n = me.roll.getValue();
return n;
},
get_heading : func(){
var n = me.heading.getValue();
if(n == nil)
{
n = 0;
}
return n;
},
get_bearing: func(){
var n = 0;
n = me.bearing.getValue();
if(n == nil or n == 0) {
# AI/MP has no radar properties
n = me.get_bearing_from_Coord(geo.aircraft_position());
}
return n;
},
get_bearing_from_Coord: func(MyAircraftCoord){
me.get_Coord();
var myBearing = 0;
if(me.coord.is_defined()) {
myBearing = MyAircraftCoord.course_to(me.coord);
}
return myBearing;
},
get_reciprocal_bearing: func(){
return geo.normdeg(me.get_bearing() + 180);
},
get_deviation: func(true_heading_ref, coord){
me.deviation = - deviation_normdeg(true_heading_ref, me.get_bearing_from_Coord(coord));
return me.deviation;
},
get_altitude: func(){
#Return Alt in feet
return me.alt.getValue();
},
get_Elevation_from_Coord: func(MyAircraftCoord) {
me.get_Coord();
var value = (me.coord.alt() - MyAircraftCoord.alt()) / me.coord.direct_distance_to(MyAircraftCoord);
if (math.abs(value) > 1) {
# warning this else will fail if logged in as observer and see aircraft on other side of globe
return 0;
}
var myPitch = math.asin(value) * R2D;
return myPitch;
},
get_total_elevation_from_Coord: func(own_pitch, MyAircraftCoord){
var myTotalElevation = - deviation_normdeg(own_pitch, me.get_Elevation_from_Coord(MyAircraftCoord));
return myTotalElevation;
},
get_total_elevation: func(own_pitch) {
me.deviation = - deviation_normdeg(own_pitch, me.getElevation());
return me.deviation;
},
get_range: func() {
var r = 0;
if(me.range == nil or me.range.getValue() == nil or me.range.getValue() == 0) {
# AI/MP has no radar properties
me.get_Coord();
r = me.coord.direct_distance_to(geo.aircraft_position()) * M2NM;
} else {
r = me.range.getValue();
}
return r;
},
get_range_from_Coord: func(MyAircraftCoord) {
var myCoord = me.get_Coord();
var myDistance = 0;
if(myCoord.is_defined()) {
myDistance = MyAircraftCoord.direct_distance_to(myCoord) * M2NM;
}
return myDistance;
},
get_type: func () {
return me.class;
},
get_cartesian: func() {
return me.cartesian;
},
get_polar: func() {
return me.polar;
},
};
var isNotBehindTerrain = func( mp ) {
var pos = mp.getNode("position");
var alt = pos.getNode("altitude-ft").getValue();
var lat = pos.getNode("latitude-deg").getValue();
var lon = pos.getNode("longitude-deg").getValue();
if(alt == nil or lat == nil or lon == nil) {
return [0,0]; # invisible and not in front of terrain
}
var aircraftPos = geo.Coord.new().set_latlon(lat, lon, alt*FT2M);
var myPos = geo.aircraft_position();
myPos.set_alt(myPos.alt()+fire_control.radar_elevation_above_terrain_m);
var target_distance = myPos.direct_distance_to(aircraftPos);
call(func {
if (target_distance*0.001 > 3.57*(math.sqrt(myPos.alt())+math.sqrt(alt*FT2M))) {
# behind earth curvature
#print("behind earth curvature");
return [0,0]; # invisible and not in front of terrain
}
},nil,nil,var err =[]);
var xyz = {"x":myPos.x(), "y":myPos.y(), "z":myPos.z()};
var dir = {"x":aircraftPos.x()-myPos.x(), "y":aircraftPos.y()-myPos.y(), "z":aircraftPos.z()-myPos.z()};
# Check for terrain between own aircraft and other:
v = get_cart_ground_intersection(xyz, dir);
if (v == nil) {
return [1,0]; # visible and not in front of terrain
#printf("No terrain, planes has clear view of each other");
} else {
var terrain = geo.Coord.new();
terrain.set_latlon(v.lat, v.lon, v.elevation);
var maxDist = myPos.direct_distance_to(aircraftPos);
var terrainDist = myPos.direct_distance_to(terrain);
if (terrainDist < maxDist-1) {
#printf("terrain found between me and aircraft %.1f meter away.", terrainDist);
return [0,0]; # visible and not in front of terrain
} else {
#print("The planes has clear view of each other");
return [1,1]; # visible and in front of terrain
}
}
}