fly/A320-family
1
0
Fork 0
Code Activity
A320-family/Models/Instruments/ND/canvas/map/TERRAIN.symbol
legoboyvdlp R 439a7c7b50 Terrain display: only show sea level water as cyan
2021-05-22 13:18:21 +01:00

451 lines
No EOL
12 KiB
Text
Raw Blame History

# See: http://wiki.flightgear.org/MapStructure
# Class things:
## Airbus Terrain on ND by InuYaksa*2021
## EGPWS device - Applicable to: MSN 0112
## Ident.: DSC-31-45-00009586.0012001 / 22 MAY 12
## Ident.: DSC-31-45-00009586.0009001 / 08 AUG 13
## inspired from work on 787-family - thanks a lots
## and a great help from legoboyvdlp
var name = 'TERRAIN';
var parents = [DotSym];
var __self__ = caller(0)[0];
DotSym.makeinstance( name, __self__ );
var element_type = "group";
var terrain_alert = props.globals.getNode("/instrumentation/mk-viii/outputs/alert-mode");
var tile_list = [
nil,"tile_gl.png","tile_gh.png","tile_al.png","tile_ah.png","tile_rh.png", # 0-5 low alt - imho real ND displays as amber-ish color than yellow one
"tile_gl.png","tile_gh.png","tile_gh.png","tile_gs.png", # 6-9 hi alt
"tile_ml.png","tile_cl.png", # 10 magenta - 11 cyan-ish/blue (water)
"tile_as.png","tile_rs.png" # 12-13 alert - solid colors
];
var is_terrain = 0;
var get_elevation = func (lat, lon) {
var info = geodinfo(lat, lon);
var elevation = 0;
if (info != nil) {
elevation = int(info[0] * 3.2808399);
me.is_terrain = (info[1] == nil) ? 1 : info[1].solid;
}
else { elevation = nil; }
return elevation;
}
var updateTerrain = func {
if (me.reference == nil) return;
if(me.fetching) return;
me.fetching = 1;
if (me.request_clear == 1) {
me.request_clear = 0;
me.clear();
me.group.setVisible(1);
}
var RAD2DEG = 57.2957795;
var DEG2RAD = 0.016774532925;
var pos_lat = me.reference.lat();
var pos_lon = me.reference.lon();
var heading = me.refheading;
var altitudeft = me.refaltitudeft;
var lowaltft = me.reflowaltft;
var basealtft = me.basealtitudeft;
var alert_level = me.terrain_alert.getValue();
var side = (math.mod(me.radar_beacon,2)==0) ? "L" : "R";
var a = int(me.radar_beacon/2);
var col = a + 0.5;
if (side == "R") {
col = -col;
}
var trn = me.terrlayer[side ~ a];
var len = size(trn);
var range = me.range;
var tiles = me.tile_list;
#var proj_lon = pos_lon + ((col * (range/30) * math.sin(DEG2RAD * (heading - 90))) / 40);
#var proj_lat = pos_lat + ((col * (range/30) * math.cos(DEG2RAD * (heading - 90))) / 40);
# if me.tileradiusw == 20
var range_20f = range / 19.70; #18.75;
var heading_sin = math.sin(DEG2RAD * heading);
var heading_cos = math.cos(DEG2RAD * heading);
var col_x_range20f = col * range_20f;
var proj_lon = pos_lon + ((col_x_range20f * math.sin(DEG2RAD * (heading - 90))) / 60);
var proj_lat = pos_lat + ((col_x_range20f * math.cos(DEG2RAD * (heading - 90))) / 60);
var elevft = [];
me.radar_cleared = 0;
var altmin = 9999;
var altmax = -9999;
for (var row = 0; row < len; row += 1) {
if (trn[row] == nil) {
append(elevft,-1);
continue;
}
var row_x_r20f_60th = (row * range_20f / 60);
var point_lon = proj_lon + (row_x_r20f_60th * heading_sin);
var point_lat = proj_lat + (row_x_r20f_60th * heading_cos);
var elev = me.get_elevation(point_lat, point_lon);
var grad = 0; #black
if (elev != nil) {
if (elev>altmax) altmax = elev;
if (me.is_terrain) {
if (elev<altmin) altmin = elev;
if (elev < basealtft) grad = 0; # < 400 near runway use blank
else {
var diff = elev - altitudeft;
if (diff>=0) {
grad = int(diff/1000) + 3;
if (grad>5) grad = 5;
if (alert_level > 0 and a <= 6) {
if (alert_level == 1 and grad != 5) grad = 12; # solid yellow
else if (alert_level == 2 and grad == 5) grad = 13; # solid red
}
} else {
if (me.hialtmode == 0) {
if (diff>=lowaltft) grad = 3; # lite yellow
else {
grad = int(diff/1000) + 2;
if (grad<0) grad = 0;
}
} else {
if (diff>=lowaltft) grad = 3; # lite yellow
else {
if (me.bands_range > 0 and elev > me.bands_minalt) {
if (elev >= me.green_altitude) grad = 9; # solid green
else {
grad = 8 - int((me.bands_maxalt - elev) / me.bands_range); # 9 -
#if (grad>9) grad = 9; # solid green
if (grad>8) grad = 8; # high green
else if (grad<6) grad = 6; #light green
}
}
}
}
}
}
} else {
if (elev <= 0) {
grad = 11; #water/cyan
}
}
append(elevft,grad); # 0-5
} else {
append(elevft,0); # no data - black (magenta)
}
}
for (var r=0; r < len; r+=1) {
var imgx = elevft[r];
if (imgx == -1) continue;
if (imgx < 1) trn[r].hide();
else trn[r].setFile(me.imgpath ~ me.tile_list[imgx]).show();
}
if (altmax != -9999) {
if (altmin > altmax) altmin = altmax; # occurs on sea areas
if (me.max_altitude == -9999) {
me.min_altitude = altmin;
me.max_altitude = altmax;
} else {
if (altmin<me.min_altitude) me.min_altitude = altmin;
if (altmax>me.max_altitude) me.max_altitude = altmax;
}
}
me.radar_beacon += 1;
if (me.radar_beacon >= (me.tileradiusw*2)) {
me.restart_beacon();
}
me.fetching = 0;
};
var update_altitudes = func {
var maxalt = int(me.max_altitude);
me.terrain_minalt.setValue(int(me.min_altitude));
me.terrain_maxalt.setValue(maxalt);
if (me.avg_maxalt == -9999) {
me.avg_minalt = int(me.min_altitude);
me.avg_maxalt = maxalt;
} else {
me.avg_minalt = math.avg(me.avg_minalt,me.min_altitude);
me.avg_maxalt = math.avg(me.avg_maxalt,maxalt);
}
var altdif = maxalt - me.refaltitudeft;
if (altdif <= 0) {
if (altdif >= me.reflowaltft) me.terrain_maxcol.setValue(1);
else me.terrain_maxcol.setValue(0);
} else {
if (altdif>=2000) me.terrain_maxcol.setValue(2);
else me.terrain_maxcol.setValue(1);
}
me.avg_diffalt = me.avg_maxalt - me.avg_minalt;
if (me.onground == 0 and (maxalt + 200) < me.refaltitudeft) { # 200 ft tollerance
me.hialtmode = 1;
var mxrange = math.max(1600,int((me.avg_maxalt - me.basealtitudeft) * 0.3));
var range = math.min(mxrange,me.avg_diffalt);
if (range < 160) { # min elev number
me.bands_range = 0;
} else {
me.bands_maxalt = me.avg_maxalt;
me.bands_minalt = math.max( me.avg_maxalt - range, me.avg_minalt + me.basealtitudeft );
me.bands_range = int( (me.bands_maxalt - me.bands_minalt) / 4);
}
me.green_altitude = math.max(maxalt - 1200, me.avg_maxalt - me.bands_range);
} else {
me.hialtmode = 0;
#me.avg_minalt = 9999;
}
me.min_altitude = 9999;
me.max_altitude = -9999;
me.avg_maxalt = -9999;
}
var restart_beacon = func {
me.radar_beacon = 0;
me.radar_cycle += 1;
me.reference = nil;
};
var init = func {
print('TERRAIN init');
#print(me.layer.efis_path);
me.tile = 33;
me.fetching = 0;
me.fetchRad = me.model.fetchRad; # Radius of radar layer to fetch
me.range = me.model.rangeNm; # Range of Navigation Display
me.viewport_radius = me.getOption('viewport_radius', 670);
me.imgpath = get_local_path('res/terrainv2/');
me.radar_beacon = 0;
me.radar_cycle = 0;
me.radar_cleared = 1;
me.request_clear = 0;
me.min_altitude = 9999;
me.max_altitude = -9999;
me.green_altitude = 0; # max altitude for solid green (peak color)
me.avg_minalt = 9999;
me.avg_maxalt = -9999;
me.avg_diffalt = nil;
me.maxalt_col = 0; # 0 = grn, 1 = yel, 2 = red
me.bands_minalt = 0;
me.bands_maxalt = 0;
me.bands_range = 0;
me.basealtitudeft = nil;
me.reference = nil;
me.onfailure = 0;
me.hialtmode = 0; # high aircraft relative altitude mode
me.checkarrival = 0;
me.onground = 1;
me.terrain_minalt = props.globals.initNode(me.layer.efis_path ~ "/nd/terrain-on-nd/min-altitude", 0,"INT");
me.terrain_maxalt = props.globals.initNode(me.layer.efis_path ~ "/nd/terrain-on-nd/max-altitude", -9999,"INT");
me.terrain_maxcol = props.globals.initNode(me.layer.efis_path ~ "/nd/terrain-on-nd/max-color", -1,"INT"); # 0= grn, 1= yel, 2= red
var tile = me.tile;
var gx = int(me.viewport_radius / tile);
me.tileradius = gx;
var limx = int((512/tile)+0.5); # display width is smaller than height
me.tileradiusw = limx;
me.terrlayer = {};
var centx = 0;
var centy = -me.viewport_radius;
var group = me.group.createChild("group").set("z-index", -100); #me.element
for (var c=0; c<limx; c+=1) {
var hh = c * tile;
var mx = (c == 0) ? gx : int(math.sqrt(gx*gx-c*c) + 0.5);
var my = int(c*4/gx);
var py = centy + (gx-1) * tile;
var pxr = centx+(c*tile);
var pxl = centx-(c*tile)-tile;
var grplx = [];
var grprx = [];
for (var r=0; r<mx; r+=1) {
if (r<my) {
append(grplx , nil); #skip
append(grprx , nil);
} else {
append(grplx , group.createChild("image").setSize(tile,tile).setTranslation(pxl,py).hide());
append(grprx , group.createChild("image").setSize(tile,tile).setTranslation(pxr,py).hide());
}
py-=tile;
}
me.terrlayer["L" ~ c] = grplx;
me.terrlayer["R" ~ c] = grprx;
}
setlistener("/instrumentation/mk-viii/inputs/discretes/ta-tcf-inhibit", func{ # detect GPWS switch status
me.onfailure = getprop("/instrumentation/mk-viii/inputs/discretes/ta-tcf-inhibit");
},1,0);
};
var clear = func {
if (me.radar_cleared == 0) {
me.radar_cleared = 1;
for (var c=0; c<me.tileradiusw; c+=1 ) {
var rowL = me.terrlayer["L" ~ c];
var rowR = me.terrlayer["R" ~ c];
var len = size(rowL);
for (var r=0; r<len; r+=1) {
if (rowL[r] != nil) {
rowL[r].hide();
rowR[r].hide();
}
}
}
}
}
var draw = func {
if(me.fetching) return;
if (pts.Sim.pause.getBoolValue()) return;
if (me.onfailure == 1) {
me.clear();
me.restart_beacon();
return;
}
if (me.layer.display_hidden == 1) {
me.layer.display_hidden = 0;
me.clear();
me.terrain_maxalt.setValue(-9999);
me.min_altitude = 9999;
me.max_altitude = -9999;
me.avg_maxalt = -9999;
me.reference = nil;
}
if (me.reference == nil) { # update aircraft reference
var ref = geo.aircraft_position();
me.reference = ref;
if (ref != nil) {
me.refheading = getprop("orientation/heading-magnetic-deg");
var refalt = int(getprop("/position/altitude-ft")); #int(ref.alt() * 3.2808399);
me.refaltitudeft = refalt;
me.groundaltft = int(getprop("/position/ground-elev-ft"));
me.reflowaltft = (pts.Gear.position[1].getValue()) ? -250 : -500;
me.onground = pts.Gear.wow[0].getValue();
if (me.max_altitude != -9999) me.update_altitudes();
var flatalt = (me.avg_diffalt == nil or me.avg_diffalt>499) ? 400 : 180;
var vspeed30s = int(getprop("velocities/vertical-speed-fps") * 30);
if (vspeed30s<-500) me.refaltitudeft = math.max(me.avg_minalt , me.refaltitudeft + vspeed30s);
if (me.basealtitudeft == nil) { # first basealt set
me.basealtitudeft = me.groundaltft + flatalt;
me.flatalt = flatalt;
me.checkarrival = 1;
print("set REFALT [init]: "~me.basealtitudeft);
} else if (fmgc.FMGCInternal.phase < 2) { # starting at phase < 2
if (me.flatalt != flatalt) {
me.basealtitudeft = me.groundaltft + flatalt;
me.flatalt = flatalt;
print("set REFALT [flat]: "~me.basealtitudeft);
}
} else if (fmgc.FMGCInternal.phase == 5) {
if (me.checkarrival == 1) {
me.checkarrival = 0;
me.basealtitudeft = nil;
if (fmgc.FMGCInternal.arrApt != nil) {
var airport = airportinfo(fmgc.FMGCInternal.arrApt);
if (airport != nil) me.basealtitudeft = flatalt + int(airport.elevation * M2FT);
print("set REFALT [arrApt]: "~me.basealtitudeft);
}
if (me.basealtitudeft == nil) {
me.basealtitudeft = flatalt + me.avg_minalt; # that's fun
}
}
} else if (fmgc.FMGCInternal.phase == 6) {
if (me.checkarrival == 0) {
me.checkarrival = 1;
#me.basealtitudeft = 0;
}
} else if (fmgc.FMGCInternal.phase == 7) {
if (me.checkarrival == 0) {
me.checkarrival = 1;
me.basealtitudeft = me.groundaltft + flatalt;
print("set REFALT [done]: "~me.basealtitudeft);
}
} else if (fmgc.FMGCInternal.phase == 2) {
var expdaltft = me.groundaltft + flatalt;
if (me.basealtitudeft > expdaltft) {
me.basealtitudeft = expdaltft;
print("set REFALT [blwbase]: "~me.basealtitudeft);
}
} else if (fmgc.FMGCInternal.phase >= 2) {
if (me.avg_minalt != 9999) me.basealtitudeft = int(math.avg(me.basealtitudeft,flatalt + me.avg_minalt));
}
}
} else {
var range = me.layer.map.getRange(); # Range of Navigation Display
var update_size = (range != me.range);
me.range = range;
if (update_size) {
me.request_clear = 1;
}
me.updateTerrain(); # left
me.updateTerrain(); # right
}
};
View git blame Copy permalink