1 // radio.cxx -- implementation of FGRadio
2 // Class to manage radio propagation using the ITM model
3 // Written by Adrian Musceac, started August 2011.
5 // This program is free software; you can redistribute it and/or
6 // modify it under the terms of the GNU General Public License as
7 // published by the Free Software Foundation; either version 2 of the
8 // License, or (at your option) any later version.
10 // This program is distributed in the hope that it will be useful, but
11 // WITHOUT ANY WARRANTY; without even the implied warranty of
12 // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
13 // General Public License for more details.
15 // You should have received a copy of the GNU General Public License
16 // along with this program; if not, write to the Free Software
17 // Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
29 #include <simgear/scene/material/mat.hxx>
30 #include <Scenery/scenery.hxx>
32 #define WITH_POINT_TO_POINT 1
38 /** radio parameters (which should probably be set for each radio) */
40 _receiver_sensitivity = -110.0; // typical AM receiver sensitivity seems to be 0.8 microVolt at 12dB SINAD
42 /** AM transmitter power in dBm.
43 * Note this value is calculated from the typical final transistor stage output
44 * small aircraft have portable transmitters which operate at 36 dBm output (4 Watts) others operate in the range 10-20 W
45 * later possibly store this value in aircraft description
46 * ATC comms usually operate high power equipment, thus making the link asymetrical; this is taken care of in propagation routines
47 * Typical output powers for ATC ground equipment, VHF-UHF:
48 * 40 dBm - 10 W (ground, clearance)
49 * 44 dBm - 20 W (tower)
50 * 47 dBm - 50 W (center, sectors)
51 * 50 dBm - 100 W (center, sectors)
52 * 53 dBm - 200 W (sectors, on directional arrays)
54 _transmitter_power = 43.0;
56 /** pilot plane's antenna gain + AI aircraft antenna gain
57 * real-life gain for conventional monopole/dipole antenna
60 _propagation_model = 2; // choose between models via option: realistic radio on/off
69 double FGRadio::getFrequency(int radio) {
73 freq = fgGetDouble("/instrumentation/comm[0]/frequencies/selected-mhz");
76 freq = fgGetDouble("/instrumentation/comm[1]/frequencies/selected-mhz");
79 freq = fgGetDouble("/instrumentation/comm[0]/frequencies/selected-mhz");
85 /*** TODO: receive multiplayer chat message and voice
87 void FGRadio::receiveChat(SGGeod tx_pos, double freq, string text, int ground_to_air) {
91 /*** TODO: receive navaid
93 double FGRadio::receiveNav(SGGeod tx_pos, double freq, int transmission_type) {
95 // typical VOR/LOC transmitter power appears to be 200 Watt ~ 53 dBm
96 // vor/loc typical sensitivity between -107 and -101 dBm
97 // glideslope sensitivity between -85 and -81 dBm
98 if ( _propagation_model == 1) {
99 return LOS_calculate_attenuation(tx_pos, freq, 1);
101 else if ( _propagation_model == 2) {
102 return ITM_calculate_attenuation(tx_pos, freq, 1);
109 /*** Receive ATC radio communication as text
111 void FGRadio::receiveATC(SGGeod tx_pos, double freq, string text, int ground_to_air) {
114 double comm1 = getFrequency(1);
115 double comm2 = getFrequency(2);
116 if ( !(fabs(freq - comm1) <= 0.0001) && !(fabs(freq - comm2) <= 0.0001) ) {
117 //cerr << "Frequency not tuned: " << freq << " Radio1: " << comm1 << " Radio2: " << comm2 << endl;
122 if ( _propagation_model == 0) {
123 fgSetString("/sim/messages/atc", text.c_str());
125 else if ( _propagation_model == 1 ) {
126 // TODO: free space, round earth
127 double signal = LOS_calculate_attenuation(tx_pos, freq, ground_to_air);
129 SG_LOG(SG_GENERAL, SG_BULK, "Signal below receiver minimum sensitivity: " << signal);
130 //cerr << "Signal below receiver minimum sensitivity: " << signal << endl;
134 SG_LOG(SG_GENERAL, SG_BULK, "Signal completely readable: " << signal);
135 //cerr << "Signal completely readable: " << signal << endl;
136 fgSetString("/sim/messages/atc", text.c_str());
137 /** write signal strength above threshold to the property tree
138 * to implement a simple S-meter just divide by 3 dB per grade (VHF norm)
140 fgSetDouble("/sim/radio/comm1-signal", signal);
143 else if ( _propagation_model == 2 ) {
144 // Use ITM propagation model
145 double signal = ITM_calculate_attenuation(tx_pos, freq, ground_to_air);
147 SG_LOG(SG_GENERAL, SG_BULK, "Signal below receiver minimum sensitivity: " << signal);
148 //cerr << "Signal below receiver minimum sensitivity: " << signal << endl;
151 if ((signal > 0.0) && (signal < 12.0)) {
152 /** for low SNR values implement a way to make the conversation
153 * hard to understand but audible
154 * in the real world, the receiver AGC fails to capture the slope
155 * and the signal, due to being amplitude modulated, decreases volume after demodulation
156 * the workaround below is more akin to what would happen on a FM transmission
157 * therefore the correct way would be to work on the volume
160 string hash_noise = " ";
161 int reps = (int) (fabs(floor(signal - 11.0)) * 2);
162 int t_size = text.size();
163 for (int n = 1; n <= reps; ++n) {
164 int pos = rand() % (t_size -1);
165 text.replace(pos,1, hash_noise);
168 double volume = (fabs(signal - 12.0) / 12);
169 double old_volume = fgGetDouble("/sim/sound/voices/voice/volume");
170 SG_LOG(SG_GENERAL, SG_BULK, "Usable signal at limit: " << signal);
171 //cerr << "Usable signal at limit: " << signal << endl;
172 fgSetDouble("/sim/sound/voices/voice/volume", volume);
173 fgSetString("/sim/messages/atc", text.c_str());
174 fgSetDouble("/sim/radio/comm1-signal", signal);
175 fgSetDouble("/sim/sound/voices/voice/volume", old_volume);
178 SG_LOG(SG_GENERAL, SG_BULK, "Signal completely readable: " << signal);
179 //cerr << "Signal completely readable: " << signal << endl;
180 fgSetString("/sim/messages/atc", text.c_str());
181 /** write signal strength above threshold to the property tree
182 * to implement a simple S-meter just divide by 3 dB per grade (VHF norm)
184 fgSetDouble("/sim/radio/comm1-signal", signal);
193 /*** Implement radio attenuation
194 based on the Longley-Rice propagation model
196 double FGRadio::ITM_calculate_attenuation(SGGeod pos, double freq, int transmission_type) {
200 /** ITM default parameters
201 TODO: take them from tile materials (especially for sea)?
203 double eps_dielect=15.0;
204 double sgm_conductivity = 0.005;
207 if( (freq < 118.0) || (freq > 137.0) )
208 frq_mhz = 125.0; // sane value, middle of bandplan
211 int radio_climate = 5; // continental temperate
212 int pol=1; // assuming vertical polarization although this is more complex in reality
213 double conf = 0.90; // 90% of situations and time, take into account speed
217 int p_mode = 0; // propgation mode selector: 0 LOS, 1 diffraction dominant, 2 troposcatter
221 double clutter_loss = 0.0; // loss due to vegetation and urban
222 double tx_pow = _transmitter_power;
223 double ant_gain = _antenna_gain;
226 if(transmission_type == 1)
227 tx_pow = _transmitter_power + 6.0;
229 if((transmission_type == 1) || (transmission_type == 3))
230 ant_gain = _antenna_gain + 3.0; //pilot plane's antenna gain + ground station antenna gain
232 double link_budget = tx_pow - _receiver_sensitivity + ant_gain;
234 FGScenery * scenery = globals->get_scenery();
236 double own_lat = fgGetDouble("/position/latitude-deg");
237 double own_lon = fgGetDouble("/position/longitude-deg");
238 double own_alt_ft = fgGetDouble("/position/altitude-ft");
239 double own_alt= own_alt_ft * SG_FEET_TO_METER;
242 //cerr << "ITM:: pilot Lat: " << own_lat << ", Lon: " << own_lon << ", Alt: " << own_alt << endl;
244 SGGeod own_pos = SGGeod::fromDegM( own_lon, own_lat, own_alt );
245 SGGeod max_own_pos = SGGeod::fromDegM( own_lon, own_lat, SG_MAX_ELEVATION_M );
246 SGGeoc center = SGGeoc::fromGeod( max_own_pos );
247 SGGeoc own_pos_c = SGGeoc::fromGeod( own_pos );
249 /** position of sender radio antenna (HAAT)
250 sender can be aircraft or ground station
252 double ATC_HAAT = 30.0;
253 double Aircraft_HAAT = 5.0;
254 double sender_alt_ft,sender_alt;
255 double transmitter_height=0.0;
256 double receiver_height=0.0;
257 SGGeod sender_pos = pos;
259 sender_alt_ft = sender_pos.getElevationFt();
260 sender_alt = sender_alt_ft * SG_FEET_TO_METER;
261 SGGeod max_sender_pos = SGGeod::fromGeodM( pos, SG_MAX_ELEVATION_M );
262 SGGeoc sender_pos_c = SGGeoc::fromGeod( sender_pos );
263 //cerr << "ITM:: sender Lat: " << parent->getLatitude() << ", Lon: " << parent->getLongitude() << ", Alt: " << sender_alt << endl;
265 double point_distance= 90.0; // regular SRTM is 90 meters
266 double course = SGGeodesy::courseRad(own_pos_c, sender_pos_c);
267 double distance_m = SGGeodesy::distanceM(own_pos, sender_pos);
268 double probe_distance = 0.0;
269 /** If distance larger than this value (300 km), assume reception imposssible */
270 if (distance_m > 300000)
272 /** If above 8000 meters, consider LOS mode and calculate free-space att */
273 if (own_alt > 8000) {
274 dbloss = 20 * log10(distance_m) +20 * log10(frq_mhz) -27.55;
275 SG_LOG(SG_GENERAL, SG_BULK,
276 "ITM Free-space mode:: Link budget: " << link_budget << ", Attenuation: " << dbloss << " dBm, free-space attenuation");
277 //cerr << "ITM Free-space mode:: Link budget: " << link_budget << ", Attenuation: " << dbloss << " dBm, free-space attenuation" << endl;
278 signal = link_budget - dbloss;
283 double max_points = distance_m / point_distance;
284 deque<double> _elevations;
285 deque<string> materials;
288 double elevation_under_pilot = 0.0;
289 if (scenery->get_elevation_m( max_own_pos, elevation_under_pilot, NULL )) {
290 receiver_height = own_alt - elevation_under_pilot + 3; //assume antenna located 3 meters above ground
293 double elevation_under_sender = 0.0;
294 if (scenery->get_elevation_m( max_sender_pos, elevation_under_sender, NULL )) {
295 transmitter_height = sender_alt - elevation_under_sender;
298 transmitter_height = sender_alt;
301 if(transmission_type == 1)
302 transmitter_height += ATC_HAAT;
304 transmitter_height += Aircraft_HAAT;
306 SG_LOG(SG_GENERAL, SG_BULK,
307 "ITM:: RX-height: " << receiver_height << " meters, TX-height: " << transmitter_height << " meters, Distance: " << distance_m << " meters");
308 cerr << "ITM:: RX-height: " << receiver_height << " meters, TX-height: " << transmitter_height << " meters, Distance: " << distance_m << " meters" << endl;
310 unsigned int e_size = (deque<unsigned>::size_type)max_points;
312 while (_elevations.size() <= e_size) {
313 probe_distance += point_distance;
314 SGGeod probe = SGGeod::fromGeoc(center.advanceRadM( course, probe_distance ));
315 const SGMaterial *mat = 0;
316 double elevation_m = 0.0;
318 if (scenery->get_elevation_m( probe, elevation_m, &mat )) {
319 if((transmission_type == 3) || (transmission_type == 4)) {
320 _elevations.push_back(elevation_m);
322 const std::vector<string> mat_names = mat->get_names();
323 materials.push_back(mat_names[0]);
326 materials.push_back("None");
330 _elevations.push_front(elevation_m);
332 const std::vector<string> mat_names = mat->get_names();
333 materials.push_front(mat_names[0]);
336 materials.push_front("None");
341 if((transmission_type == 3) || (transmission_type == 4)) {
342 _elevations.push_back(0.0);
343 materials.push_back("None");
346 _elevations.push_front(0.0);
347 materials.push_front("None");
351 if((transmission_type == 3) || (transmission_type == 4)) {
352 _elevations.push_front(elevation_under_pilot);
353 _elevations.push_back(elevation_under_sender);
356 _elevations.push_back(elevation_under_pilot);
357 _elevations.push_front(elevation_under_sender);
361 double max_alt_between=0.0;
362 for( deque<double>::size_type i = 0; i < _elevations.size(); i++ ) {
363 if (_elevations[i] > max_alt_between) {
364 max_alt_between = _elevations[i];
368 double num_points= (double)_elevations.size();
369 //cerr << "ITM:: Max alt between: " << max_alt_between << ", num points:" << num_points << endl;
370 _elevations.push_front(point_distance);
371 _elevations.push_front(num_points -1);
372 int size = _elevations.size();
373 double itm_elev[size];
374 for(int i=0;i<size;i++) {
375 itm_elev[i]=_elevations[i];
376 //cerr << "ITM:: itm_elev: " << _elevations[i] << endl;
379 if((transmission_type == 3) || (transmission_type == 4)) {
380 // the sender and receiver roles are switched
381 point_to_point(itm_elev, receiver_height, transmitter_height,
382 eps_dielect, sgm_conductivity, eno, frq_mhz, radio_climate,
383 pol, conf, rel, dbloss, strmode, p_mode, horizons, errnum);
384 if( fgGetBool( "/sim/radio/use-clutter-attenuation", false ) )
385 clutterLoss(frq_mhz, distance_m, itm_elev, materials, receiver_height, transmitter_height, p_mode, horizons, clutter_loss);
388 point_to_point(itm_elev, transmitter_height, receiver_height,
389 eps_dielect, sgm_conductivity, eno, frq_mhz, radio_climate,
390 pol, conf, rel, dbloss, strmode, p_mode, horizons, errnum);
391 if( fgGetBool( "/sim/radio/use-clutter-attenuation", false ) )
392 clutterLoss(frq_mhz, distance_m, itm_elev, materials, transmitter_height, receiver_height, p_mode, horizons, clutter_loss);
394 SG_LOG(SG_GENERAL, SG_BULK,
395 "ITM:: Link budget: " << link_budget << ", Attenuation: " << dbloss << " dBm, " << strmode << ", Error: " << errnum);
396 cerr << "ITM:: Link budget: " << link_budget << ", Attenuation: " << dbloss << " dBm, " << strmode << ", Error: " << errnum << endl;
398 cerr << "Clutter loss: " << clutter_loss << endl;
399 //if (errnum == 4) // if parameters are outside sane values for lrprop, the alternative method is used
401 signal = link_budget - dbloss - clutter_loss;
406 /*** Calculate losses due to vegetation and urban clutter (WIP)
407 * We are only worried about clutter loss, terrain influence
408 * on the first Fresnel zone is calculated in the ITM functions
410 void FGRadio::clutterLoss(double freq, double distance_m, double itm_elev[], deque<string> materials,
411 double transmitter_height, double receiver_height, int p_mode,
412 double horizons[], double &clutter_loss) {
414 if (p_mode == 0) { // LOS: take each point and see how clutter height affects first Fresnel zone
416 int j=1; // first point is TX elevation, last is RX elevation
417 for (int k=3;k < (int)itm_elev[0];k++) {
419 double clutter_height = 0.0; // mean clutter height for a certain terrain type
420 double clutter_density = 0.0; // percent of reflected wave
421 get_material_properties(materials[mat], clutter_height, clutter_density);
422 //cerr << "Clutter:: material: " << materials[mat] << " height: " << clutter_height << ", density: " << clutter_density << endl;
423 double grad = fabs(itm_elev[2] + transmitter_height - itm_elev[(int)itm_elev[0] + 1] + receiver_height) / distance_m;
424 // First Fresnel radius
425 double frs_rad = 548 * sqrt( (j * itm_elev[1] * (itm_elev[0] - j) * itm_elev[1] / 1000000) / ( distance_m * freq / 1000) );
427 //cerr << "Clutter:: fresnel radius: " << frs_rad << endl;
428 //double earth_h = distance_m * (distance_m - j * itm_elev[1]) / ( 1000000 * 12.75 * 1.33 ); // K=4/3
430 double min_elev = SGMiscd::min(itm_elev[2] + transmitter_height, itm_elev[(int)itm_elev[0] + 1] + receiver_height);
431 double d1 = j * itm_elev[1];
432 if ((itm_elev[2] + transmitter_height) > ( itm_elev[(int)itm_elev[0] + 1] + receiver_height) ) {
433 d1 = (itm_elev[0] - j) * itm_elev[1];
435 double ray_height = (grad * d1) + min_elev;
436 //cerr << "Clutter:: ray height: " << ray_height << " ground height:" << itm_elev[k] << endl;
437 double clearance = ray_height - (itm_elev[k] + clutter_height) - frs_rad * 8/10;
438 double intrusion = fabs(clearance);
439 //cerr << "Clutter:: clearance: " << clearance << endl;
440 if (clearance >= 0) {
443 else if (clearance < 0 && (intrusion < clutter_height)) {
445 clutter_loss += clutter_density * (intrusion / (frs_rad * 2) ) * freq/100;
447 else if (clearance < 0 && (intrusion > clutter_height)) {
448 clutter_loss += clutter_density * (clutter_height / (frs_rad * 2 ) ) * freq/100;
458 else if (p_mode == 1) { // diffraction
460 if (horizons[1] == 0.0) { // single horizon: same as above, except pass twice using the highest point
461 int num_points_1st = (int)floor( horizons[0] * (double)itm_elev[0] / distance_m );
462 int num_points_2nd = (int)floor( (distance_m - horizons[0]) * (double)itm_elev[0] / distance_m );
464 /** perform the first pass */
466 int j=1; // first point is TX elevation, 2nd is obstruction elevation
467 for (int k=3;k < num_points_1st ;k++) {
469 double clutter_height = 0.0; // mean clutter height for a certain terrain type
470 double clutter_density = 0.0; // percent of reflected wave
471 get_material_properties(materials[mat], clutter_height, clutter_density);
472 //cerr << "Clutter:: material: " << materials[mat] << " height: " << clutter_height << ", density: " << clutter_density << endl;
473 double grad = fabs(itm_elev[2] + transmitter_height - itm_elev[num_points_1st + 1] + clutter_height) / distance_m;
474 // First Fresnel radius
475 double frs_rad = 548 * sqrt( (j * itm_elev[1] * (num_points_1st - j) * itm_elev[1] / 1000000) / ( num_points_1st * itm_elev[1] * freq / 1000) );
477 //cerr << "Clutter:: fresnel radius: " << frs_rad << endl;
478 //double earth_h = distance_m * (distance_m - j * itm_elev[1]) / ( 1000000 * 12.75 * 1.33 ); // K=4/3
480 double min_elev = SGMiscd::min(itm_elev[2] + transmitter_height, itm_elev[num_points_1st + 1] + clutter_height);
481 double d1 = j * itm_elev[1];
482 if ( (itm_elev[2] + transmitter_height) > (itm_elev[num_points_1st + 1] + clutter_height) ) {
483 d1 = (num_points_1st - j) * itm_elev[1];
485 double ray_height = (grad * d1) + min_elev;
486 //cerr << "Clutter:: ray height: " << ray_height << " ground height:" << itm_elev[k] << endl;
487 double clearance = ray_height - (itm_elev[k] + clutter_height) - frs_rad * 8/10;
488 double intrusion = fabs(clearance);
489 //cerr << "Clutter:: clearance: " << clearance << endl;
490 if (clearance >= 0) {
493 else if (clearance < 0 && (intrusion < clutter_height)) {
495 clutter_loss += clutter_density * (intrusion / (frs_rad * 2) ) * freq/100;
497 else if (clearance < 0 && (intrusion > clutter_height)) {
498 clutter_loss += clutter_density * (clutter_height / (frs_rad * 2 ) ) * freq/100;
508 /** and the second pass */
510 int l =1; // first point is diffraction edge, 2nd the RX elevation
511 for (int k=last+1;k < num_points_2nd ;k++) {
513 double clutter_height = 0.0; // mean clutter height for a certain terrain type
514 double clutter_density = 0.0; // percent of reflected wave
515 get_material_properties(materials[mat], clutter_height, clutter_density);
516 //cerr << "Clutter:: material: " << materials[mat] << " height: " << clutter_height << ", density: " << clutter_density << endl;
517 double grad = fabs(itm_elev[last] + clutter_height - itm_elev[(int)itm_elev[0] + 1] + receiver_height) / distance_m;
518 // First Fresnel radius
519 double frs_rad = 548 * sqrt( (l * itm_elev[1] * (num_points_2nd - l) * itm_elev[1] / 1000000) / ( num_points_2nd * itm_elev[1] * freq / 1000) );
521 //cerr << "Clutter:: fresnel radius: " << frs_rad << endl;
522 //double earth_h = distance_m * (distance_m - j * itm_elev[1]) / ( 1000000 * 12.75 * 1.33 ); // K=4/3
524 double min_elev = SGMiscd::min(itm_elev[last] + clutter_height, itm_elev[(int)itm_elev[0] + 1] + receiver_height);
525 double d1 = l * itm_elev[1];
526 if ( (itm_elev[last] + clutter_height) > (itm_elev[(int)itm_elev[0] + 1] + receiver_height) ) {
527 d1 = (num_points_2nd - l) * itm_elev[1];
529 double ray_height = (grad * d1) + min_elev;
530 //cerr << "Clutter:: ray height: " << ray_height << " ground height:" << itm_elev[k] << endl;
531 double clearance = ray_height - (itm_elev[k] + clutter_height) - frs_rad * 8/10;
532 double intrusion = fabs(clearance);
533 //cerr << "Clutter:: clearance: " << clearance << endl;
534 if (clearance >= 0) {
537 else if (clearance < 0 && (intrusion < clutter_height)) {
539 clutter_loss += clutter_density * (intrusion / (frs_rad * 2) ) * freq/100;
541 else if (clearance < 0 && (intrusion > clutter_height)) {
542 clutter_loss += clutter_density * (clutter_height / (frs_rad * 2 ) ) * freq/100;
553 else { // double horizon: same as single horizon, except there are 3 segments
555 int num_points_1st = (int)floor( horizons[0] * (double)itm_elev[0] / distance_m );
556 int num_points_2nd = (int)floor( (horizons[1] - horizons[0]) * (double)itm_elev[0] / distance_m );
557 int num_points_3rd = (int)floor( (distance_m - horizons[1]) * (double)itm_elev[0] / distance_m );
559 /** perform the first pass */
561 int j=1; // first point is TX elevation, 2nd is obstruction elevation
562 for (int k=3;k < num_points_1st ;k++) {
564 double clutter_height = 0.0; // mean clutter height for a certain terrain type
565 double clutter_density = 0.0; // percent of reflected wave
566 get_material_properties(materials[mat], clutter_height, clutter_density);
567 //cerr << "Clutter:: material: " << materials[mat] << " height: " << clutter_height << ", density: " << clutter_density << endl;
568 double grad = fabs(itm_elev[2] + transmitter_height - itm_elev[num_points_1st + 1] + clutter_height) / distance_m;
569 // First Fresnel radius
570 double frs_rad = 548 * sqrt( (j * itm_elev[1] * (num_points_1st - j) * itm_elev[1] / 1000000) / ( num_points_1st * itm_elev[1] * freq / 1000) );
572 //cerr << "Clutter:: fresnel radius: " << frs_rad << endl;
573 //double earth_h = distance_m * (distance_m - j * itm_elev[1]) / ( 1000000 * 12.75 * 1.33 ); // K=4/3
575 double min_elev = SGMiscd::min(itm_elev[2] + transmitter_height, itm_elev[num_points_1st + 1] + clutter_height);
576 double d1 = j * itm_elev[1];
577 if ( (itm_elev[2] + transmitter_height) > (itm_elev[num_points_1st + 1] + clutter_height) ) {
578 d1 = (num_points_1st - j) * itm_elev[1];
580 double ray_height = (grad * d1) + min_elev;
581 //cerr << "Clutter:: ray height: " << ray_height << " ground height:" << itm_elev[k] << endl;
582 double clearance = ray_height - (itm_elev[k] + clutter_height) - frs_rad * 8/10;
583 double intrusion = fabs(clearance);
584 //cerr << "Clutter:: clearance: " << clearance << endl;
585 if (clearance >= 0) {
588 else if (clearance < 0 && (intrusion < clutter_height)) {
590 clutter_loss += clutter_density * (intrusion / (frs_rad * 2) ) * freq/100;
592 else if (clearance < 0 && (intrusion > clutter_height)) {
593 clutter_loss += clutter_density * (clutter_height / (frs_rad * 2 ) ) * freq/100;
602 /** and the second pass */
604 int l =1; // first point is 1st obstruction elevation, 2nd is 2nd obstruction elevation
605 for (int k=last;k < num_points_2nd ;k++) {
607 double clutter_height = 0.0; // mean clutter height for a certain terrain type
608 double clutter_density = 0.0; // percent of reflected wave
609 get_material_properties(materials[mat], clutter_height, clutter_density);
610 //cerr << "Clutter:: material: " << materials[mat] << " height: " << clutter_height << ", density: " << clutter_density << endl;
611 double grad = fabs(itm_elev[last] + clutter_height - itm_elev[num_points_1st + num_points_2nd + 1] + clutter_height) / distance_m;
612 // First Fresnel radius
613 double frs_rad = 548 * sqrt( (l * itm_elev[1] * (num_points_2nd - j) * itm_elev[1] / 1000000) / ( num_points_2nd * itm_elev[1] * freq / 1000) );
615 //cerr << "Clutter:: fresnel radius: " << frs_rad << endl;
616 //double earth_h = distance_m * (distance_m - j * itm_elev[1]) / ( 1000000 * 12.75 * 1.33 ); // K=4/3
618 double min_elev = SGMiscd::min(itm_elev[last] + clutter_height, itm_elev[num_points_1st + num_points_2nd + 2] + clutter_height);
619 double d1 = l * itm_elev[1];
620 if ( (itm_elev[last] + clutter_height) > (itm_elev[num_points_1st + num_points_2nd + 1] + clutter_height) ) {
621 d1 = (num_points_2nd - l) * itm_elev[1];
623 double ray_height = (grad * d1) + min_elev;
624 //cerr << "Clutter:: ray height: " << ray_height << " ground height:" << itm_elev[k] << endl;
625 double clearance = ray_height - (itm_elev[k] + clutter_height) - frs_rad * 8/10;
626 double intrusion = fabs(clearance);
627 //cerr << "Clutter:: clearance: " << clearance << endl;
628 if (clearance >= 0) {
631 else if (clearance < 0 && (intrusion < clutter_height)) {
633 clutter_loss += clutter_density * (intrusion / (frs_rad * 2) ) * freq/100;
635 else if (clearance < 0 && (intrusion > clutter_height)) {
636 clutter_loss += clutter_density * (clutter_height / (frs_rad * 2 ) ) * freq/100;
647 /** third and final pass */
649 int m =1; // first point is 2nd obstruction elevation, 3rd is RX elevation
650 for (int k=last;k < num_points_3rd ;k++) {
652 double clutter_height = 0.0; // mean clutter height for a certain terrain type
653 double clutter_density = 0.0; // percent of reflected wave
654 get_material_properties(materials[mat], clutter_height, clutter_density);
655 //cerr << "Clutter:: material: " << materials[mat] << " height: " << clutter_height << ", density: " << clutter_density << endl;
656 double grad = fabs(itm_elev[last] + clutter_height - itm_elev[(int)itm_elev[0] + 1] + receiver_height) / distance_m;
657 // First Fresnel radius
658 double frs_rad = 548 * sqrt( (m * itm_elev[1] * (num_points_3rd - m) * itm_elev[1] / 1000000) / ( num_points_3rd * itm_elev[1] * freq / 1000) );
660 //cerr << "Clutter:: fresnel radius: " << frs_rad << endl;
661 //double earth_h = distance_m * (distance_m - j * itm_elev[1]) / ( 1000000 * 12.75 * 1.33 ); // K=4/3
663 double min_elev = SGMiscd::min(itm_elev[last] + clutter_height, itm_elev[(int)itm_elev[0] + 1] + receiver_height);
664 double d1 = m * itm_elev[1];
665 if ( (itm_elev[last] + clutter_height) > (itm_elev[(int)itm_elev[0] + 1] + receiver_height) ) {
666 d1 = (num_points_3rd - m) * itm_elev[1];
668 double ray_height = (grad * d1) + min_elev;
669 //cerr << "Clutter:: ray height: " << ray_height << " ground height:" << itm_elev[k] << endl;
670 double clearance = ray_height - (itm_elev[k] + clutter_height) - frs_rad * 8/10;
671 double intrusion = fabs(clearance);
672 //cerr << "Clutter:: clearance: " << clearance << endl;
673 if (clearance >= 0) {
676 else if (clearance < 0 && (intrusion < clutter_height)) {
678 clutter_loss += clutter_density * (intrusion / (frs_rad * 2) ) * freq/100;
680 else if (clearance < 0 && (intrusion > clutter_height)) {
681 clutter_loss += clutter_density * (clutter_height / (frs_rad * 2 ) ) * freq/100;
694 else if (p_mode == 2) { // troposcatter: ignore ground clutter for now...
700 /*** Temporary material properties database
701 * height: median clutter height
702 * density: radiowave attenuation factor
704 void FGRadio::get_material_properties(string mat_name, double &height, double &density) {
706 if(mat_name == "Landmass") {
711 else if(mat_name == "SomeSort") {
716 else if(mat_name == "Island") {
720 else if(mat_name == "Default") {
724 else if(mat_name == "EvergreenBroadCover") {
728 else if(mat_name == "EvergreenForest") {
732 else if(mat_name == "DeciduousBroadCover") {
736 else if(mat_name == "DeciduousForest") {
740 else if(mat_name == "MixedForestCover") {
744 else if(mat_name == "MixedForest") {
748 else if(mat_name == "RainForest") {
752 else if(mat_name == "EvergreenNeedleCover") {
756 else if(mat_name == "WoodedTundraCover") {
760 else if(mat_name == "DeciduousNeedleCover") {
764 else if(mat_name == "ScrubCover") {
768 else if(mat_name == "BuiltUpCover") {
772 else if(mat_name == "Urban") {
776 else if(mat_name == "Construction") {
780 else if(mat_name == "Industrial") {
784 else if(mat_name == "Port") {
788 else if(mat_name == "Town") {
792 else if(mat_name == "SubUrban") {
796 else if(mat_name == "CropWoodCover") {
800 else if(mat_name == "CropWood") {
804 else if(mat_name == "AgroForest") {
815 /*** implement simple LOS propagation model (WIP)
817 double FGRadio::LOS_calculate_attenuation(SGGeod pos, double freq, int transmission_type) {
819 if( (freq < 118.0) || (freq > 137.0) )
820 frq_mhz = 125.0; // sane value, middle of bandplan
824 double tx_pow = _transmitter_power;
825 double ant_gain = _antenna_gain;
827 double ATC_HAAT = 30.0;
828 double Aircraft_HAAT = 5.0;
829 double sender_alt_ft,sender_alt;
830 double transmitter_height=0.0;
831 double receiver_height=0.0;
832 double own_lat = fgGetDouble("/position/latitude-deg");
833 double own_lon = fgGetDouble("/position/longitude-deg");
834 double own_alt_ft = fgGetDouble("/position/altitude-ft");
835 double own_alt= own_alt_ft * SG_FEET_TO_METER;
837 if(transmission_type == 1)
838 tx_pow = _transmitter_power + 6.0;
840 if((transmission_type == 1) || (transmission_type == 3))
841 ant_gain = _antenna_gain + 3.0; //pilot plane's antenna gain + ground station antenna gain
843 double link_budget = tx_pow - _receiver_sensitivity + ant_gain;
845 //cerr << "ITM:: pilot Lat: " << own_lat << ", Lon: " << own_lon << ", Alt: " << own_alt << endl;
847 SGGeod own_pos = SGGeod::fromDegM( own_lon, own_lat, own_alt );
849 SGGeod sender_pos = pos;
851 sender_alt_ft = sender_pos.getElevationFt();
852 sender_alt = sender_alt_ft * SG_FEET_TO_METER;
854 receiver_height = own_alt;
855 transmitter_height = sender_alt;
857 double distance_m = SGGeodesy::distanceM(own_pos, sender_pos);
859 if(transmission_type == 1)
860 transmitter_height += ATC_HAAT;
862 transmitter_height += Aircraft_HAAT;
864 /** radio horizon calculation with wave bending k=4/3 */
865 double receiver_horizon = 4.12 * sqrt(receiver_height);
866 double transmitter_horizon = 4.12 * sqrt(transmitter_height);
867 double total_horizon = receiver_horizon + transmitter_horizon;
869 if (distance_m > total_horizon) {
873 // free-space loss (distance calculation should be changed)
874 dbloss = 20 * log10(distance_m) +20 * log10(frq_mhz) -27.55;
875 signal = link_budget - dbloss;
876 SG_LOG(SG_GENERAL, SG_BULK,
877 "LOS:: Link budget: " << link_budget << ", Attenuation: " << dbloss << " dBm ");
878 //cerr << "LOS:: Link budget: " << link_budget << ", Attenuation: " << dbloss << " dBm " << endl;
883 /*** Material properties database
885 void FGRadio::set_material_properties() {