// Air Ground Radar // // Written by Vivian MEAZZA, started Feb 2008. // // // Copyright (C) 2008 Vivian Meazza // // This program is free software; you can redistribute it and/or // modify it under the terms of the GNU General Public License as // published by the Free Software Foundation; either version 2 of the // License, or (at your option) any later version. // // This program is distributed in the hope that it will be useful, but // WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU // General Public License for more details. // // You should have received a copy of the GNU General Public License // along with this program; if not, write to the Free Software // Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. // // #ifdef HAVE_CONFIG_H # include "config.h" #endif #include
#include
#include "agradar.hxx" agRadar::agRadar(SGPropertyNode *node) : wxRadarBg(node) { _name = node->getStringValue("name", "air-ground-radar"); _num = node->getIntValue("number", 0); } agRadar::~agRadar () { } void agRadar::init () { _user_hdg_deg_node = fgGetNode("/orientation/heading-deg", true); _user_pitch_deg_node = fgGetNode("/orientation/pitch-deg", true); _user_roll_deg_node = fgGetNode("/orientation/roll-deg", true); _terrain_warning_node = fgGetNode("/sim/alarms/terrain-warning", true); _terrain_warning_node->setBoolValue(false); wxRadarBg::init(); // those properties are used by a radar instrument of a MFD // input switch = OFF | TST | STBY | ON // input mode = WX | WXA | MAP | TW // output status = STBY | TEST | WX | WXA | MAP | blank // input lightning = true | false // input TRK = +/- n degrees // input TILT = +/- n degree // input autotilt = true | false // input range = n nm (20/40/80) // input display-mode = arc | rose | map | plan _Instrument->setFloatValue("trk", 0.0); _Instrument->setFloatValue("tilt",-2.5); _Instrument->setStringValue("status",""); _Instrument->setIntValue("mode-control", 5); _Instrument->setBoolValue("stabilisation/roll", false); _Instrument->setBoolValue("stabilisation/pitch", false); _xOffsetMNode = getInstrumentNode("antenna/x-offset-m", 0.0); _yOffsetMNode = getInstrumentNode("antenna/y-offset-m", 0.0); _zOffsetMNode = getInstrumentNode("antenna/z-offset-m", 0.0); _elevLimitDegNode = getInstrumentNode("terrain-warning/elev-limit-deg", 2.0); _elevStepDegNode = getInstrumentNode("terrain-warning/elev-step-deg", 1.0); _azLimitDegNode = getInstrumentNode("terrain-warning/az-limit-deg", 1.0); _azStepDegNode = getInstrumentNode("terrain-warning/az-step-deg", 1.5); _maxRangeMNode = getInstrumentNode("terrain-warning/max-range-m", 4000.0); _minRangeMNode = getInstrumentNode("terrain-warning/min-range-m", 250.0); _tiltNode = getInstrumentNode("terrain-warning/tilt", -2.0); _brgDegNode = getInstrumentNode("terrain-warning/hit/brg-deg", 0.0); _rangeMNode = getInstrumentNode("terrain-warning/hit/range-m", 0.0); _elevationMNode = getInstrumentNode("terrain-warning/hit/elevation-m", 0.0); _materialNode = getInstrumentNode("terrain-warning/hit/material", ""); _bumpinessNode = getInstrumentNode("terrain-warning/hit/bumpiness", 0.0); _rollStabNode = getInstrumentNode("terrain-warning/stabilisation/roll", true); _pitchStabNode = getInstrumentNode("terrain-warning/stabilisation/pitch", false); // cout << "init done" << endl; } void agRadar::update (double delta_time_sec) { if ( ! _sim_init_done ) { if ( ! fgGetBool("sim/sceneryloaded", false) ) return; _sim_init_done = true; } if ( !_odg || ! _serviceable_node->getBoolValue() ) { _Instrument->setStringValue("status",""); return; } _time += delta_time_sec; if (_time < _interval) return; _time = 0.0; update_terrain(); // wxRadarBg::update(delta_time_sec); } void agRadar::setUserPos() { userpos.setLatitudeDeg(_user_lat_node->getDoubleValue()); userpos.setLongitudeDeg(_user_lon_node->getDoubleValue()); userpos.setElevationM(_user_alt_node->getDoubleValue() * SG_FEET_TO_METER); } SGVec3d agRadar::getCartUserPos() const { SGVec3d cartUserPos = SGVec3d::fromGeod(userpos); return cartUserPos; } SGVec3d agRadar::getCartAntennaPos() const { float yaw = _user_hdg_deg_node->getDoubleValue(); float pitch = _user_pitch_deg_node->getDoubleValue(); float roll = _user_roll_deg_node->getDoubleValue(); double x_offset_m =_xOffsetMNode->getDoubleValue(); double y_offset_m =_yOffsetMNode->getDoubleValue(); double z_offset_m =_zOffsetMNode->getDoubleValue(); // convert geodetic positions to geocentered SGVec3d cartuserPos = getCartUserPos(); // Transform to the right coordinate frame, configuration is done in // the x-forward, y-right, z-up coordinates (feet), computation // in the simulation usual body x-forward, y-right, z-down coordinates // (meters) ) SGVec3d _off(x_offset_m, y_offset_m, -z_offset_m); // Transform the user position to the horizontal local coordinate system. SGQuatd hlTrans = SGQuatd::fromLonLat(userpos); // and postrotate the orientation of the user model wrt the horizontal // local frame hlTrans *= SGQuatd::fromYawPitchRollDeg(yaw,pitch,roll); // The offset converted to the usual body fixed coordinate system // rotated to the earth-fixed coordinates axis SGVec3d off = hlTrans.backTransform(_off); // Add the position offset of the user model to get the geocentered position SGVec3d offsetPos = cartuserPos + off; return offsetPos; } void agRadar::setAntennaPos() { SGGeodesy::SGCartToGeod(getCartAntennaPos(), antennapos); } void agRadar::setUserVec(double az, double el) { float yaw = _user_hdg_deg_node->getDoubleValue(); float pitch = _user_pitch_deg_node->getDoubleValue(); float roll = _user_roll_deg_node->getDoubleValue(); double tilt = _Instrument->getDoubleValue("tilt"); double trk = _Instrument->getDoubleValue("trk"); bool roll_stab = _Instrument->getBoolValue("stabilisation/roll"); bool pitch_stab = _Instrument->getBoolValue("stabilisation/pitch"); SGQuatd offset = SGQuatd::fromYawPitchRollDeg(az + trk, el + tilt, 0); // Transform the antenna position to the horizontal local coordinate system. SGQuatd hlTrans = SGQuatd::fromLonLat(antennapos); // and postrotate the orientation of the radar wrt the horizontal // local frame hlTrans *= SGQuatd::fromYawPitchRollDeg(yaw, pitch_stab ? 0 :pitch, roll_stab ? 0 : roll); hlTrans *= offset; // now rotate the rotation vector back into the // earth centered frames coordinates SGVec3d angleaxis(1,0,0); uservec = hlTrans.backTransform(angleaxis); } bool agRadar::getMaterial(){ if (globals->get_scenery()->get_elevation_m(hitpos, _elevation_m, &_material)){ //_ht_agl_ft = pos.getElevationFt() - _elevation_m * SG_METER_TO_FEET; if (_material) { const vector& names = _material->get_names(); _solid = _material->get_solid(); _load_resistance = _material->get_load_resistance(); _frictionFactor =_material->get_friction_factor(); _bumpinessFactor = _material->get_bumpiness(); if (!names.empty()) _mat_name = names[0].c_str(); else _mat_name = ""; } /*cout << "material " << mat_name << " solid " << _solid << " load " << _load_resistance << " frictionFactor " << frictionFactor << " _bumpinessFactor " << _bumpinessFactor << endl;*/ return true; } else { return false; } } void agRadar::update_terrain() { int mode = _radar_mode_control_node->getIntValue(); double el_limit = 1; double el_step = 1; double az_limit = 50; double az_step = 10; double max_range = 40000; double min_range = 250; double tilt = -2.5; bool roll_stab = _rollStabNode->getBoolValue(); bool pitch_stab = _pitchStabNode->getBoolValue(); //string status = ""; const char* status; bool hdg_mkr = true; if (mode == 5){ status = "TW"; hdg_mkr = false; tilt = _tiltNode->getDoubleValue(); el_limit = _elevLimitDegNode->getDoubleValue(); el_step = _elevStepDegNode->getDoubleValue(); az_limit = _azLimitDegNode->getDoubleValue(); az_step = _azStepDegNode->getDoubleValue(); max_range = _maxRangeMNode->getDoubleValue(); min_range = _minRangeMNode->getDoubleValue(); } _Instrument->setDoubleValue("tilt", tilt); _Instrument->setBoolValue("stabilisation/roll", roll_stab); _Instrument->setBoolValue("stabilisation/pitch", pitch_stab); _Instrument->setStringValue("status", status); _Instrument->setDoubleValue("limit-deg", az_limit); _Instrument->setBoolValue("heading-marker", hdg_mkr); setUserPos(); setAntennaPos(); SGVec3d cartantennapos = getCartAntennaPos(); for(double brg = -az_limit; brg <= az_limit; brg += az_step){ for(double elev = el_limit; elev >= - el_limit; elev -= el_step){ setUserVec(brg, elev); SGVec3d nearestHit; globals->get_scenery()->get_cart_ground_intersection(cartantennapos, uservec, nearestHit); SGGeodesy::SGCartToGeod(nearestHit, hitpos); double course1, course2, distance; SGGeodesy::inverse(hitpos, antennapos, course1, course2, distance); if (distance >= min_range && distance <= max_range) { _terrain_warning_node->setBoolValue(true); getMaterial(); _brgDegNode->setDoubleValue(course2); _rangeMNode->setDoubleValue(distance); _materialNode->setStringValue(_mat_name.c_str()); _bumpinessNode->setDoubleValue(_bumpinessFactor); _elevationMNode->setDoubleValue(_elevation_m); } else { _terrain_warning_node->setBoolValue(false); _brgDegNode->setDoubleValue(0); _rangeMNode->setDoubleValue(0); _materialNode->setStringValue(""); _bumpinessNode->setDoubleValue(0); _elevationMNode->setDoubleValue(0); } //cout << "usr hdg " << _user_hdg_deg_node->getDoubleValue() // << " ant brg " << course2 // << " elev " << _Instrument->getDoubleValue("tilt") // << " gnd rng nm " << distance * SG_METER_TO_NM // << " ht " << hitpos.getElevationFt() // << " mat " << _mat_name // << " solid " << _solid // << " bumpiness " << _bumpinessFactor // << endl; } } }