#include "AP_NavEKF2.h" #include #include void NavEKF2::Log_Write_EKF1(uint8_t _core, LogMessages msg_id, uint64_t time_us) const { // Write first EKF packet Vector3f euler; Vector2f posNE; float posD; Vector3f velNED; Vector3f gyroBias; float posDownDeriv; Location originLLH; getEulerAngles(_core,euler); getVelNED(_core,velNED); getPosNE(_core,posNE); getPosD(_core,posD); getGyroBias(_core,gyroBias); posDownDeriv = getPosDownDerivative(_core); if (!getOriginLLH(_core,originLLH)) { originLLH.alt = 0; } const struct log_EKF1 pkt{ LOG_PACKET_HEADER_INIT(msg_id), time_us : time_us, roll : (int16_t)(100*degrees(euler.x)), // roll angle (centi-deg, displayed as deg due to format string) pitch : (int16_t)(100*degrees(euler.y)), // pitch angle (centi-deg, displayed as deg due to format string) yaw : (uint16_t)wrap_360_cd(100*degrees(euler.z)), // yaw angle (centi-deg, displayed as deg due to format string) velN : (float)(velNED.x), // velocity North (m/s) velE : (float)(velNED.y), // velocity East (m/s) velD : (float)(velNED.z), // velocity Down (m/s) posD_dot : (float)(posDownDeriv), // first derivative of down position posN : (float)(posNE.x), // metres North posE : (float)(posNE.y), // metres East posD : (float)(posD), // metres Down gyrX : (int16_t)(100*degrees(gyroBias.x)), // cd/sec, displayed as deg/sec due to format string gyrY : (int16_t)(100*degrees(gyroBias.y)), // cd/sec, displayed as deg/sec due to format string gyrZ : (int16_t)(100*degrees(gyroBias.z)), // cd/sec, displayed as deg/sec due to format string originHgt : originLLH.alt // WGS-84 altitude of EKF origin in cm }; AP::logger().WriteBlock(&pkt, sizeof(pkt)); } void NavEKF2::Log_Write_NKF2(uint8_t _core, LogMessages msg_id, uint64_t time_us) const { // Write second EKF packet float azbias = 0; Vector3f wind; Vector3f magNED; Vector3f magXYZ; Vector3f gyroScaleFactor; uint8_t magIndex = getActiveMag(_core); getAccelZBias(_core,azbias); getWind(_core,wind); getMagNED(_core,magNED); getMagXYZ(_core,magXYZ); getGyroScaleErrorPercentage(_core,gyroScaleFactor); const struct log_NKF2 pkt2{ LOG_PACKET_HEADER_INIT(msg_id), time_us : time_us, AZbias : (int8_t)(100*azbias), scaleX : (int16_t)(100*gyroScaleFactor.x), scaleY : (int16_t)(100*gyroScaleFactor.y), scaleZ : (int16_t)(100*gyroScaleFactor.z), windN : (int16_t)(100*wind.x), windE : (int16_t)(100*wind.y), magN : (int16_t)(magNED.x), magE : (int16_t)(magNED.y), magD : (int16_t)(magNED.z), magX : (int16_t)(magXYZ.x), magY : (int16_t)(magXYZ.y), magZ : (int16_t)(magXYZ.z), index : (uint8_t)(magIndex) }; AP::logger().WriteBlock(&pkt2, sizeof(pkt2)); } void NavEKF2::Log_Write_NKF3(uint8_t _core, LogMessages msg_id, uint64_t time_us) const { // Write third EKF packet Vector3f velInnov; Vector3f posInnov; Vector3f magInnov; float tasInnov = 0; float yawInnov = 0; getInnovations(_core,velInnov, posInnov, magInnov, tasInnov, yawInnov); const struct log_NKF3 pkt3{ LOG_PACKET_HEADER_INIT(msg_id), time_us : time_us, innovVN : (int16_t)(100*velInnov.x), innovVE : (int16_t)(100*velInnov.y), innovVD : (int16_t)(100*velInnov.z), innovPN : (int16_t)(100*posInnov.x), innovPE : (int16_t)(100*posInnov.y), innovPD : (int16_t)(100*posInnov.z), innovMX : (int16_t)(magInnov.x), innovMY : (int16_t)(magInnov.y), innovMZ : (int16_t)(magInnov.z), innovYaw : (int16_t)(100*degrees(yawInnov)), innovVT : (int16_t)(100*tasInnov) }; AP::logger().WriteBlock(&pkt3, sizeof(pkt3)); } void NavEKF2::Log_Write_NKF4(uint8_t _core, LogMessages msg_id, uint64_t time_us) const { // Write fourth EKF packet float velVar = 0; float posVar = 0; float hgtVar = 0; Vector3f magVar; float tasVar = 0; Vector2f offset; uint16_t faultStatus=0; uint8_t timeoutStatus=0; nav_filter_status solutionStatus {}; nav_gps_status gpsStatus {}; getVariances(_core,velVar, posVar, hgtVar, magVar, tasVar, offset); float tempVar = fmaxf(fmaxf(magVar.x,magVar.y),magVar.z); getFilterFaults(_core,faultStatus); getFilterTimeouts(_core,timeoutStatus); getFilterStatus(_core,solutionStatus); getFilterGpsStatus(_core,gpsStatus); float tiltError; getTiltError(_core,tiltError); int8_t primaryIndex = getPrimaryCoreIndex(); const struct log_NKF4 pkt4{ LOG_PACKET_HEADER_INIT(msg_id), time_us : time_us, sqrtvarV : (int16_t)(100*velVar), sqrtvarP : (int16_t)(100*posVar), sqrtvarH : (int16_t)(100*hgtVar), sqrtvarM : (int16_t)(100*tempVar), sqrtvarVT : (int16_t)(100*tasVar), tiltErr : (float)tiltError, offsetNorth : (int8_t)(offset.x), offsetEast : (int8_t)(offset.y), faults : (uint16_t)(faultStatus), timeouts : (uint8_t)(timeoutStatus), solution : (uint16_t)(solutionStatus.value), gps : (uint16_t)(gpsStatus.value), primary : (int8_t)primaryIndex }; AP::logger().WriteBlock(&pkt4, sizeof(pkt4)); } void NavEKF2::Log_Write_NKF5(uint64_t time_us) const { // Write fifth EKF packet - take data from the primary instance float normInnov=0; // normalised innovation variance ratio for optical flow observations fused by the main nav filter float gndOffset=0; // estimated vertical position of the terrain relative to the nav filter zero datum float flowInnovX=0, flowInnovY=0; // optical flow LOS rate vector innovations from the main nav filter float auxFlowInnov=0; // optical flow LOS rate innovation from terrain offset estimator float HAGL=0; // height above ground level float rngInnov=0; // range finder innovations float range=0; // measured range float gndOffsetErr=0; // filter ground offset state error Vector3f predictorErrors; // output predictor angle, velocity and position tracking error getFlowDebug(-1,normInnov, gndOffset, flowInnovX, flowInnovY, auxFlowInnov, HAGL, rngInnov, range, gndOffsetErr); getOutputTrackingError(-1,predictorErrors); const struct log_NKF5 pkt5{ LOG_PACKET_HEADER_INIT(LOG_NKF5_MSG), time_us : time_us, normInnov : (uint8_t)(MIN(100*normInnov,255)), FIX : (int16_t)(1000*flowInnovX), FIY : (int16_t)(1000*flowInnovY), AFI : (int16_t)(1000*auxFlowInnov), HAGL : (int16_t)(100*HAGL), offset : (int16_t)(100*gndOffset), RI : (int16_t)(100*rngInnov), meaRng : (uint16_t)(100*range), errHAGL : (uint16_t)(100*gndOffsetErr), angErr : (float)predictorErrors.x, velErr : (float)predictorErrors.y, posErr : (float)predictorErrors.z }; AP::logger().WriteBlock(&pkt5, sizeof(pkt5)); } void NavEKF2::Log_Write_Quaternion(uint8_t _core, LogMessages msg_id, uint64_t time_us) const { // log quaternion Quaternion quat; getQuaternion(_core, quat); const struct log_Quaternion pktq1{ LOG_PACKET_HEADER_INIT(msg_id), time_us : time_us, q1 : quat.q1, q2 : quat.q2, q3 : quat.q3, q4 : quat.q4 }; AP::logger().WriteBlock(&pktq1, sizeof(pktq1)); } void NavEKF2::Log_Write_Beacon(uint64_t time_us) const { if (AP::beacon() != nullptr) { uint8_t ID; float rng; float innovVar; float innov; float testRatio; Vector3f beaconPosNED; float bcnPosOffsetHigh; float bcnPosOffsetLow; if (getRangeBeaconDebug(-1, ID, rng, innov, innovVar, testRatio, beaconPosNED, bcnPosOffsetHigh, bcnPosOffsetLow)) { if (rng > 0.0f) { struct log_RngBcnDebug pkt10 = { LOG_PACKET_HEADER_INIT(LOG_NKF10_MSG), time_us : time_us, ID : (uint8_t)ID, rng : (int16_t)(100*rng), innov : (int16_t)(100*innov), sqrtInnovVar : (uint16_t)(100*safe_sqrt(innovVar)), testRatio : (uint16_t)(100*constrain_float(testRatio,0.0f,650.0f)), beaconPosN : (int16_t)(100*beaconPosNED.x), beaconPosE : (int16_t)(100*beaconPosNED.y), beaconPosD : (int16_t)(100*beaconPosNED.z), offsetHigh : (int16_t)(100*bcnPosOffsetHigh), offsetLow : (int16_t)(100*bcnPosOffsetLow), posN : 0, posE : 0, posD : 0 }; AP::logger().WriteBlock(&pkt10, sizeof(pkt10)); } } } } void NavEKF2::Log_Write() { // only log if enabled if (activeCores() <= 0) { return; } const uint64_t time_us = AP_HAL::micros64(); Log_Write_EKF1(0, LOG_NKF1_MSG, time_us); Log_Write_NKF2(0, LOG_NKF2_MSG, time_us); Log_Write_NKF3(0, LOG_NKF3_MSG, time_us); Log_Write_NKF4(0, LOG_NKF4_MSG, time_us); Log_Write_NKF5(time_us); Log_Write_Quaternion(0, LOG_NKQ1_MSG, time_us); // log innovations for the second IMU if enabled if (activeCores() >= 2) { Log_Write_EKF1(1, LOG_NKF6_MSG, time_us); Log_Write_NKF2(1, LOG_NKF7_MSG, time_us); Log_Write_NKF3(1, LOG_NKF8_MSG, time_us); Log_Write_NKF4(1, LOG_NKF9_MSG, time_us); Log_Write_Quaternion(1, LOG_NKQ2_MSG, time_us); } // write range beacon fusion debug packet if the range value is non-zero Log_Write_Beacon(time_us); // log EKF timing statistics every 5s static uint32_t lastTimingLogTime_ms = 0; if (AP_HAL::millis() - lastTimingLogTime_ms > 5000) { lastTimingLogTime_ms = AP_HAL::millis(); struct ekf_timing timing; for (uint8_t i=0; i