/////////////////////////////////////////////////////////////////////////////////// // 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 "SWGFeatureSettings.h" #include "SWGFeatureReport.h" #include "SWGFeatureActions.h" #include "SWGDeviceState.h" #include "SWGStarTrackerDisplaySettings.h" #include "dsp/dspengine.h" #include "util/weather.h" #include "util/units.h" #include "settings/serializable.h" #include "maincore.h" #include "startrackerreport.h" #include "startrackerworker.h" #include "startracker.h" MESSAGE_CLASS_DEFINITION(StarTracker::MsgConfigureStarTracker, Message) MESSAGE_CLASS_DEFINITION(StarTracker::MsgStartStop, Message) MESSAGE_CLASS_DEFINITION(StarTracker::MsgSetSolarFlux, Message) const char* const StarTracker::m_featureIdURI = "sdrangel.feature.startracker"; const char* const StarTracker::m_featureId = "StarTracker"; StarTracker::StarTracker(WebAPIAdapterInterface *webAPIAdapterInterface) : Feature(m_featureIdURI, webAPIAdapterInterface) { qDebug("StarTracker::StarTracker: webAPIAdapterInterface: %p", webAPIAdapterInterface); setObjectName(m_featureId); m_worker = new StarTrackerWorker(this, webAPIAdapterInterface); m_worker->moveToThread(&m_thread); m_state = StIdle; m_errorMessage = "StarTracker error"; connect(&m_updatePipesTimer, SIGNAL(timeout()), this, SLOT(updatePipes())); m_updatePipesTimer.start(1000); m_networkManager = new QNetworkAccessManager(); connect(m_networkManager, SIGNAL(finished(QNetworkReply*)), this, SLOT(networkManagerFinished(QNetworkReply*))); m_weather = nullptr; m_solarFlux = 0.0f; // Unfortunately, can't seem to access resources in static global constructor m_temps.append(new FITS(":/startracker/startracker/150mhz_ra_dec.fits")); m_temps.append(new FITS(":/startracker/startracker/408mhz_ra_dec.fits")); m_temps.append(new FITS(":/startracker/startracker/1420mhz_ra_dec.fits")); m_spectralIndex = new FITS(":/startracker/startracker/408mhz_ra_dec_spectral_index.fits"); } StarTracker::~StarTracker() { disconnect(m_networkManager, SIGNAL(finished(QNetworkReply*)), this, SLOT(networkManagerFinished(QNetworkReply*))); delete m_networkManager; if (m_worker->isRunning()) { stop(); } delete m_worker; if (m_weather) { disconnect(m_weather, &Weather::weatherUpdated, this, &StarTracker::weatherUpdated); delete m_weather; } qDeleteAll(m_temps); delete m_spectralIndex; } void StarTracker::start() { qDebug("StarTracker::start"); m_worker->reset(); m_worker->setMessageQueueToFeature(getInputMessageQueue()); m_worker->setMessageQueueToGUI(getMessageQueueToGUI()); bool ok = m_worker->startWork(); m_state = ok ? StRunning : StError; m_thread.start(); m_worker->getInputMessageQueue()->push(StarTrackerWorker::MsgConfigureStarTrackerWorker::create(m_settings, true)); m_worker->getInputMessageQueue()->push(MsgSetSolarFlux::create(m_solarFlux)); } void StarTracker::stop() { qDebug("StarTracker::stop"); m_worker->stopWork(); m_state = StIdle; m_thread.quit(); m_thread.wait(); } bool StarTracker::handleMessage(const Message& cmd) { if (MsgConfigureStarTracker::match(cmd)) { MsgConfigureStarTracker& cfg = (MsgConfigureStarTracker&) cmd; qDebug() << "StarTracker::handleMessage: MsgConfigureStarTracker"; applySettings(cfg.getSettings(), cfg.getForce()); return true; } else if (MsgStartStop::match(cmd)) { MsgStartStop& cfg = (MsgStartStop&) cmd; qDebug() << "StarTracker::handleMessage: MsgStartStop: start:" << cfg.getStartStop(); if (cfg.getStartStop()) { start(); } else { stop(); } return true; } else if (MsgSetSolarFlux::match(cmd)) { MsgSetSolarFlux& msg = (MsgSetSolarFlux&) cmd; m_solarFlux = msg.getFlux(); m_worker->getInputMessageQueue()->push(new MsgSetSolarFlux(msg)); return true; } else if (MainCore::MsgStarTrackerDisplaySettings::match(cmd)) { MainCore::MsgStarTrackerDisplaySettings& settings = (MainCore::MsgStarTrackerDisplaySettings&) cmd; if (m_guiMessageQueue) { m_guiMessageQueue->push(new MainCore::MsgStarTrackerDisplaySettings(settings)); } return true; } else if (MainCore::MsgStarTrackerDisplayLoSSettings::match(cmd)) { MainCore::MsgStarTrackerDisplayLoSSettings& settings = (MainCore::MsgStarTrackerDisplayLoSSettings&) cmd; if (m_guiMessageQueue) { m_guiMessageQueue->push(new MainCore::MsgStarTrackerDisplayLoSSettings(settings)); } return true; } else { return false; } } void StarTracker::updatePipes() { QList availablePipes = updateAvailablePipeSources("startracker.display", StarTrackerSettings::m_pipeTypes, StarTrackerSettings::m_pipeURIs, this); if (availablePipes != m_availablePipes) { m_availablePipes = availablePipes; if (getMessageQueueToGUI()) { MsgReportPipes *msgToGUI = MsgReportPipes::create(); QList& msgAvailablePipes = msgToGUI->getAvailablePipes(); msgAvailablePipes.append(availablePipes); getMessageQueueToGUI()->push(msgToGUI); } } } QByteArray StarTracker::serialize() const { return m_settings.serialize(); } bool StarTracker::deserialize(const QByteArray& data) { if (m_settings.deserialize(data)) { MsgConfigureStarTracker *msg = MsgConfigureStarTracker::create(m_settings, true); m_inputMessageQueue.push(msg); return true; } else { m_settings.resetToDefaults(); MsgConfigureStarTracker *msg = MsgConfigureStarTracker::create(m_settings, true); m_inputMessageQueue.push(msg); return false; } } void StarTracker::applySettings(const StarTrackerSettings& settings, bool force) { qDebug() << "StarTracker::applySettings:" << " m_target: " << settings.m_target << " m_ra: " << settings.m_ra << " m_dec: " << settings.m_dec << " m_az: " << settings.m_az << " m_el: " << settings.m_el << " m_l: " << settings.m_l << " m_b: " << settings.m_b << " m_azOffset: " << settings.m_azOffset << " m_elOffset: " << settings.m_elOffset << " m_latitude: " << settings.m_latitude << " m_longitude: " << settings.m_longitude << " m_serverPort: " << settings.m_serverPort << " m_enableServer: " << settings.m_enableServer << " m_title: " << settings.m_title << " m_rgbColor: " << settings.m_rgbColor << " m_useReverseAPI: " << settings.m_useReverseAPI << " m_reverseAPIAddress: " << settings.m_reverseAPIAddress << " m_reverseAPIPort: " << settings.m_reverseAPIPort << " m_reverseAPIFeatureSetIndex: " << settings.m_reverseAPIFeatureSetIndex << " m_reverseAPIFeatureIndex: " << settings.m_reverseAPIFeatureIndex << " force: " << force; QList reverseAPIKeys; if ((m_settings.m_target != settings.m_target) || force) { reverseAPIKeys.append("target"); } if ((m_settings.m_ra != settings.m_ra) || force) { reverseAPIKeys.append("ra"); } if ((m_settings.m_dec != settings.m_dec) || force) { reverseAPIKeys.append("dec"); } if ((m_settings.m_latitude != settings.m_latitude) || force) { reverseAPIKeys.append("latitude"); } if ((m_settings.m_longitude != settings.m_longitude) || force) { reverseAPIKeys.append("longitude"); } if ((m_settings.m_dateTime != settings.m_dateTime) || force) { reverseAPIKeys.append("dateTime"); } if ((m_settings.m_refraction != settings.m_refraction) || force) { reverseAPIKeys.append("refraction"); } if ((m_settings.m_pressure != settings.m_pressure) || force) { reverseAPIKeys.append("pressure"); } if ((m_settings.m_temperature != settings.m_temperature) || force) { reverseAPIKeys.append("temperature"); } if ((m_settings.m_humidity != settings.m_humidity) || force) { reverseAPIKeys.append("humidity"); } if ((m_settings.m_heightAboveSeaLevel != settings.m_heightAboveSeaLevel) || force) { reverseAPIKeys.append("heightAboveSeaLevel"); } if ((m_settings.m_temperatureLapseRate != settings.m_temperatureLapseRate) || force) { reverseAPIKeys.append("temperatureLapseRate"); } if ((m_settings.m_frequency != settings.m_frequency) || force) { reverseAPIKeys.append("frequency"); } if ((m_settings.m_serverPort != settings.m_serverPort) || force) { reverseAPIKeys.append("stellariumPort"); } if ((m_settings.m_enableServer != settings.m_enableServer) || force) { reverseAPIKeys.append("stellariumServerEnabled"); } if ((m_settings.m_updatePeriod != settings.m_updatePeriod) || force) { reverseAPIKeys.append("updatePeriod"); } if ((m_settings.m_jnow != settings.m_jnow) || force) { reverseAPIKeys.append("epoch"); } if ((m_settings.m_title != settings.m_title) || force) { reverseAPIKeys.append("title"); } if ((m_settings.m_rgbColor != settings.m_rgbColor) || force) { reverseAPIKeys.append("rgbColor"); } if ((m_settings.m_az != settings.m_az) || force) { reverseAPIKeys.append("azimuth"); } if ((m_settings.m_el != settings.m_el) || force) { reverseAPIKeys.append("elevation"); } if ((m_settings.m_l != settings.m_l) || force) { reverseAPIKeys.append("l"); } if ((m_settings.m_b != settings.m_b) || force) { reverseAPIKeys.append("b"); } if ((m_settings.m_azOffset != settings.m_azOffset) || force) { reverseAPIKeys.append("azimuthOffset"); } if ((m_settings.m_elOffset != settings.m_elOffset) || force) { reverseAPIKeys.append("elevationOffset"); } if ((m_settings.m_owmAPIKey != settings.m_owmAPIKey) || force) { if (m_weather) { disconnect(m_weather, &Weather::weatherUpdated, this, &StarTracker::weatherUpdated); delete m_weather; m_weather = nullptr; } if (!settings.m_owmAPIKey.isEmpty()) { m_weather = Weather::create(settings.m_owmAPIKey); if (m_weather) { connect(m_weather, &Weather::weatherUpdated, this, &StarTracker::weatherUpdated); } } } if ( (m_settings.m_owmAPIKey != settings.m_owmAPIKey) || (m_settings.m_latitude != settings.m_latitude) || (m_settings.m_longitude != settings.m_longitude) || (m_settings.m_weatherUpdatePeriod != settings.m_weatherUpdatePeriod) || force) { if (m_weather) { m_weather->getWeatherPeriodically(m_settings.m_latitude, m_settings.m_longitude, settings.m_weatherUpdatePeriod); } } StarTrackerWorker::MsgConfigureStarTrackerWorker *msg = StarTrackerWorker::MsgConfigureStarTrackerWorker::create( settings, force ); m_worker->getInputMessageQueue()->push(msg); if (settings.m_useReverseAPI) { bool fullUpdate = ((m_settings.m_useReverseAPI != settings.m_useReverseAPI) && settings.m_useReverseAPI) || (m_settings.m_reverseAPIAddress != settings.m_reverseAPIAddress) || (m_settings.m_reverseAPIPort != settings.m_reverseAPIPort) || (m_settings.m_reverseAPIFeatureSetIndex != settings.m_reverseAPIFeatureSetIndex) || (m_settings.m_reverseAPIFeatureIndex != settings.m_reverseAPIFeatureIndex); webapiReverseSendSettings(reverseAPIKeys, settings, fullUpdate || force); } m_settings = settings; } int StarTracker::webapiRun(bool run, SWGSDRangel::SWGDeviceState& response, QString& errorMessage) { (void) errorMessage; getFeatureStateStr(*response.getState()); MsgStartStop *msg = MsgStartStop::create(run); getInputMessageQueue()->push(msg); return 202; } int StarTracker::webapiSettingsGet( SWGSDRangel::SWGFeatureSettings& response, QString& errorMessage) { (void) errorMessage; response.setStarTrackerSettings(new SWGSDRangel::SWGStarTrackerSettings()); response.getStarTrackerSettings()->init(); webapiFormatFeatureSettings(response, m_settings); return 200; } int StarTracker::webapiSettingsPutPatch( bool force, const QStringList& featureSettingsKeys, SWGSDRangel::SWGFeatureSettings& response, QString& errorMessage) { (void) errorMessage; StarTrackerSettings settings = m_settings; webapiUpdateFeatureSettings(settings, featureSettingsKeys, response); MsgConfigureStarTracker *msg = MsgConfigureStarTracker::create(settings, force); m_inputMessageQueue.push(msg); qDebug("StarTracker::webapiSettingsPutPatch: forward to GUI: %p", m_guiMessageQueue); if (m_guiMessageQueue) // forward to GUI if any { MsgConfigureStarTracker *msgToGUI = MsgConfigureStarTracker::create(settings, force); m_guiMessageQueue->push(msgToGUI); } webapiFormatFeatureSettings(response, settings); return 200; } int StarTracker::webapiReportGet( SWGSDRangel::SWGFeatureReport& response, QString& errorMessage) { (void) errorMessage; response.setStarTrackerReport(new SWGSDRangel::SWGStarTrackerReport()); response.getStarTrackerReport()->init(); webapiFormatFeatureReport(response); return 200; } void StarTracker::webapiFormatFeatureReport(SWGSDRangel::SWGFeatureReport& response) { response.getStarTrackerReport()->setRunningState(getState()); } int StarTracker::webapiActionsPost( const QStringList& featureActionsKeys, SWGSDRangel::SWGFeatureActions& query, QString& errorMessage) { SWGSDRangel::SWGStarTrackerActions *swgSWGStarTrackerActions = query.getStarTrackerActions(); if (swgSWGStarTrackerActions) { if (featureActionsKeys.contains("run")) { bool featureRun = swgSWGStarTrackerActions->getRun() != 0; MsgStartStop *msg = MsgStartStop::create(featureRun); getInputMessageQueue()->push(msg); return 202; } else { errorMessage = "Unknown action"; return 400; } } else { errorMessage = "Missing StarTrackerActions in query"; return 400; } } void StarTracker::webapiFormatFeatureSettings( SWGSDRangel::SWGFeatureSettings& response, const StarTrackerSettings& settings) { response.getStarTrackerSettings()->setTarget(new QString(settings.m_target)); response.getStarTrackerSettings()->setRa(new QString(settings.m_ra)); response.getStarTrackerSettings()->setDec(new QString(settings.m_dec)); response.getStarTrackerSettings()->setLatitude(settings.m_latitude); response.getStarTrackerSettings()->setLongitude(settings.m_longitude); response.getStarTrackerSettings()->setDateTime(new QString(settings.m_dateTime)); response.getStarTrackerSettings()->setRefraction(new QString(settings.m_refraction)); response.getStarTrackerSettings()->setPressure(settings.m_pressure); response.getStarTrackerSettings()->setTemperature(settings.m_temperature); response.getStarTrackerSettings()->setHumidity(settings.m_humidity); response.getStarTrackerSettings()->setHeightAboveSeaLevel(settings.m_heightAboveSeaLevel); response.getStarTrackerSettings()->setTemperatureLapseRate(settings.m_temperatureLapseRate); response.getStarTrackerSettings()->setFrequency(settings.m_frequency/1000000.0); response.getStarTrackerSettings()->setStellariumServerEnabled(settings.m_enableServer ? 1 : 0); response.getStarTrackerSettings()->setStellariumPort(settings.m_serverPort); response.getStarTrackerSettings()->setUpdatePeriod(settings.m_updatePeriod); response.getStarTrackerSettings()->setEpoch(settings.m_jnow ? new QString("JNOW") : new QString("J2000")); if (response.getStarTrackerSettings()->getTitle()) { *response.getStarTrackerSettings()->getTitle() = settings.m_title; } else { response.getStarTrackerSettings()->setTitle(new QString(settings.m_title)); } response.getStarTrackerSettings()->setRgbColor(settings.m_rgbColor); response.getStarTrackerSettings()->setUseReverseApi(settings.m_useReverseAPI ? 1 : 0); if (response.getStarTrackerSettings()->getReverseApiAddress()) { *response.getStarTrackerSettings()->getReverseApiAddress() = settings.m_reverseAPIAddress; } else { response.getStarTrackerSettings()->setReverseApiAddress(new QString(settings.m_reverseAPIAddress)); } response.getStarTrackerSettings()->setReverseApiPort(settings.m_reverseAPIPort); response.getStarTrackerSettings()->setReverseApiFeatureSetIndex(settings.m_reverseAPIFeatureSetIndex); response.getStarTrackerSettings()->setReverseApiFeatureIndex(settings.m_reverseAPIFeatureIndex); response.getStarTrackerSettings()->setAzimuth(settings.m_az); response.getStarTrackerSettings()->setElevation(settings.m_el); response.getStarTrackerSettings()->setL(settings.m_l); response.getStarTrackerSettings()->setB(settings.m_b); response.getStarTrackerSettings()->setAzimuthOffset(settings.m_azOffset); response.getStarTrackerSettings()->setElevationOffset(settings.m_elOffset); if (settings.m_rollupState) { if (response.getStarTrackerSettings()->getRollupState()) { settings.m_rollupState->formatTo(response.getStarTrackerSettings()->getRollupState()); } else { SWGSDRangel::SWGRollupState *swgRollupState = new SWGSDRangel::SWGRollupState(); settings.m_rollupState->formatTo(swgRollupState); response.getStarTrackerSettings()->setRollupState(swgRollupState); } } } void StarTracker::webapiUpdateFeatureSettings( StarTrackerSettings& settings, const QStringList& featureSettingsKeys, SWGSDRangel::SWGFeatureSettings& response) { if (featureSettingsKeys.contains("target")) { settings.m_target = *response.getStarTrackerSettings()->getTarget(); } if (featureSettingsKeys.contains("ra")) { settings.m_ra = *response.getStarTrackerSettings()->getRa(); } if (featureSettingsKeys.contains("dec")) { settings.m_dec = *response.getStarTrackerSettings()->getDec(); } if (featureSettingsKeys.contains("latitude")) { settings.m_latitude = response.getStarTrackerSettings()->getLatitude(); } if (featureSettingsKeys.contains("longitude")) { settings.m_longitude = response.getStarTrackerSettings()->getLongitude(); } if (featureSettingsKeys.contains("dateTime")) { settings.m_dateTime = *response.getStarTrackerSettings()->getDateTime(); } if (featureSettingsKeys.contains("pressure")) { settings.m_pressure = response.getStarTrackerSettings()->getPressure(); } if (featureSettingsKeys.contains("temperature")) { settings.m_temperature = response.getStarTrackerSettings()->getTemperature(); } if (featureSettingsKeys.contains("humidity")) { settings.m_humidity = response.getStarTrackerSettings()->getHumidity(); } if (featureSettingsKeys.contains("heightAboveSeaLevel")) { settings.m_heightAboveSeaLevel = response.getStarTrackerSettings()->getHeightAboveSeaLevel(); } if (featureSettingsKeys.contains("temperatureLapseRate")) { settings.m_temperatureLapseRate = response.getStarTrackerSettings()->getTemperatureLapseRate(); } if (featureSettingsKeys.contains("frequency")) { settings.m_frequency = response.getStarTrackerSettings()->getFrequency() * 100000.0; } if (featureSettingsKeys.contains("stellariumServerEnabled")) { settings.m_enableServer = response.getStarTrackerSettings()->getStellariumServerEnabled() == 1; } if (featureSettingsKeys.contains("stellariumPort")) { settings.m_serverPort = response.getStarTrackerSettings()->getStellariumPort(); } if (featureSettingsKeys.contains("updatePeriod")) { settings.m_updatePeriod = response.getStarTrackerSettings()->getUpdatePeriod(); } if (featureSettingsKeys.contains("epoch")) { settings.m_jnow = *response.getStarTrackerSettings()->getEpoch() == "JNOW"; } if (featureSettingsKeys.contains("title")) { settings.m_title = *response.getStarTrackerSettings()->getTitle(); } if (featureSettingsKeys.contains("rgbColor")) { settings.m_rgbColor = response.getStarTrackerSettings()->getRgbColor(); } if (featureSettingsKeys.contains("useReverseAPI")) { settings.m_useReverseAPI = response.getStarTrackerSettings()->getUseReverseApi() != 0; } if (featureSettingsKeys.contains("reverseAPIAddress")) { settings.m_reverseAPIAddress = *response.getStarTrackerSettings()->getReverseApiAddress(); } if (featureSettingsKeys.contains("reverseAPIPort")) { settings.m_reverseAPIPort = response.getStarTrackerSettings()->getReverseApiPort(); } if (featureSettingsKeys.contains("reverseAPIFeatureSetIndex")) { settings.m_reverseAPIFeatureSetIndex = response.getStarTrackerSettings()->getReverseApiFeatureSetIndex(); } if (featureSettingsKeys.contains("reverseAPIFeatureIndex")) { settings.m_reverseAPIFeatureIndex = response.getStarTrackerSettings()->getReverseApiFeatureIndex(); } if (featureSettingsKeys.contains("azimuth")) { settings.m_az = response.getStarTrackerSettings()->getAzimuth(); } if (featureSettingsKeys.contains("elevation")) { settings.m_el = response.getStarTrackerSettings()->getElevation(); } if (featureSettingsKeys.contains("l")) { settings.m_l = response.getStarTrackerSettings()->getL(); } if (featureSettingsKeys.contains("b")) { settings.m_b = response.getStarTrackerSettings()->getB(); } if (featureSettingsKeys.contains("azimuthOffset")) { settings.m_azOffset = response.getStarTrackerSettings()->getAzimuthOffset(); } if (featureSettingsKeys.contains("elevationOffset")) { settings.m_elOffset = response.getStarTrackerSettings()->getElevationOffset(); } if (settings.m_rollupState && featureSettingsKeys.contains("rollupState")) { settings.m_rollupState->updateFrom(featureSettingsKeys, response.getStarTrackerSettings()->getRollupState()); } } void StarTracker::webapiReverseSendSettings(QList& featureSettingsKeys, const StarTrackerSettings& settings, bool force) { SWGSDRangel::SWGFeatureSettings *swgFeatureSettings = new SWGSDRangel::SWGFeatureSettings(); // swgFeatureSettings->setOriginatorFeatureIndex(getIndexInDeviceSet()); // swgFeatureSettings->setOriginatorFeatureSetIndex(getDeviceSetIndex()); swgFeatureSettings->setFeatureType(new QString("StarTracker")); swgFeatureSettings->setStarTrackerSettings(new SWGSDRangel::SWGStarTrackerSettings()); SWGSDRangel::SWGStarTrackerSettings *swgStarTrackerSettings = swgFeatureSettings->getStarTrackerSettings(); // transfer data that has been modified. When force is on transfer all data except reverse API data if (featureSettingsKeys.contains("target") || force) { swgStarTrackerSettings->setTarget(new QString(settings.m_target)); } if (featureSettingsKeys.contains("ra") || force) { swgStarTrackerSettings->setRa(new QString(settings.m_ra)); } if (featureSettingsKeys.contains("dec") || force) { swgStarTrackerSettings->setDec(new QString(settings.m_dec)); } if (featureSettingsKeys.contains("latitude") || force) { swgStarTrackerSettings->setLatitude(settings.m_latitude); } if (featureSettingsKeys.contains("longitude") || force) { swgStarTrackerSettings->setLongitude(settings.m_longitude); } if (featureSettingsKeys.contains("dateTime") || force) { swgStarTrackerSettings->setDateTime(new QString(settings.m_dateTime)); } if (featureSettingsKeys.contains("pressure") || force) { swgStarTrackerSettings->setPressure(settings.m_pressure); } if (featureSettingsKeys.contains("temperature") || force) { swgStarTrackerSettings->setTemperature(settings.m_temperature); } if (featureSettingsKeys.contains("humidity") || force) { swgStarTrackerSettings->setHumidity(settings.m_humidity); } if (featureSettingsKeys.contains("heightAboveSeaLevel") || force) { swgStarTrackerSettings->setHeightAboveSeaLevel(settings.m_heightAboveSeaLevel); } if (featureSettingsKeys.contains("temperatureLapseRate") || force) { swgStarTrackerSettings->setTemperatureLapseRate(settings.m_temperatureLapseRate); } if (featureSettingsKeys.contains("frequency") || force) { swgStarTrackerSettings->setFrequency(settings.m_frequency / 1000000.0); } if (featureSettingsKeys.contains("stellariumServerEnabled") || force) { swgStarTrackerSettings->setStellariumServerEnabled(settings.m_enableServer ? 1 : 0); } if (featureSettingsKeys.contains("stellariumPort") || force) { swgStarTrackerSettings->setStellariumPort(settings.m_serverPort); } if (featureSettingsKeys.contains("updatePeriod") || force) { swgStarTrackerSettings->setUpdatePeriod(settings.m_updatePeriod); } if (featureSettingsKeys.contains("epoch") || force) { swgStarTrackerSettings->setEpoch(settings.m_jnow ? new QString("JNOW") : new QString("J2000")); } if (featureSettingsKeys.contains("title") || force) { swgStarTrackerSettings->setTitle(new QString(settings.m_title)); } if (featureSettingsKeys.contains("rgbColor") || force) { swgStarTrackerSettings->setRgbColor(settings.m_rgbColor); } if (featureSettingsKeys.contains("azimuth") || force) { swgStarTrackerSettings->setAzimuth(settings.m_az); } if (featureSettingsKeys.contains("elevation") || force) { swgStarTrackerSettings->setElevation(settings.m_el); } if (featureSettingsKeys.contains("l") || force) { swgStarTrackerSettings->setL(settings.m_l); } if (featureSettingsKeys.contains("b") || force) { swgStarTrackerSettings->setB(settings.m_b); } if (featureSettingsKeys.contains("azimuthOffset") || force) { swgStarTrackerSettings->setAzimuthOffset(settings.m_azOffset); } if (featureSettingsKeys.contains("elevationOffset") || force) { swgStarTrackerSettings->setElevationOffset(settings.m_elOffset); } QString channelSettingsURL = QString("http://%1:%2/sdrangel/featureset/%3/feature/%4/settings") .arg(settings.m_reverseAPIAddress) .arg(settings.m_reverseAPIPort) .arg(settings.m_reverseAPIFeatureSetIndex) .arg(settings.m_reverseAPIFeatureIndex); m_networkRequest.setUrl(QUrl(channelSettingsURL)); m_networkRequest.setHeader(QNetworkRequest::ContentTypeHeader, "application/json"); QBuffer *buffer = new QBuffer(); buffer->open((QBuffer::ReadWrite)); buffer->write(swgFeatureSettings->asJson().toUtf8()); buffer->seek(0); // Always use PATCH to avoid passing reverse API settings QNetworkReply *reply = m_networkManager->sendCustomRequest(m_networkRequest, "PATCH", buffer); buffer->setParent(reply); delete swgFeatureSettings; } void StarTracker::networkManagerFinished(QNetworkReply *reply) { QNetworkReply::NetworkError replyError = reply->error(); if (replyError) { qWarning() << "StarTracker::networkManagerFinished:" << " error(" << (int) replyError << "): " << replyError << ": " << reply->errorString(); } else { QString answer = reply->readAll(); answer.chop(1); // remove last \n qDebug("StarTracker::networkManagerFinished: reply:\n%s", answer.toStdString().c_str()); } reply->deleteLater(); } void StarTracker::weatherUpdated(float temperature, float pressure, float humidity) { if (!std::isnan(temperature)) { m_settings.m_temperature = temperature; } if (!std::isnan(pressure)) { m_settings.m_pressure = pressure; } if (!std::isnan(humidity)) { m_settings.m_humidity = humidity; } m_worker->getInputMessageQueue()->push(StarTrackerWorker::MsgConfigureStarTrackerWorker::create(m_settings, false)); if (m_guiMessageQueue) { m_guiMessageQueue->push(MsgConfigureStarTracker::create(m_settings, false)); } } double StarTracker::applyBeam(const FITS *fits, double beamwidth, double ra, double dec, int& imgX, int& imgY) const { const double halfBeamwidth = beamwidth/2.0; // Use cos^p(x) for approximation of radiation pattern // (Essentially the same as Gaussian of exp(-4*ln(theta^2/beamwidth^2)) // (See a2 in https://arxiv.org/pdf/1812.10084.pdf for Elliptical equivalent)) // We have gain of 0dB (1) at 0 degrees, and -3dB (~0.5) at half-beamwidth degrees // Find exponent that correponds to -3dB at that angle double minus3dBLinear = pow(10.0, -3.0/10.0); double p = log(minus3dBLinear)/log(cos(Units::degreesToRadians(halfBeamwidth))); // Create an matrix with gain as a function of angle double degreesPerPixelH = abs(fits->degreesPerPixelH()); double degreesPerPixelV = abs(fits->degreesPerPixelV()); int numberOfCoeffsH = ceil(beamwidth/degreesPerPixelH); int numberOfCoeffsV = ceil(beamwidth/degreesPerPixelV); if ((numberOfCoeffsH & 1) == 0) { numberOfCoeffsH++; } if ((numberOfCoeffsV & 1) == 0) { numberOfCoeffsV++; } double *beam = new double[numberOfCoeffsH*numberOfCoeffsV]; double sum = 0.0; int y0 = numberOfCoeffsV/2; int x0 = numberOfCoeffsH/2; int nonZeroCount = 0; for (int y = 0; y < numberOfCoeffsV; y++) { for (int x = 0; x < numberOfCoeffsH; x++) { double xp = (x - x0) * degreesPerPixelH; double yp = (y - y0) * degreesPerPixelV; double r = sqrt(xp*xp+yp*yp); if (r < halfBeamwidth) { beam[y*numberOfCoeffsH+x] = pow(cos(Units::degreesToRadians(r)), p); sum += beam[y*numberOfCoeffsH+x]; nonZeroCount++; } else { beam[y*numberOfCoeffsH+x] = 0.0; } } } // Get centre pixel coordinates double centreX; if (ra <= 12.0) { centreX = (12.0 - ra) / 24.0; } else { centreX = (24 - ra + 12) / 24.0; } double centreY = (90.0-dec) / 180.0; imgX = centreX * fits->width(); imgY = centreY * fits->height(); // Apply weighting to temperature data double weightedSum = 0.0; for (int y = 0; y < numberOfCoeffsV; y++) { for (int x = 0; x < numberOfCoeffsH; x++) { weightedSum += beam[y*numberOfCoeffsH+x] * fits->scaledWrappedValue(imgX + (x-x0), imgY + (y-y0)); } } // From: https://www.cv.nrao.edu/~sransom/web/Ch3.html // The antenna temperature equals the source brightness temperature multiplied by the fraction of the beam solid angle filled by the source // So we scale the sum by the total number of non-zero pixels (i.e. beam area) // If we compare to some maps with different beamwidths here: https://www.cv.nrao.edu/~demerson/radiosky/sky_jun96.pdf // The values we've computed are a bit higher.. double temp = weightedSum/nonZeroCount; delete[] beam; return temp; } bool StarTracker::calcSkyTemperature(double frequency, double beamwidth, double ra, double dec, double& temp) const { const FITS *fits; int imgX, imgY; if ((frequency >= 1.4e9) && (frequency <= 1.45e9)) { // Adjust temperature from 1420MHz FITS file, just using beamwidth fits = getTempFITS(2); if (fits && fits->valid()) { temp = applyBeam(fits, beamwidth, ra, dec, imgX, imgY); return true; } else { qDebug() << "StarTracker::calcSkyTemperature: 1420MHz FITS temperature file not valid"; return false; } } else { // Adjust temperature from 408MHz FITS file, taking in to account // observation frequency and beamwidth fits = getTempFITS(1); if (fits && fits->valid()) { double temp408 = applyBeam(fits, beamwidth, ra, dec, imgX, imgY); // Scale according to frequency - CMB contribution constant // Power law at low frequencies, with slight variation in spectral index // See: // Global Sky Model: https://ascl.net/1011.010 // An improved Model of Diffuse Galactic Radio Emission: https://arxiv.org/pdf/1605.04920.pdf // A high-resolution self-consistent whole sky foreground model: https://arxiv.org/abs/1812.10084 // (De-striping:) Full sky study of diffuse Galactic emission at decimeter wavelength https://www.aanda.org/articles/aa/pdf/2003/42/aah4363.pdf // Data here: http://cdsarc.u-strasbg.fr/viz-bin/cat/J/A+A/410/847 // LFmap: https://www.faculty.ece.vt.edu/swe/lwa/memo/lwa0111.pdf double iso408 = 50 * pow(150e6/408e6, 2.75); // Extra-galactic isotropic in reference map at 408MHz double isoT = 50 * pow(150e6/frequency, 2.75); // Extra-galactic isotropic at target frequency double cmbT = 2.725; // Cosmic microwave backgroud; double spectralIndex; const FITS *spectralIndexFITS = getSpectralIndexFITS(); if (spectralIndexFITS && spectralIndexFITS->valid()) { // See https://www.aanda.org/articles/aa/pdf/2003/42/aah4363.pdf spectralIndex = spectralIndexFITS->scaledValue(imgX, imgY); } else { // See https://arxiv.org/abs/1812.10084 fig 2 if (frequency < 200e6) { spectralIndex = 2.55; } else if (frequency < 20e9) { spectralIndex = 2.695; } else { spectralIndex = 3.1; } } double galactic480 = temp408 - cmbT - iso408; double galacticT = galactic480 * pow(408e6/frequency, spectralIndex); // Scale galactic contribution by frequency temp = galacticT + cmbT + isoT; // Final temperature return true; } else { qDebug() << "StarTracker::calcSkyTemperature: 408MHz FITS temperature file not valid"; return false; } } }