/////////////////////////////////////////////////////////////////////////////////// // Copyright (C) 2021 Jon Beniston, M7RCE // // Copyright (C) 2020 Edouard Griffiths, F4EXB // // // // 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 as version 3 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 V3 for more details. // // // // You should have received a copy of the GNU General Public License // // along with this program. If not, see . // /////////////////////////////////////////////////////////////////////////////////// #include #include #include #include #include #include #include #include #include "SWGTargetAzimuthElevation.h" #include "SWGMapItem.h" #include "webapi/webapiadapterinterface.h" #include "webapi/webapiutils.h" #include "util/units.h" #include "device/deviceset.h" #include "device/deviceapi.h" #include "channel/channelwebapiutils.h" #include "feature/featurewebapiutils.h" #include "maincore.h" #include "satellitetracker.h" #include "satellitetrackerworker.h" #include "satellitetrackerreport.h" #include "satellitetrackersgp4.h" MESSAGE_CLASS_DEFINITION(SatelliteTrackerWorker::MsgConfigureSatelliteTrackerWorker, Message) MESSAGE_CLASS_DEFINITION(SatelliteTrackerReport::MsgReportSat, Message) MESSAGE_CLASS_DEFINITION(SatelliteTrackerReport::MsgReportAOS, Message) MESSAGE_CLASS_DEFINITION(SatelliteTrackerReport::MsgReportLOS, Message) MESSAGE_CLASS_DEFINITION(SatelliteTrackerReport::MsgReportTarget, Message) SatelliteTrackerWorker::SatelliteTrackerWorker(SatelliteTracker* satelliteTracker, WebAPIAdapterInterface *webAPIAdapterInterface) : m_satelliteTracker(satelliteTracker), m_webAPIAdapterInterface(webAPIAdapterInterface), m_msgQueueToFeature(nullptr), m_msgQueueToGUI(nullptr), m_running(false), m_mutex(QMutex::Recursive), m_recalculatePasses(true), m_flipRotation(false), m_extendedAzRotation(false) { connect(&m_pollTimer, SIGNAL(timeout()), this, SLOT(update())); } SatelliteTrackerWorker::~SatelliteTrackerWorker() { m_inputMessageQueue.clear(); } void SatelliteTrackerWorker::reset() { QMutexLocker mutexLocker(&m_mutex); m_inputMessageQueue.clear(); } bool SatelliteTrackerWorker::startWork() { QMutexLocker mutexLocker(&m_mutex); connect(&m_inputMessageQueue, SIGNAL(messageEnqueued()), this, SLOT(handleInputMessages())); m_pollTimer.start((int)round(m_settings.m_updatePeriod*1000.0)); // Resume doppler timers QHashIterator itr(m_workerState); while (itr.hasNext()) { itr.next(); SatWorkerState *satWorkerState = itr.value(); if (satWorkerState->m_dopplerTimer.interval() > 0) satWorkerState->m_dopplerTimer.start(); } m_recalculatePasses = true; m_running = true; return m_running; } void SatelliteTrackerWorker::stopWork() { QMutexLocker mutexLocker(&m_mutex); disconnect(&m_inputMessageQueue, SIGNAL(messageEnqueued()), this, SLOT(handleInputMessages())); m_pollTimer.stop(); // Stop doppler timers QHashIterator itr(m_workerState); while (itr.hasNext()) { itr.next(); itr.value()->m_dopplerTimer.stop(); } m_running = false; } void SatelliteTrackerWorker::handleInputMessages() { Message* message; while ((message = m_inputMessageQueue.pop()) != nullptr) { if (handleMessage(*message)) { delete message; } } } bool SatelliteTrackerWorker::handleMessage(const Message& message) { if (MsgConfigureSatelliteTrackerWorker::match(message)) { QMutexLocker mutexLocker(&m_mutex); MsgConfigureSatelliteTrackerWorker& cfg = (MsgConfigureSatelliteTrackerWorker&) message; applySettings(cfg.getSettings(), cfg.getForce()); return true; } else if (SatelliteTracker::MsgSatData::match(message)) { SatelliteTracker::MsgSatData& satData = (SatelliteTracker::MsgSatData&) message; m_satellites = satData.getSatellites(); m_recalculatePasses = true; return true; } else { return false; } } void SatelliteTrackerWorker::applySettings(const SatelliteTrackerSettings& settings, bool force) { qDebug() << "SatelliteTrackerWorker::applySettings:" << " m_target: " << settings.m_target << " m_satellites: " << settings.m_satellites << " m_dateTime: " << settings.m_dateTime << " m_utc: " << settings.m_utc << " m_updatePeriod: " << settings.m_updatePeriod << " force: " << force; if ((m_settings.m_target != settings.m_target) || (m_settings.m_latitude != settings.m_latitude) || (m_settings.m_longitude != settings.m_longitude) || (m_settings.m_heightAboveSeaLevel != settings.m_heightAboveSeaLevel) || (m_settings.m_dateTime != settings.m_dateTime) || (m_settings.m_utc != settings.m_utc) || (m_settings.m_groundTrackPoints != settings.m_groundTrackPoints) || (m_settings.m_minAOSElevation != settings.m_minAOSElevation) || (m_settings.m_minPassElevation != settings.m_minPassElevation) || (m_settings.m_predictionPeriod != settings.m_predictionPeriod) || (m_settings.m_passStartTime != settings.m_passStartTime) || (m_settings.m_passFinishTime != settings.m_passFinishTime) || (!m_settings.m_drawOnMap && settings.m_drawOnMap) || force) { // Recalculate immediately m_recalculatePasses = true; QTimer::singleShot(1, this, &SatelliteTrackerWorker::update); m_pollTimer.start((int)round(settings.m_updatePeriod*1000.0)); } else if ((m_settings.m_updatePeriod != settings.m_updatePeriod) || force) { m_pollTimer.start((int)round(settings.m_updatePeriod*1000.0)); } if (!settings.m_drawOnMap && m_settings.m_drawOnMap) { QHashIterator itr(m_workerState); while (itr.hasNext()) { itr.next(); removeFromMap(itr.key()); } } // Remove satellites no longer needed QMutableHashIterator itr(m_workerState); while (itr.hasNext()) { itr.next(); if (settings.m_satellites.indexOf(itr.key()) == -1) itr.remove(); } // Add new satellites for (int i = 0; i < settings.m_satellites.size(); i++) { if (!m_workerState.contains(settings.m_satellites[i])) { SatWorkerState *satWorkerState = new SatWorkerState(settings.m_satellites[i]); m_workerState.insert(settings.m_satellites[i], satWorkerState); connect(&satWorkerState->m_aosTimer, &QTimer::timeout, [this, satWorkerState]() { aos(satWorkerState); }); connect(&satWorkerState->m_losTimer, &QTimer::timeout, [this, satWorkerState]() { los(satWorkerState); }); m_recalculatePasses = true; } } m_settings = settings; } void SatelliteTrackerWorker::removeFromMap(QString id) { MessagePipes& messagePipes = MainCore::instance()->getMessagePipes(); QList *mapMessageQueues = messagePipes.getMessageQueues(m_satelliteTracker, "mapitems"); if (mapMessageQueues) sendToMap(mapMessageQueues, id, "", "", 0.0, 0.0, 0.0, 0.0, nullptr, nullptr); } void SatelliteTrackerWorker::sendToMap(QList *mapMessageQueues, QString name, QString image, QString text, double lat, double lon, double altitude, double rotation, QList *track, QList *predictedTrack) { QList::iterator it = mapMessageQueues->begin(); for (; it != mapMessageQueues->end(); ++it) { SWGSDRangel::SWGMapItem *swgMapItem = new SWGSDRangel::SWGMapItem(); swgMapItem->setName(new QString(name)); swgMapItem->setLatitude(lat); swgMapItem->setLongitude(lon); swgMapItem->setAltitude(altitude); swgMapItem->setImage(new QString(image)); swgMapItem->setImageRotation(rotation); swgMapItem->setText(new QString(text)); swgMapItem->setImageMinZoom(0); if (track != nullptr) { QList *mapTrack = new QList(); for (int i = 0; i < track->size(); i++) { SWGSDRangel::SWGMapCoordinate* p = new SWGSDRangel::SWGMapCoordinate(); QGeoCoordinate *c = track->at(i); p->setLatitude(c->latitude()); p->setLongitude(c->longitude()); p->setAltitude(c->altitude()); mapTrack->append(p); } swgMapItem->setTrack(mapTrack); } if (predictedTrack != nullptr) { QList *mapTrack = new QList(); for (int i = 0; i < predictedTrack->size(); i++) { SWGSDRangel::SWGMapCoordinate* p = new SWGSDRangel::SWGMapCoordinate(); QGeoCoordinate *c = predictedTrack->at(i); p->setLatitude(c->latitude()); p->setLongitude(c->longitude()); p->setAltitude(c->altitude()); mapTrack->append(p); } swgMapItem->setPredictedTrack(mapTrack); } MainCore::MsgMapItem *msg = MainCore::MsgMapItem::create(m_satelliteTracker, swgMapItem); (*it)->push(msg); } } void SatelliteTrackerWorker::update() { // Get date and time to calculate position at QDateTime qdt; if (m_settings.m_dateTime == "") qdt = SatelliteTracker::currentDateTimeUtc(); else if (m_settings.m_utc) qdt = QDateTime::fromString(m_settings.m_dateTime, Qt::ISODateWithMs); else qdt = QDateTime::fromString(m_settings.m_dateTime, Qt::ISODateWithMs).toUTC(); QHashIterator itr(m_workerState); while (itr.hasNext()) { itr.next(); SatWorkerState *satWorkerState = itr.value(); QString name = satWorkerState->m_name; if (m_satellites.contains(name)) { SatNogsSatellite *sat = m_satellites.value(name); if (sat->m_tle != nullptr) { // Calculate position, AOS/LOS and other details for satellite int noOfPasses; bool recalcAsPastLOS = (satWorkerState->m_satState.m_passes.size() > 0) && (satWorkerState->m_satState.m_passes[0]->m_los < qdt); if (m_recalculatePasses || recalcAsPastLOS) noOfPasses = (name == m_settings.m_target) ? 99 : 1; else noOfPasses = 0; getSatelliteState(qdt, sat->m_tle->m_tle0, sat->m_tle->m_tle1, sat->m_tle->m_tle2, m_settings.m_latitude, m_settings.m_longitude, m_settings.m_heightAboveSeaLevel/1000.0, m_settings.m_predictionPeriod, m_settings.m_minAOSElevation, m_settings.m_minPassElevation, m_settings.m_passStartTime, m_settings.m_passFinishTime, m_settings.m_utc, noOfPasses, m_settings.m_groundTrackPoints, &satWorkerState->m_satState); // Update AOS/LOS (only set timers if using real time) if ((m_settings.m_dateTime == "") && (satWorkerState->m_satState.m_passes.size() > 0)) { // Do we have a new AOS? if ((satWorkerState->m_aos != satWorkerState->m_satState.m_passes[0]->m_aos) || (satWorkerState->m_los != satWorkerState->m_satState.m_passes[0]->m_los)) { qDebug() << "SatelliteTrackerWorker: New AOS: " << name << " new: " << satWorkerState->m_satState.m_passes[0]->m_aos << " old: " << satWorkerState->m_aos; qDebug() << "SatelliteTrackerWorker: New LOS: " << name << " new: " << satWorkerState->m_satState.m_passes[0]->m_los << " old: " << satWorkerState->m_los; satWorkerState->m_aos = satWorkerState->m_satState.m_passes[0]->m_aos; satWorkerState->m_los = satWorkerState->m_satState.m_passes[0]->m_los; if (satWorkerState->m_aos.isValid()) { if (satWorkerState->m_aos > qdt) { satWorkerState->m_aosTimer.setInterval(satWorkerState->m_aos.toMSecsSinceEpoch() - qdt.toMSecsSinceEpoch()); satWorkerState->m_aosTimer.setSingleShot(true); satWorkerState->m_aosTimer.start(); } else if (qdt < satWorkerState->m_los) aos(satWorkerState); if (satWorkerState->m_los.isValid() && (m_settings.m_target == satWorkerState->m_name)) calculateRotation(satWorkerState); } if (satWorkerState->m_los.isValid() && (satWorkerState->m_los > qdt)) { if (satWorkerState->m_losTimer.isActive()) { qDebug() << "SatelliteTrackerWorker::update m_losTimer.remainingTime: " << satWorkerState->m_losTimer.remainingTime(); } // We can detect a new AOS for a satellite, a little bit before the LOS has occured, presumably // because the calculations aren't accurate to fractions of a second. Allow for 1s here if (satWorkerState->m_losTimer.isActive() && (satWorkerState->m_losTimer.remainingTime() <= 1000)) { satWorkerState->m_losTimer.stop(); // LOS hasn't been called yet - do so, before we reset timer los(satWorkerState); } satWorkerState->m_losTimer.setInterval(satWorkerState->m_los.toMSecsSinceEpoch() - qdt.toMSecsSinceEpoch()); satWorkerState->m_losTimer.setSingleShot(true); satWorkerState->m_losTimer.start(); } } } else { satWorkerState->m_aos = QDateTime(); satWorkerState->m_los = QDateTime(); satWorkerState->m_aosTimer.stop(); satWorkerState->m_losTimer.stop(); } // Send Az/El of target to Rotator Controllers, if elevation above horizon if ((name == m_settings.m_target) && (satWorkerState->m_satState.m_elevation >= 0)) { double azimuth = satWorkerState->m_satState.m_azimuth; double elevation = satWorkerState->m_satState.m_elevation; if (m_extendedAzRotation) { if (azimuth < 180.0) azimuth += 360.0; } else if (m_flipRotation) { azimuth = std::fmod(azimuth + 180.0, 360.0); elevation = 180.0 - elevation; } MessagePipes& messagePipes = MainCore::instance()->getMessagePipes(); QList *rotatorMessageQueues = messagePipes.getMessageQueues(m_satelliteTracker, "target"); if (rotatorMessageQueues) { QList::iterator it = rotatorMessageQueues->begin(); for (; it != rotatorMessageQueues->end(); ++it) { SWGSDRangel::SWGTargetAzimuthElevation *swgTarget = new SWGSDRangel::SWGTargetAzimuthElevation(); swgTarget->setName(new QString(m_settings.m_target)); swgTarget->setAzimuth(azimuth); swgTarget->setElevation(elevation); (*it)->push(MainCore::MsgTargetAzimuthElevation::create(m_satelliteTracker, swgTarget)); } } } // Send to Map if (m_settings.m_drawOnMap) { MessagePipes& messagePipes = MainCore::instance()->getMessagePipes(); QList *mapMessageQueues = messagePipes.getMessageQueues(m_satelliteTracker, "mapitems"); if (mapMessageQueues) { QString image; if (sat->m_name == "ISS") image = "qrc:///satellitetracker/satellitetracker/iss-32.png"; else image = "qrc:///satellitetracker/satellitetracker/satellite-32.png"; QString text = QString("Name: %1\nAltitude: %2 km\nRange: %3 km\nRange rate: %4 km/s\nSpeed: %5 km/h\nPeriod: %6 mins") .arg(sat->m_name) .arg((int)round(satWorkerState->m_satState.m_altitude)) .arg((int)round(satWorkerState->m_satState.m_range)) .arg(satWorkerState->m_satState.m_rangeRate, 0, 'f', 1) .arg(Units::kmpsToIntegerKPH(satWorkerState->m_satState.m_speed)) .arg((int)round(satWorkerState->m_satState.m_period)); if (satWorkerState->m_satState.m_passes.size() > 0) { if ((qdt >= satWorkerState->m_satState.m_passes[0]->m_aos) && (qdt <= satWorkerState->m_satState.m_passes[0]->m_los)) text = text.append("\nSatellite is visible"); else text = text.append("\nAOS in: %1 mins").arg((int)round((satWorkerState->m_satState.m_passes[0]->m_aos.toSecsSinceEpoch() - qdt.toSecsSinceEpoch())/60.0)); QString aosDateTime; QString losDateTime; if (m_settings.m_utc) { aosDateTime = satWorkerState->m_satState.m_passes[0]->m_aos.toString(m_settings.m_dateFormat + " hh:mm"); losDateTime = satWorkerState->m_satState.m_passes[0]->m_los.toString(m_settings.m_dateFormat + " hh:mm"); } else { aosDateTime = satWorkerState->m_satState.m_passes[0]->m_aos.toLocalTime().toString(m_settings.m_dateFormat + " hh:mm"); losDateTime = satWorkerState->m_satState.m_passes[0]->m_los.toLocalTime().toString(m_settings.m_dateFormat + " hh:mm"); } text = QString("%1\nAOS: %2\nLOS: %3\nMax El: %4%5") .arg(text) .arg(aosDateTime) .arg(losDateTime) .arg((int)round(satWorkerState->m_satState.m_passes[0]->m_maxElevation)) .arg(QChar(0xb0)); } sendToMap(mapMessageQueues, sat->m_name, image, text, satWorkerState->m_satState.m_latitude, satWorkerState->m_satState.m_longitude, satWorkerState->m_satState.m_altitude * 1000.0, 0, &satWorkerState->m_satState.m_groundTrack, &satWorkerState->m_satState.m_predictedGroundTrack); } } // Send to GUI if (getMessageQueueToGUI()) getMessageQueueToGUI()->push(SatelliteTrackerReport::MsgReportSat::create(new SatelliteState(satWorkerState->m_satState))); } else qDebug() << "SatelliteTrackerWorker::update: No TLE for " << sat->m_name << ". Can't compute position."; } } m_recalculatePasses = false; } void SatelliteTrackerWorker::aos(SatWorkerState *satWorkerState) { qDebug() << "SatelliteTrackerWorker::aos " << satWorkerState->m_name; // Indicate AOS to GUI if (getMessageQueueToGUI()) { int durationMins = (int)round((satWorkerState->m_los.toSecsSinceEpoch() - satWorkerState->m_aos.toSecsSinceEpoch())/60.0); int maxElevation = 0; if (satWorkerState->m_satState.m_passes.size() > 0) maxElevation = satWorkerState->m_satState.m_passes[0]->m_maxElevation; getMessageQueueToGUI()->push(SatelliteTrackerReport::MsgReportAOS::create(satWorkerState->m_name, durationMins, maxElevation)); } // Update target if (m_settings.m_autoTarget && (satWorkerState->m_name != m_settings.m_target)) { // Only switch if higher priority (earlier in list) or other target not in AOS SatWorkerState *targetSatWorkerState = m_workerState.value(m_settings.m_target); int currentTargetIdx = m_settings.m_satellites.indexOf(m_settings.m_target); int newTargetIdx = m_settings.m_satellites.indexOf(satWorkerState->m_name); if ((newTargetIdx < currentTargetIdx) || !targetSatWorkerState->hasAOS()) { // Stop doppler correction for current target if (m_workerState.contains(m_settings.m_target)) m_workerState.value(m_settings.m_target)->m_dopplerTimer.stop(); qDebug() << "SatelliteTrackerWorker::aos - autoTarget setting " << satWorkerState->m_name; m_settings.m_target = satWorkerState->m_name; // Update GUI with new target if (getMessageQueueToGUI()) getMessageQueueToGUI()->push(SatelliteTrackerReport::MsgReportTarget::create(satWorkerState->m_name)); } } // TODO: Detect if different device sets are used and support multiple sats simultaneously if (m_settings.m_target == satWorkerState->m_name) applyDeviceAOSSettings(satWorkerState->m_name); } // Determine if we need to flip rotator or use extended azimuth to avoid 360/0 discontinuity void SatelliteTrackerWorker::calculateRotation(SatWorkerState *satWorkerState) { m_flipRotation = false; m_extendedAzRotation = false; if (satWorkerState->m_satState.m_passes.size() > 0) { SatNogsSatellite *sat = m_satellites.value(satWorkerState->m_name); bool passes0 = getPassesThrough0Deg(sat->m_tle->m_tle0, sat->m_tle->m_tle1, sat->m_tle->m_tle2, m_settings.m_latitude, m_settings.m_longitude, m_settings.m_heightAboveSeaLevel/1000.0, satWorkerState->m_satState.m_passes[0]->m_aos, satWorkerState->m_satState.m_passes[0]->m_los); if (passes0) { double aosAz = satWorkerState->m_satState.m_passes[0]->m_aosAzimuth; double losAz = satWorkerState->m_satState.m_passes[0]->m_losAzimuth; double minAz = std::min(aosAz, losAz); if ((m_settings.m_rotatorMaxAzimuth - 360.0) > minAz) m_extendedAzRotation = true; else if (m_settings.m_rotatorMaxElevation == 180.0) m_flipRotation = true; } } } void SatelliteTrackerWorker::applyDeviceAOSSettings(const QString& name) { // Execute global program/script if (!m_settings.m_aosCommand.isEmpty()) { qDebug() << "SatelliteTrackerWorker::aos: executing command: " << m_settings.m_aosCommand; QProcess::startDetached(m_settings.m_aosCommand); } // Update device set if (m_settings.m_deviceSettings.contains(name)) { QList *m_deviceSettingsList = m_settings.m_deviceSettings.value(name); MainCore *mainCore = MainCore::instance(); // Load presets for (int i = 0; i < m_deviceSettingsList->size(); i++) { SatelliteTrackerSettings::SatelliteDeviceSettings *devSettings = m_deviceSettingsList->at(i); if (!devSettings->m_presetGroup.isEmpty() && !devSettings->m_deviceSet.isEmpty()) { const MainSettings& mainSettings = mainCore->getSettings(); QString presetType = QString(devSettings->m_deviceSet[0]); const Preset* preset = mainSettings.getPreset(devSettings->m_presetGroup, devSettings->m_presetFrequency, devSettings->m_presetDescription, presetType); if (preset != nullptr) { qDebug() << "SatelliteTrackerWorker::aos: Loading preset " << preset->getDescription() << " to " << devSettings->m_deviceSet[0]; unsigned int deviceSetIndex = devSettings->m_deviceSet.mid(1).toInt(); std::vector& deviceSets = mainCore->getDeviceSets(); if (deviceSetIndex < deviceSets.size()) { MainCore::MsgLoadPreset *msg = MainCore::MsgLoadPreset::create(preset, deviceSetIndex); mainCore->getMainMessageQueue()->push(msg); } else qWarning() << "SatelliteTrackerWorker::aos: device set " << devSettings->m_deviceSet << " does not exist"; } else qWarning() << "SatelliteTrackerWorker::aos: Unable to get preset: " << devSettings->m_presetGroup << " " << devSettings->m_presetFrequency << " " << devSettings->m_presetDescription; } } // Wait a little bit for presets to load before performing other steps QTimer::singleShot(1000, [this, mainCore, name, m_deviceSettingsList]() { for (int i = 0; i < m_deviceSettingsList->size(); i++) { SatelliteTrackerSettings::SatelliteDeviceSettings *devSettings = m_deviceSettingsList->at(i); // Override frequency if (devSettings->m_frequency != 0) { qDebug() << "SatelliteTrackerWorker::aos: setting frequency to: " << devSettings->m_frequency; int deviceSetIndex = devSettings->m_deviceSet.mid(1).toInt(); ChannelWebAPIUtils::setCenterFrequency(deviceSetIndex, devSettings->m_frequency); } // Execute per satellite program/script if (!devSettings->m_aosCommand.isEmpty()) { qDebug() << "SatelliteTrackerWorker::aos: executing command: " << devSettings->m_aosCommand; QProcess::startDetached(devSettings->m_aosCommand); } } // Start acquisition - Need to use WebAPI, in order for GUI to correctly reflect being started for (int i = 0; i < m_deviceSettingsList->size(); i++) { SatelliteTrackerSettings::SatelliteDeviceSettings *devSettings = m_deviceSettingsList->at(i); if (devSettings->m_startOnAOS) { qDebug() << "SatelliteTrackerWorker::aos: starting acqusition"; int deviceSetIndex = devSettings->m_deviceSet.mid(1).toInt(); ChannelWebAPIUtils::run(deviceSetIndex); } } // Send AOS message to channels/features SatWorkerState *satWorkerState = m_workerState.value(name); ChannelWebAPIUtils::satelliteAOS(name, satWorkerState->m_satState.m_passes[0]->m_northToSouth); FeatureWebAPIUtils::satelliteAOS(name, satWorkerState->m_aos, satWorkerState->m_los); // Start Doppler correction, if needed satWorkerState->m_initFrequencyOffset.clear(); bool requiresDoppler = false; for (int i = 0; i < m_deviceSettingsList->size(); i++) { SatelliteTrackerSettings::SatelliteDeviceSettings *devSettings = m_deviceSettingsList->at(i); if (devSettings->m_doppler.size() > 0) { requiresDoppler = true; for (int j = 0; j < devSettings->m_doppler.size(); j++) { int offset; int deviceSetIndex = devSettings->m_deviceSet.mid(1).toInt(); if (ChannelWebAPIUtils::getFrequencyOffset(deviceSetIndex, devSettings->m_doppler[j], offset)) { satWorkerState->m_initFrequencyOffset.append(offset); qDebug() << "SatelliteTrackerWorker::applyDeviceAOSSettings: Initial frequency offset: " << offset; } else { qDebug() << "SatelliteTrackerWorker::applyDeviceAOSSettings: Failed to get initial frequency offset"; satWorkerState->m_initFrequencyOffset.append(0); } } } } if (requiresDoppler) { satWorkerState->m_dopplerTimer.setInterval(m_settings.m_dopplerPeriod * 1000); satWorkerState->m_dopplerTimer.start(); connect(&satWorkerState->m_dopplerTimer, &QTimer::timeout, [this, satWorkerState]() { doppler(satWorkerState); }); } // Start file sinks (need a little delay to ensure sample rate message has been handled in filerecord) QTimer::singleShot(1000, [this, m_deviceSettingsList]() { for (int i = 0; i < m_deviceSettingsList->size(); i++) { SatelliteTrackerSettings::SatelliteDeviceSettings *devSettings = m_deviceSettingsList->at(i); if (devSettings->m_startStopFileSink) { qDebug() << "SatelliteTrackerWorker::aos: starting file sinks"; int deviceSetIndex = devSettings->m_deviceSet.mid(1).toInt(); ChannelWebAPIUtils::startStopFileSinks(deviceSetIndex, true); } } }); }); } else { // Send AOS message to channels/features SatWorkerState *satWorkerState = m_workerState.value(name); ChannelWebAPIUtils::satelliteAOS(name, satWorkerState->m_satState.m_passes[0]->m_northToSouth); FeatureWebAPIUtils::satelliteAOS(name, satWorkerState->m_aos, satWorkerState->m_los); } } void SatelliteTrackerWorker::doppler(SatWorkerState *satWorkerState) { qDebug() << "SatelliteTrackerWorker::doppler " << satWorkerState->m_name; QList *m_deviceSettingsList = m_settings.m_deviceSettings.value(satWorkerState->m_name); if (m_deviceSettingsList != nullptr) { for (int i = 0; i < m_deviceSettingsList->size(); i++) { SatelliteTrackerSettings::SatelliteDeviceSettings *devSettings = m_deviceSettingsList->at(i); if (devSettings->m_doppler.size() > 0) { // Get center frequency for this device int deviceSetIndex = devSettings->m_deviceSet.mid(1).toInt(); double centerFrequency; if (ChannelWebAPIUtils::getCenterFrequency(deviceSetIndex, centerFrequency)) { // Calculate frequency delta due to Doppler double c = 299792458.0; double deltaF = centerFrequency * satWorkerState->m_satState.m_rangeRate * 1000.0 / c; for (int j = 0; j < devSettings->m_doppler.size(); j++) { // For receive, we subtract, transmit we add int offset; if (devSettings->m_deviceSet[0] == "R") offset = satWorkerState->m_initFrequencyOffset[i] - (int)round(deltaF); else offset = satWorkerState->m_initFrequencyOffset[i] + (int)round(deltaF); if (!ChannelWebAPIUtils::setFrequencyOffset(deviceSetIndex, devSettings->m_doppler[j], offset)) qDebug() << "SatelliteTrackerWorker::doppler: Failed to set frequency offset"; } } else qDebug() << "SatelliteTrackerWorker::doppler: couldn't get centre frequency for " << devSettings->m_deviceSet; } } } } void SatelliteTrackerWorker::los(SatWorkerState *satWorkerState) { qDebug() << "SatelliteTrackerWorker::los " << satWorkerState->m_name; // Indicate LOS to GUI if (getMessageQueueToGUI()) getMessageQueueToGUI()->push(SatelliteTrackerReport::MsgReportLOS::create(satWorkerState->m_name)); // Stop Doppler timer, and set interval to 0, so we don't restart it in start() satWorkerState->m_dopplerTimer.stop(); satWorkerState->m_dopplerTimer.setInterval(0); if (m_settings.m_target == satWorkerState->m_name) { // Execute program/script if (!m_settings.m_losCommand.isEmpty()) { qDebug() << "SatelliteTrackerWorker::los: executing command: " << m_settings.m_losCommand; QProcess::startDetached(m_settings.m_losCommand); } if (m_settings.m_deviceSettings.contains(satWorkerState->m_name)) { QList *m_deviceSettingsList = m_settings.m_deviceSettings.value(satWorkerState->m_name); // Stop file sinks for (int i = 0; i < m_deviceSettingsList->size(); i++) { SatelliteTrackerSettings::SatelliteDeviceSettings *devSettings = m_deviceSettingsList->at(i); if (devSettings->m_startStopFileSink) { qDebug() << "SatelliteTrackerWorker::los: stopping file sinks"; int deviceSetIndex = devSettings->m_deviceSet.mid(1).toInt(); ChannelWebAPIUtils::startStopFileSinks(deviceSetIndex, false); } } // Send LOS message to channels/features ChannelWebAPIUtils::satelliteLOS(satWorkerState->m_name); FeatureWebAPIUtils::satelliteLOS(satWorkerState->m_name); // Stop acquisition for (int i = 0; i < m_deviceSettingsList->size(); i++) { SatelliteTrackerSettings::SatelliteDeviceSettings *devSettings = m_deviceSettingsList->at(i); if (devSettings->m_stopOnLOS) { int deviceSetIndex = devSettings->m_deviceSet.mid(1).toInt(); ChannelWebAPIUtils::stop(deviceSetIndex); } } // Execute per satellite program/script // Do after stopping acquisition, so files are closed by file sink for (int i = 0; i < m_deviceSettingsList->size(); i++) { SatelliteTrackerSettings::SatelliteDeviceSettings *devSettings = m_deviceSettingsList->at(i); if (!devSettings->m_losCommand.isEmpty()) { qDebug() << "SatelliteTrackerWorker::los: executing command: " << devSettings->m_losCommand; QProcess::startDetached(devSettings->m_losCommand); } } } } // Is another lower-priority satellite with AOS available to switch to? if (m_settings.m_autoTarget) { for (int i = m_settings.m_satellites.indexOf(m_settings.m_target) + 1; i < m_settings.m_satellites.size(); i++) { if (m_workerState.contains(m_settings.m_satellites[i])) { SatWorkerState *newSatWorkerState = m_workerState.value(m_settings.m_satellites[i]); if (newSatWorkerState->hasAOS()) { qDebug() << "SatelliteTrackerWorker::los - autoTarget setting " << m_settings.m_satellites[i]; m_settings.m_target = m_settings.m_satellites[i]; // Update GUI with new target if (getMessageQueueToGUI()) getMessageQueueToGUI()->push(SatelliteTrackerReport::MsgReportTarget::create(m_settings.m_target)); // Apply device settings applyDeviceAOSSettings(m_settings.m_target); break; } } } } m_recalculatePasses = true; } bool SatWorkerState::hasAOS() { QDateTime currentTime = SatelliteTracker::currentDateTimeUtc(); return (m_aos <= currentTime) && (m_los > currentTime); }