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fgdata/Aircraft/Instruments-3d/radardist/radardist.nas

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### Radar Visibility Calculator
# Jettoo (glazmax) and xiii (Alexis)
# my_maxrange(myaircraft): finds our own aircraft max radar range in a table.
# Returns my_radarcorr in kilometers, should be called from your own aircraft
# radar stuff.
# radis(i, my_radarcorr): find multiplayer[i], its Radar Cross Section (RCS),
# applies factor upon our altitude, shorter radar detection distance (due to air
# turbulence), then factor upon its altitude above ground, and finaly computes if
# it is detectable given our radar range.
# Returns 1 if detectable, 0 if not. Should be called from your own aircraft
# radar stuff too.
2008-10-05 14:47:21 +00:00
var data_path = getprop("/sim/fg-root") ~ "/Aircraft/Instruments-3d/radardist/radardist.xml";
var aircraftData = {};
var radarData = [];
mpnode_string = nil;
var cutname = nil;
var mpnode = nil;
var mpname_node_string = nil;
var mpname_node = nil;
var mpname = nil;
var splitname = nil;
var acname = nil;
var rcs_4r = nil;
var radartype = nil;
var alt_corr = nil;
var alt_ac = nil;
var agl_corr = nil;
var mp_lon = nil;
var mp_lat = nil;
var pos_elev = nil;
var mp_agl = nil;
var det_range = nil;
var act_range = nil;
var max_range = nil;
var radar_range = nil;
var radar_area = nil;
var have_radar = nil;
var FT2M = 0.3048;
var NM2KM = 1.852;
var my_maxrange = func(a) {
max_range = 0;
radar_range = 0;
radar_area = 0;
acname = aircraftData[a] or 0;
if ( acname ) {
have_radar = radarData[acname][4];
if ( have_radar != "none" and have_radar != "unknown") {
radar_area = radarData[acname][7];
radar_range = radarData[acname][5];
if ( radar_area > 0 ) { max_range = radar_range / radar_area }
}
}
return( max_range );
}
var get_ecm_type_num = func(a) {
acname = aircraftData[a] or 0;
var num = 0;
if ( acname ) {
num = radarData[acname][8];
}
return( num );
}
var get_aircraft_name = func( t ) {
# Get the multiplayer aircraft name.
mpnode_string = t;
mpnode = props.globals.getNode(mpnode_string);
if ( find("tanker", mpnode_string) > 0 ) {
cutname = "KC135";
} else {
mpname_node_string = mpnode_string ~ "/sim/model/path";
mpname_node = props.globals.getNode(mpname_node_string);
if (mpname_node == nil) { return(0) }
var mpname = mpname_node.getValue();
if (mpname == nil) { return(0) }
splitname = split("/", mpname);
cutname = splitname[1];
}
return( cutname );
}
var radis = func(t, my_radarcorr) {
cutname = get_aircraft_name(t);
# Calculate the rcs detection range,
# if aircraft is not found in list, 0 (generic) will be used.
acname = aircraftData[cutname];
if ( acname == nil ) { acname = 0 }
rcs_4r = radarData[acname][3];
# Add a correction factor for altitude, as lower alt means
# shorter radar distance (due to air turbulence).
alt_corr = 1;
alt_ac = mpnode.getNode("position/altitude-ft").getValue();
if (alt_ac <= 1000) {
alt_corr = 0.6;
} elsif ((alt_ac > 1000) and (alt_ac <= 5000)) {
alt_corr = 0.8;
}
# Add a correction factor for altitude AGL. Skip if AI tanker.
agl_corr = 1;
if ( find("tanker", t) == 0 ) {
mp_lon = mpnode.getNode("position/longitude-deg").getValue();
pos_elev = geo.elevation(mp_lat, mp_lon);
if (pos_elev != nil) {
mp_agl = alt_ac - ( pos_elev / FT2M );
if (mp_agl <= 40) {
agl_corr = 0.03;
} elsif ((mp_agl > 40) and (mp_agl <= 80)) {
agl_corr = 0.07;
} elsif ((mp_agl > 80) and (mp_agl <= 120)) {
agl_corr = 0.25;
} elsif ((mp_agl > 120) and (mp_agl <= 300)) {
agl_corr = 0.4;
} elsif ((mp_agl > 300) and (mp_agl <= 600)) {
agl_corr = 0.7;
} elsif ((mp_agl > 600) and (mp_agl <= 1000)) {
agl_corr = 0.85;
}
}
}
# Calculate the detection distance for this multiplayer.
det_range = my_radarcorr * rcs_4r * alt_corr * agl_corr / NM2KM;
# Compare if aircraft is in detection range and return.
act_range = mpnode.getNode("radar/range-nm").getValue() or 500;
if (det_range >= act_range) {
return(1);
}
return(0);
}
var radar_horizon = func(our_alt_ft, target_alt_ft) {
if (our_alt_ft < 0 or our_alt_ft == nil) { our_alt_ft = 0 }
if (target_alt_ft < 0 or target_alt_ft == nil) { target_alt_ft = 0 }
return( 2.2 * ( math.sqrt(our_alt_ft * FT2M) + math.sqrt(target_alt_ft * FT2M) ) );
}
var load_data = func {
# a) converts aircraft model name to lookup (index) number in aircraftData{}.
# b) appends ordered list of data into radarData[],
# data is:
# - acname (the index number)
# - the first (if several) aircraft model name corresponding to this type,
# - RCS(m2),
# - 4th root of RCS,
# - radar type,
# - max. radar range(km),
# - max. radar range target seize(RCS)m2,
# - 4th root of radar RCS.
var data_node = props.globals.getNode("instrumentation/radar-performance/data");
var aircraft_types = data_node.getChildren();
foreach( var t; aircraft_types ) {
var index = t.getIndex();
var aircraft_names = t.getChildren();
foreach( var n; aircraft_names) {
if ( n.getName() == "name") {
aircraftData[n.getValue()] = index;
}
}
var t_list = [
index,
t.getNode("name[0]").getValue(),
t.getNode("rcs-sq-meter").getValue(),
t.getNode("rcs-4th-root").getValue(),
t.getNode("radar-type").getValue(),
t.getNode("max-radar-rng-km").getValue(),
t.getNode("max-target-sq-meter").getValue(),
t.getNode("max-target-4th-root").getValue(),
t.getNode("ecm-type-num").getValue()
];
append(radarData, t_list);
}
}
var launched = 0;
var init = func {
if (! launched) {
print("Initializing Radar Data");
io.read_properties(data_path, props.globals);
load_data();
launched = 1;
}
}