#include #include #include #include #include #include #include #include #include #include #include #include #include "AP_Logger.h" #include "AP_Logger_File.h" #include "AP_Logger_MAVLink.h" #include "LoggerMessageWriter.h" extern const AP_HAL::HAL& hal; /* write a structure format to the log - should be in frontend */ void AP_Logger_Backend::Fill_Format(const struct LogStructure *s, struct log_Format &pkt) { memset(&pkt, 0, sizeof(pkt)); pkt.head1 = HEAD_BYTE1; pkt.head2 = HEAD_BYTE2; pkt.msgid = LOG_FORMAT_MSG; pkt.type = s->msg_type; pkt.length = s->msg_len; strncpy(pkt.name, s->name, sizeof(pkt.name)); strncpy(pkt.format, s->format, sizeof(pkt.format)); strncpy(pkt.labels, s->labels, sizeof(pkt.labels)); } /* Pack a LogStructure packet into a structure suitable to go to the logfile: */ void AP_Logger_Backend::Fill_Format_Units(const struct LogStructure *s, struct log_Format_Units &pkt) { memset(&pkt, 0, sizeof(pkt)); pkt.head1 = HEAD_BYTE1; pkt.head2 = HEAD_BYTE2; pkt.msgid = LOG_FORMAT_UNITS_MSG; pkt.time_us = AP_HAL::micros64(); pkt.format_type = s->msg_type; strncpy(pkt.units, s->units, sizeof(pkt.units)); strncpy(pkt.multipliers, s->multipliers, sizeof(pkt.multipliers)); } /* write a structure format to the log */ bool AP_Logger_Backend::Write_Format(const struct LogStructure *s) { struct log_Format pkt; Fill_Format(s, pkt); return WriteCriticalBlock(&pkt, sizeof(pkt)); } /* write a unit definition */ bool AP_Logger_Backend::Write_Unit(const struct UnitStructure *s) { struct log_Unit pkt = { LOG_PACKET_HEADER_INIT(LOG_UNIT_MSG), time_us : AP_HAL::micros64(), type : s->ID, unit : { } }; strncpy(pkt.unit, s->unit, sizeof(pkt.unit)); return WriteCriticalBlock(&pkt, sizeof(pkt)); } /* write a unit-multiplier definition */ bool AP_Logger_Backend::Write_Multiplier(const struct MultiplierStructure *s) { struct log_Format_Multiplier pkt = { LOG_PACKET_HEADER_INIT(LOG_MULT_MSG), time_us : AP_HAL::micros64(), type : s->ID, multiplier : s->multiplier, }; return WriteCriticalBlock(&pkt, sizeof(pkt)); } /* write the units for a format to the log */ bool AP_Logger_Backend::Write_Format_Units(const struct LogStructure *s) { struct log_Format_Units pkt; Fill_Format_Units(s, pkt); return WriteCriticalBlock(&pkt, sizeof(pkt)); } /* write a parameter to the log */ bool AP_Logger_Backend::Write_Parameter(const char *name, float value) { struct log_Parameter pkt = { LOG_PACKET_HEADER_INIT(LOG_PARAMETER_MSG), time_us : AP_HAL::micros64(), name : {}, value : value }; strncpy(pkt.name, name, sizeof(pkt.name)); return WriteCriticalBlock(&pkt, sizeof(pkt)); } /* write a parameter to the log */ bool AP_Logger_Backend::Write_Parameter(const AP_Param *ap, const AP_Param::ParamToken &token, enum ap_var_type type) { char name[16]; ap->copy_name_token(token, &name[0], sizeof(name), true); return Write_Parameter(name, ap->cast_to_float(type)); } // Write an GPS packet void AP_Logger::Write_GPS(uint8_t i, uint64_t time_us) { const AP_GPS &gps = AP::gps(); if (time_us == 0) { time_us = AP_HAL::micros64(); } const struct Location &loc = gps.location(i); struct log_GPS pkt = { LOG_PACKET_HEADER_INIT((uint8_t)(LOG_GPS_MSG+i)), time_us : time_us, status : (uint8_t)gps.status(i), gps_week_ms : gps.time_week_ms(i), gps_week : gps.time_week(i), num_sats : gps.num_sats(i), hdop : gps.get_hdop(i), latitude : loc.lat, longitude : loc.lng, altitude : loc.alt, ground_speed : gps.ground_speed(i), ground_course : gps.ground_course(i), vel_z : gps.velocity(i).z, used : (uint8_t)(gps.primary_sensor() == i) }; WriteBlock(&pkt, sizeof(pkt)); /* write auxiliary accuracy information as well */ float hacc = 0, vacc = 0, sacc = 0; gps.horizontal_accuracy(i, hacc); gps.vertical_accuracy(i, vacc); gps.speed_accuracy(i, sacc); struct log_GPA pkt2 = { LOG_PACKET_HEADER_INIT((uint8_t)(LOG_GPA_MSG+i)), time_us : time_us, vdop : gps.get_vdop(i), hacc : (uint16_t)MIN((hacc*100), UINT16_MAX), vacc : (uint16_t)MIN((vacc*100), UINT16_MAX), sacc : (uint16_t)MIN((sacc*100), UINT16_MAX), have_vv : (uint8_t)gps.have_vertical_velocity(i), sample_ms : gps.last_message_time_ms(i), delta_ms : gps.last_message_delta_time_ms(i) }; WriteBlock(&pkt2, sizeof(pkt2)); } // Write an RCIN packet void AP_Logger::Write_RCIN(void) { uint16_t values[14] = {}; rc().get_radio_in(values, ARRAY_SIZE(values)); struct log_RCIN pkt = { LOG_PACKET_HEADER_INIT(LOG_RCIN_MSG), time_us : AP_HAL::micros64(), chan1 : values[0], chan2 : values[1], chan3 : values[2], chan4 : values[3], chan5 : values[4], chan6 : values[5], chan7 : values[6], chan8 : values[7], chan9 : values[8], chan10 : values[9], chan11 : values[10], chan12 : values[11], chan13 : values[12], chan14 : values[13] }; WriteBlock(&pkt, sizeof(pkt)); } // Write an SERVO packet void AP_Logger::Write_RCOUT(void) { struct log_RCOUT pkt = { LOG_PACKET_HEADER_INIT(LOG_RCOUT_MSG), time_us : AP_HAL::micros64(), chan1 : hal.rcout->read(0), chan2 : hal.rcout->read(1), chan3 : hal.rcout->read(2), chan4 : hal.rcout->read(3), chan5 : hal.rcout->read(4), chan6 : hal.rcout->read(5), chan7 : hal.rcout->read(6), chan8 : hal.rcout->read(7), chan9 : hal.rcout->read(8), chan10 : hal.rcout->read(9), chan11 : hal.rcout->read(10), chan12 : hal.rcout->read(11), chan13 : hal.rcout->read(12), chan14 : hal.rcout->read(13) }; WriteBlock(&pkt, sizeof(pkt)); } // Write an RSSI packet void AP_Logger::Write_RSSI() { AP_RSSI *rssi = AP::rssi(); if (rssi == nullptr) { return; } struct log_RSSI pkt = { LOG_PACKET_HEADER_INIT(LOG_RSSI_MSG), time_us : AP_HAL::micros64(), RXRSSI : rssi->read_receiver_rssi() }; WriteBlock(&pkt, sizeof(pkt)); } void AP_Logger::Write_Baro_instance(uint64_t time_us, uint8_t baro_instance, enum LogMessages type) { AP_Baro &baro = AP::baro(); float climbrate = baro.get_climb_rate(); float drift_offset = baro.get_baro_drift_offset(); float ground_temp = baro.get_ground_temperature(); struct log_BARO pkt = { LOG_PACKET_HEADER_INIT(type), time_us : time_us, altitude : baro.get_altitude(baro_instance), pressure : baro.get_pressure(baro_instance), temperature : (int16_t)(baro.get_temperature(baro_instance) * 100 + 0.5f), climbrate : climbrate, sample_time_ms: baro.get_last_update(baro_instance), drift_offset : drift_offset, ground_temp : ground_temp, }; WriteBlock(&pkt, sizeof(pkt)); } // Write a BARO packet void AP_Logger::Write_Baro(uint64_t time_us) { if (time_us == 0) { time_us = AP_HAL::micros64(); } const AP_Baro &baro = AP::baro(); Write_Baro_instance(time_us, 0, LOG_BARO_MSG); if (baro.num_instances() > 1 && baro.healthy(1)) { Write_Baro_instance(time_us, 1, LOG_BAR2_MSG); } if (baro.num_instances() > 2 && baro.healthy(2)) { Write_Baro_instance(time_us, 2, LOG_BAR3_MSG); } } void AP_Logger::Write_IMU_instance(const uint64_t time_us, const uint8_t imu_instance, const enum LogMessages type) { const AP_InertialSensor &ins = AP::ins(); const Vector3f &gyro = ins.get_gyro(imu_instance); const Vector3f &accel = ins.get_accel(imu_instance); struct log_IMU pkt = { LOG_PACKET_HEADER_INIT(type), time_us : time_us, gyro_x : gyro.x, gyro_y : gyro.y, gyro_z : gyro.z, accel_x : accel.x, accel_y : accel.y, accel_z : accel.z, gyro_error : ins.get_gyro_error_count(imu_instance), accel_error : ins.get_accel_error_count(imu_instance), temperature : ins.get_temperature(imu_instance), gyro_health : (uint8_t)ins.get_gyro_health(imu_instance), accel_health : (uint8_t)ins.get_accel_health(imu_instance), gyro_rate : ins.get_gyro_rate_hz(imu_instance), accel_rate : ins.get_accel_rate_hz(imu_instance), }; WriteBlock(&pkt, sizeof(pkt)); } // Write an raw accel/gyro data packet void AP_Logger::Write_IMU() { uint64_t time_us = AP_HAL::micros64(); const AP_InertialSensor &ins = AP::ins(); Write_IMU_instance(time_us, 0, LOG_IMU_MSG); if (ins.get_gyro_count() < 2 && ins.get_accel_count() < 2) { return; } Write_IMU_instance(time_us, 1, LOG_IMU2_MSG); if (ins.get_gyro_count() < 3 && ins.get_accel_count() < 3) { return; } Write_IMU_instance(time_us, 2, LOG_IMU3_MSG); } // Write an accel/gyro delta time data packet void AP_Logger::Write_IMUDT_instance(const uint64_t time_us, const uint8_t imu_instance, const enum LogMessages type) { const AP_InertialSensor &ins = AP::ins(); float delta_t = ins.get_delta_time(); float delta_vel_t = ins.get_delta_velocity_dt(imu_instance); float delta_ang_t = ins.get_delta_angle_dt(imu_instance); Vector3f delta_angle, delta_velocity; ins.get_delta_angle(imu_instance, delta_angle); ins.get_delta_velocity(imu_instance, delta_velocity); struct log_IMUDT pkt = { LOG_PACKET_HEADER_INIT(type), time_us : time_us, delta_time : delta_t, delta_vel_dt : delta_vel_t, delta_ang_dt : delta_ang_t, delta_ang_x : delta_angle.x, delta_ang_y : delta_angle.y, delta_ang_z : delta_angle.z, delta_vel_x : delta_velocity.x, delta_vel_y : delta_velocity.y, delta_vel_z : delta_velocity.z }; WriteBlock(&pkt, sizeof(pkt)); } void AP_Logger::Write_IMUDT(uint64_t time_us, uint8_t imu_mask) { const AP_InertialSensor &ins = AP::ins(); if (imu_mask & 1) { Write_IMUDT_instance(time_us, 0, LOG_IMUDT_MSG); } if ((ins.get_gyro_count() < 2 && ins.get_accel_count() < 2) || !ins.use_gyro(1)) { return; } if (imu_mask & 2) { Write_IMUDT_instance(time_us, 1, LOG_IMUDT2_MSG); } if ((ins.get_gyro_count() < 3 && ins.get_accel_count() < 3) || !ins.use_gyro(2)) { return; } if (imu_mask & 4) { Write_IMUDT_instance(time_us, 2, LOG_IMUDT3_MSG); } } void AP_Logger::Write_Vibration() { uint64_t time_us = AP_HAL::micros64(); const AP_InertialSensor &ins = AP::ins(); const Vector3f vibration = ins.get_vibration_levels(); struct log_Vibe pkt = { LOG_PACKET_HEADER_INIT(LOG_VIBE_MSG), time_us : time_us, vibe_x : vibration.x, vibe_y : vibration.y, vibe_z : vibration.z, clipping_0 : ins.get_accel_clip_count(0), clipping_1 : ins.get_accel_clip_count(1), clipping_2 : ins.get_accel_clip_count(2) }; WriteBlock(&pkt, sizeof(pkt)); } bool AP_Logger_Backend::Write_Mission_Cmd(const AP_Mission &mission, const AP_Mission::Mission_Command &cmd) { mavlink_mission_item_int_t mav_cmd = {}; AP_Mission::mission_cmd_to_mavlink_int(cmd,mav_cmd); struct log_Cmd pkt = { LOG_PACKET_HEADER_INIT(LOG_CMD_MSG), time_us : AP_HAL::micros64(), command_total : mission.num_commands(), sequence : mav_cmd.seq, command : mav_cmd.command, param1 : mav_cmd.param1, param2 : mav_cmd.param2, param3 : mav_cmd.param3, param4 : mav_cmd.param4, latitude : mav_cmd.x, longitude : mav_cmd.y, altitude : mav_cmd.z, frame : mav_cmd.frame }; return WriteBlock(&pkt, sizeof(pkt)); } void AP_Logger_Backend::Write_EntireMission() { LoggerMessageWriter_WriteEntireMission writer; writer.set_logger_backend(this); writer.process(); } // Write a text message to the log bool AP_Logger_Backend::Write_Message(const char *message) { struct log_Message pkt = { LOG_PACKET_HEADER_INIT(LOG_MESSAGE_MSG), time_us : AP_HAL::micros64(), msg : {} }; strncpy(pkt.msg, message, sizeof(pkt.msg)); return WriteCriticalBlock(&pkt, sizeof(pkt)); } void AP_Logger::Write_Power(void) { #if CONFIG_HAL_BOARD == HAL_BOARD_CHIBIOS uint8_t safety_and_armed = uint8_t(hal.util->safety_switch_state()); if (hal.util->get_soft_armed()) { // encode armed state in bit 3 safety_and_armed |= 1U<<2; } struct log_POWR pkt = { LOG_PACKET_HEADER_INIT(LOG_POWR_MSG), time_us : AP_HAL::micros64(), Vcc : hal.analogin->board_voltage(), Vservo : hal.analogin->servorail_voltage(), flags : hal.analogin->power_status_flags(), safety_and_arm : safety_and_armed }; WriteBlock(&pkt, sizeof(pkt)); #endif } // Write an AHRS2 packet void AP_Logger::Write_AHRS2(AP_AHRS &ahrs) { Vector3f euler; struct Location loc; Quaternion quat; if (!ahrs.get_secondary_attitude(euler) || !ahrs.get_secondary_position(loc) || !ahrs.get_secondary_quaternion(quat)) { return; } struct log_AHRS pkt = { LOG_PACKET_HEADER_INIT(LOG_AHR2_MSG), time_us : AP_HAL::micros64(), roll : (int16_t)(degrees(euler.x)*100), pitch : (int16_t)(degrees(euler.y)*100), yaw : (uint16_t)(wrap_360_cd(degrees(euler.z)*100)), alt : loc.alt*1.0e-2f, lat : loc.lat, lng : loc.lng, q1 : quat.q1, q2 : quat.q2, q3 : quat.q3, q4 : quat.q4, }; WriteBlock(&pkt, sizeof(pkt)); } // Write a POS packet void AP_Logger::Write_POS(AP_AHRS &ahrs) { Location loc; if (!ahrs.get_position(loc)) { return; } float home, origin; ahrs.get_relative_position_D_home(home); struct log_POS pkt = { LOG_PACKET_HEADER_INIT(LOG_POS_MSG), time_us : AP_HAL::micros64(), lat : loc.lat, lng : loc.lng, alt : loc.alt*1.0e-2f, rel_home_alt : -home, rel_origin_alt : ahrs.get_relative_position_D_origin(origin) ? -origin : quiet_nanf(), }; WriteBlock(&pkt, sizeof(pkt)); } #if AP_AHRS_NAVEKF_AVAILABLE void AP_Logger::Write_EKF(AP_AHRS_NavEKF &ahrs) { // only log EKF2 if enabled if (ahrs.get_NavEKF2().activeCores() > 0) { Write_EKF2(ahrs); } // only log EKF3 if enabled if (ahrs.get_NavEKF3().activeCores() > 0) { Write_EKF3(ahrs); } } /* write an EKF timing message */ void AP_Logger::Write_EKF_Timing(const char *name, uint64_t time_us, const struct ekf_timing &timing) { Write(name, "TimeUS,Cnt,IMUMin,IMUMax,EKFMin,EKFMax,AngMin,AngMax,VMin,VMax", "QIffffffff", time_us, timing.count, (double)timing.dtIMUavg_min, (double)timing.dtIMUavg_max, (double)timing.dtEKFavg_min, (double)timing.dtEKFavg_max, (double)timing.delAngDT_min, (double)timing.delAngDT_max, (double)timing.delVelDT_min, (double)timing.delVelDT_max); } void AP_Logger::Write_EKF2(AP_AHRS_NavEKF &ahrs) { uint64_t time_us = AP_HAL::micros64(); // Write first EKF packet Vector3f euler; Vector2f posNE; float posD; Vector3f velNED; Vector3f gyroBias; float posDownDeriv; Location originLLH; ahrs.get_NavEKF2().getEulerAngles(0,euler); ahrs.get_NavEKF2().getVelNED(0,velNED); ahrs.get_NavEKF2().getPosNE(0,posNE); ahrs.get_NavEKF2().getPosD(0,posD); ahrs.get_NavEKF2().getGyroBias(0,gyroBias); posDownDeriv = ahrs.get_NavEKF2().getPosDownDerivative(0); if (!ahrs.get_NavEKF2().getOriginLLH(0,originLLH)) { originLLH.alt = 0; } struct log_EKF1 pkt = { LOG_PACKET_HEADER_INIT(LOG_NKF1_MSG), 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 }; WriteBlock(&pkt, sizeof(pkt)); // Write second EKF packet float azbias = 0; Vector3f wind; Vector3f magNED; Vector3f magXYZ; Vector3f gyroScaleFactor; uint8_t magIndex = ahrs.get_NavEKF2().getActiveMag(0); ahrs.get_NavEKF2().getAccelZBias(0,azbias); ahrs.get_NavEKF2().getWind(0,wind); ahrs.get_NavEKF2().getMagNED(0,magNED); ahrs.get_NavEKF2().getMagXYZ(0,magXYZ); ahrs.get_NavEKF2().getGyroScaleErrorPercentage(0,gyroScaleFactor); struct log_NKF2 pkt2 = { LOG_PACKET_HEADER_INIT(LOG_NKF2_MSG), 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) }; WriteBlock(&pkt2, sizeof(pkt2)); // Write third EKF packet Vector3f velInnov; Vector3f posInnov; Vector3f magInnov; float tasInnov = 0; float yawInnov = 0; ahrs.get_NavEKF2().getInnovations(0,velInnov, posInnov, magInnov, tasInnov, yawInnov); struct log_NKF3 pkt3 = { LOG_PACKET_HEADER_INIT(LOG_NKF3_MSG), 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) }; WriteBlock(&pkt3, sizeof(pkt3)); // 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 {}; ahrs.get_NavEKF2().getVariances(0,velVar, posVar, hgtVar, magVar, tasVar, offset); float tempVar = fmaxf(fmaxf(magVar.x,magVar.y),magVar.z); ahrs.get_NavEKF2().getFilterFaults(0,faultStatus); ahrs.get_NavEKF2().getFilterTimeouts(0,timeoutStatus); ahrs.get_NavEKF2().getFilterStatus(0,solutionStatus); ahrs.get_NavEKF2().getFilterGpsStatus(0,gpsStatus); float tiltError; ahrs.get_NavEKF2().getTiltError(0,tiltError); int8_t primaryIndex = ahrs.get_NavEKF2().getPrimaryCoreIndex(); struct log_NKF4 pkt4 = { LOG_PACKET_HEADER_INIT(LOG_NKF4_MSG), 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 }; WriteBlock(&pkt4, sizeof(pkt4)); // 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 ahrs.get_NavEKF2().getFlowDebug(-1,normInnov, gndOffset, flowInnovX, flowInnovY, auxFlowInnov, HAGL, rngInnov, range, gndOffsetErr); ahrs.get_NavEKF2().getOutputTrackingError(-1,predictorErrors); 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 }; WriteBlock(&pkt5, sizeof(pkt5)); // log quaternion Quaternion quat; ahrs.get_NavEKF2().getQuaternion(0, quat); struct log_Quaternion pktq1 = { LOG_PACKET_HEADER_INIT(LOG_NKQ1_MSG), time_us : time_us, q1 : quat.q1, q2 : quat.q2, q3 : quat.q3, q4 : quat.q4 }; WriteBlock(&pktq1, sizeof(pktq1)); // log innovations for the second IMU if enabled if (ahrs.get_NavEKF2().activeCores() >= 2) { // Write 6th EKF packet ahrs.get_NavEKF2().getEulerAngles(1,euler); ahrs.get_NavEKF2().getVelNED(1,velNED); ahrs.get_NavEKF2().getPosNE(1,posNE); ahrs.get_NavEKF2().getPosD(1,posD); ahrs.get_NavEKF2().getGyroBias(1,gyroBias); posDownDeriv = ahrs.get_NavEKF2().getPosDownDerivative(1); if (!ahrs.get_NavEKF2().getOriginLLH(1,originLLH)) { originLLH.alt = 0; } struct log_EKF1 pkt6 = { LOG_PACKET_HEADER_INIT(LOG_NKF6_MSG), 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 }; WriteBlock(&pkt6, sizeof(pkt6)); // Write 7th EKF packet ahrs.get_NavEKF2().getAccelZBias(1,azbias); ahrs.get_NavEKF2().getWind(1,wind); ahrs.get_NavEKF2().getMagNED(1,magNED); ahrs.get_NavEKF2().getMagXYZ(1,magXYZ); ahrs.get_NavEKF2().getGyroScaleErrorPercentage(1,gyroScaleFactor); magIndex = ahrs.get_NavEKF2().getActiveMag(1); struct log_NKF2 pkt7 = { LOG_PACKET_HEADER_INIT(LOG_NKF7_MSG), 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) }; WriteBlock(&pkt7, sizeof(pkt7)); // Write 8th EKF packet ahrs.get_NavEKF2().getInnovations(1,velInnov, posInnov, magInnov, tasInnov, yawInnov); struct log_NKF3 pkt8 = { LOG_PACKET_HEADER_INIT(LOG_NKF8_MSG), 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) }; WriteBlock(&pkt8, sizeof(pkt8)); // Write 9th EKF packet ahrs.get_NavEKF2().getVariances(1,velVar, posVar, hgtVar, magVar, tasVar, offset); tempVar = fmaxf(fmaxf(magVar.x,magVar.y),magVar.z); ahrs.get_NavEKF2().getFilterFaults(1,faultStatus); ahrs.get_NavEKF2().getFilterTimeouts(1,timeoutStatus); ahrs.get_NavEKF2().getFilterStatus(1,solutionStatus); ahrs.get_NavEKF2().getFilterGpsStatus(1,gpsStatus); ahrs.get_NavEKF2().getTiltError(1,tiltError); struct log_NKF4 pkt9 = { LOG_PACKET_HEADER_INIT(LOG_NKF9_MSG), 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 }; WriteBlock(&pkt9, sizeof(pkt9)); ahrs.get_NavEKF2().getQuaternion(1, quat); struct log_Quaternion pktq2 = { LOG_PACKET_HEADER_INIT(LOG_NKQ2_MSG), time_us : time_us, q1 : quat.q1, q2 : quat.q2, q3 : quat.q3, q4 : quat.q4 }; WriteBlock(&pktq2, sizeof(pktq2)); } // write range beacon fusion debug packet if the range value is non-zero if (ahrs.get_beacon() != nullptr) { uint8_t ID; float rng; float innovVar; float innov; float testRatio; Vector3f beaconPosNED; float bcnPosOffsetHigh; float bcnPosOffsetLow; if (ahrs.get_NavEKF2().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 }; WriteBlock(&pkt10, sizeof(pkt10)); } } } // 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= 2) { // Write 6th EKF packet ahrs.get_NavEKF3().getEulerAngles(1,euler); ahrs.get_NavEKF3().getVelNED(1,velNED); ahrs.get_NavEKF3().getPosNE(1,posNE); ahrs.get_NavEKF3().getPosD(1,posD); ahrs.get_NavEKF3().getGyroBias(1,gyroBias); posDownDeriv = ahrs.get_NavEKF3().getPosDownDerivative(1); if (!ahrs.get_NavEKF3().getOriginLLH(1,originLLH)) { originLLH.alt = 0; } struct log_EKF1 pkt6 = { LOG_PACKET_HEADER_INIT(LOG_XKF6_MSG), 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 }; WriteBlock(&pkt6, sizeof(pkt6)); // Write 7th EKF packet ahrs.get_NavEKF3().getAccelBias(1,accelBias); ahrs.get_NavEKF3().getWind(1,wind); ahrs.get_NavEKF3().getMagNED(1,magNED); ahrs.get_NavEKF3().getMagXYZ(1,magXYZ); magIndex = ahrs.get_NavEKF3().getActiveMag(1); struct log_NKF2a pkt7 = { LOG_PACKET_HEADER_INIT(LOG_XKF7_MSG), time_us : time_us, accBiasX : (int16_t)(100*accelBias.x), accBiasY : (int16_t)(100*accelBias.y), accBiasZ : (int16_t)(100*accelBias.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) }; WriteBlock(&pkt7, sizeof(pkt7)); // Write 8th EKF packet ahrs.get_NavEKF3().getInnovations(1,velInnov, posInnov, magInnov, tasInnov, yawInnov); struct log_NKF3 pkt8 = { LOG_PACKET_HEADER_INIT(LOG_XKF8_MSG), 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) }; WriteBlock(&pkt8, sizeof(pkt8)); // Write 9th EKF packet ahrs.get_NavEKF3().getVariances(1,velVar, posVar, hgtVar, magVar, tasVar, offset); tempVar = fmaxf(fmaxf(magVar.x,magVar.y),magVar.z); ahrs.get_NavEKF3().getFilterFaults(1,faultStatus); ahrs.get_NavEKF3().getFilterTimeouts(1,timeoutStatus); ahrs.get_NavEKF3().getFilterStatus(1,solutionStatus); ahrs.get_NavEKF3().getFilterGpsStatus(1,gpsStatus); ahrs.get_NavEKF3().getTiltError(1,tiltError); struct log_NKF4 pkt9 = { LOG_PACKET_HEADER_INIT(LOG_XKF9_MSG), 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 }; WriteBlock(&pkt9, sizeof(pkt9)); // log quaternion ahrs.get_NavEKF3().getQuaternion(1, quat); struct log_Quaternion pktq2 = { LOG_PACKET_HEADER_INIT(LOG_XKQ2_MSG), time_us : time_us, q1 : quat.q1, q2 : quat.q2, q3 : quat.q3, q4 : quat.q4 }; WriteBlock(&pktq2, sizeof(pktq2)); } // write range beacon fusion debug packet if the range value is non-zero uint8_t ID; float rng; float innovVar; float innov; float testRatio; Vector3f beaconPosNED; float bcnPosOffsetHigh; float bcnPosOffsetLow; Vector3f posNED; if (ahrs.get_NavEKF3().getRangeBeaconDebug(-1, ID, rng, innov, innovVar, testRatio, beaconPosNED, bcnPosOffsetHigh, bcnPosOffsetLow, posNED)) { if (rng > 0.0f) { struct log_RngBcnDebug pkt10 = { LOG_PACKET_HEADER_INIT(LOG_XKF10_MSG), time_us : time_us, ID : (uint8_t)ID, rng : (int16_t)(100*rng), innov : (int16_t)(100*innov), sqrtInnovVar : (uint16_t)(100*sqrtf(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 : (int16_t)(100*posNED.x), posE : (int16_t)(100*posNED.y), posD : (int16_t)(100*posNED.z) }; WriteBlock(&pkt10, sizeof(pkt10)); } } // write debug data for body frame odometry fusion Vector3f velBodyInnov,velBodyInnovVar; static uint32_t lastUpdateTime_ms = 0; uint32_t updateTime_ms = ahrs.get_NavEKF3().getBodyFrameOdomDebug(-1, velBodyInnov, velBodyInnovVar); if (updateTime_ms > lastUpdateTime_ms) { struct log_ekfBodyOdomDebug pkt11 = { LOG_PACKET_HEADER_INIT(LOG_XKFD_MSG), time_us : time_us, velInnovX : velBodyInnov.x, velInnovY : velBodyInnov.y, velInnovZ : velBodyInnov.z, velInnovVarX : velBodyInnovVar.x, velInnovVarY : velBodyInnovVar.y, velInnovVarZ : velBodyInnovVar.z }; WriteBlock(&pkt11, sizeof(pkt11)); lastUpdateTime_ms = updateTime_ms; } // log state variances every 0.49s static uint32_t lastEkfStateVarLogTime_ms = 0; if (AP_HAL::millis() - lastEkfStateVarLogTime_ms > 490) { lastEkfStateVarLogTime_ms = AP_HAL::millis(); float stateVar[24]; ahrs.get_NavEKF3().getStateVariances(-1, stateVar); struct log_ekfStateVar pktv1 = { LOG_PACKET_HEADER_INIT(LOG_XKV1_MSG), time_us : time_us, v00 : stateVar[0], v01 : stateVar[1], v02 : stateVar[2], v03 : stateVar[3], v04 : stateVar[4], v05 : stateVar[5], v06 : stateVar[6], v07 : stateVar[7], v08 : stateVar[8], v09 : stateVar[9], v10 : stateVar[10], v11 : stateVar[11] }; WriteBlock(&pktv1, sizeof(pktv1)); struct log_ekfStateVar pktv2 = { LOG_PACKET_HEADER_INIT(LOG_XKV2_MSG), time_us : time_us, v00 : stateVar[12], v01 : stateVar[13], v02 : stateVar[14], v03 : stateVar[15], v04 : stateVar[16], v05 : stateVar[17], v06 : stateVar[18], v07 : stateVar[19], v08 : stateVar[20], v09 : stateVar[21], v10 : stateVar[22], v11 : stateVar[23] }; WriteBlock(&pktv2, sizeof(pktv2)); } // 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= AP_GPS::GPS_OK_FIX_3D) { altitude_gps = gps.location().alt; } else { altitude_gps = 0; } struct log_Camera pkt = { LOG_PACKET_HEADER_INIT(static_cast(msg)), time_us : timestamp_us?timestamp_us:AP_HAL::micros64(), gps_time : gps.time_week_ms(), gps_week : gps.time_week(), latitude : current_loc.lat, longitude : current_loc.lng, altitude : altitude, altitude_rel: altitude_rel, altitude_gps: altitude_gps, roll : (int16_t)ahrs.roll_sensor, pitch : (int16_t)ahrs.pitch_sensor, yaw : (uint16_t)ahrs.yaw_sensor }; WriteCriticalBlock(&pkt, sizeof(pkt)); } // Write a Camera packet void AP_Logger::Write_Camera(const AP_AHRS &ahrs, const Location ¤t_loc, uint64_t timestamp_us) { Write_CameraInfo(LOG_CAMERA_MSG, ahrs, current_loc, timestamp_us); } // Write a Trigger packet void AP_Logger::Write_Trigger(const AP_AHRS &ahrs, const Location ¤t_loc) { Write_CameraInfo(LOG_TRIGGER_MSG, ahrs, current_loc, 0); } // Write an attitude packet void AP_Logger::Write_Attitude(AP_AHRS &ahrs, const Vector3f &targets) { struct log_Attitude pkt = { LOG_PACKET_HEADER_INIT(LOG_ATTITUDE_MSG), time_us : AP_HAL::micros64(), control_roll : (int16_t)targets.x, roll : (int16_t)ahrs.roll_sensor, control_pitch : (int16_t)targets.y, pitch : (int16_t)ahrs.pitch_sensor, control_yaw : (uint16_t)wrap_360_cd(targets.z), yaw : (uint16_t)wrap_360_cd(ahrs.yaw_sensor), error_rp : (uint16_t)(ahrs.get_error_rp() * 100), error_yaw : (uint16_t)(ahrs.get_error_yaw() * 100) }; WriteBlock(&pkt, sizeof(pkt)); } // Write an attitude packet void AP_Logger::Write_AttitudeView(AP_AHRS_View &ahrs, const Vector3f &targets) { struct log_Attitude pkt = { LOG_PACKET_HEADER_INIT(LOG_ATTITUDE_MSG), time_us : AP_HAL::micros64(), control_roll : (int16_t)targets.x, roll : (int16_t)ahrs.roll_sensor, control_pitch : (int16_t)targets.y, pitch : (int16_t)ahrs.pitch_sensor, control_yaw : (uint16_t)wrap_360_cd(targets.z), yaw : (uint16_t)wrap_360_cd(ahrs.yaw_sensor), error_rp : (uint16_t)(ahrs.get_error_rp() * 100), error_yaw : (uint16_t)(ahrs.get_error_yaw() * 100) }; WriteBlock(&pkt, sizeof(pkt)); } void AP_Logger::Write_Current_instance(const uint64_t time_us, const uint8_t battery_instance, const enum LogMessages type, const enum LogMessages celltype) { AP_BattMonitor &battery = AP::battery(); float temp; bool has_temp = battery.get_temperature(temp, battery_instance); struct log_Current pkt = { LOG_PACKET_HEADER_INIT(type), time_us : time_us, voltage : battery.voltage(battery_instance), voltage_resting : battery.voltage_resting_estimate(battery_instance), current_amps : battery.current_amps(battery_instance), current_total : battery.consumed_mah(battery_instance), consumed_wh : battery.consumed_wh(battery_instance), temperature : (int16_t)(has_temp ? (temp * 100) : 0), resistance : battery.get_resistance(battery_instance) }; WriteBlock(&pkt, sizeof(pkt)); // individual cell voltages if (battery.has_cell_voltages(battery_instance)) { const AP_BattMonitor::cells &cells = battery.get_cell_voltages(battery_instance); struct log_Current_Cells cell_pkt = { LOG_PACKET_HEADER_INIT(celltype), time_us : time_us, voltage : battery.voltage(battery_instance) }; for (uint8_t i = 0; i < ARRAY_SIZE(cells.cells); i++) { cell_pkt.cell_voltages[i] = cells.cells[i] + 1; } WriteBlock(&cell_pkt, sizeof(cell_pkt)); // check battery structure can hold all cells static_assert(ARRAY_SIZE(cells.cells) == (sizeof(cell_pkt.cell_voltages) / sizeof(cell_pkt.cell_voltages[0])), "Battery cell number doesn't match in library and log structure"); } } // Write an Current data packet void AP_Logger::Write_Current() { // Big painful assert to ensure that logging won't produce suprising results when the // number of battery monitors changes, does have the built in expectation that // LOG_COMPASS_MSG follows the last LOG_CURRENT_CELLSx_MSG static_assert(((LOG_CURRENT_MSG + AP_BATT_MONITOR_MAX_INSTANCES) == LOG_CURRENT_CELLS_MSG) && ((LOG_CURRENT_CELLS_MSG + AP_BATT_MONITOR_MAX_INSTANCES) == LOG_COMPASS_MSG), "The number of batt monitors has changed without updating the log " "table entries. Please add new enums for LOG_CURRENT_MSG, LOG_CURRENT_CELLS_MSG " "directly following the highest indexed fields. Don't forget to update the log " "description table as well."); const uint64_t time_us = AP_HAL::micros64(); const uint8_t num_instances = AP::battery().num_instances(); for (uint8_t i = 0; i < num_instances; i++) { Write_Current_instance(time_us, i, (LogMessages)((uint8_t)LOG_CURRENT_MSG + i), (LogMessages)((uint8_t)LOG_CURRENT_CELLS_MSG + i)); } } void AP_Logger::Write_Compass_instance(const uint64_t time_us, const uint8_t mag_instance, const enum LogMessages type) { const Compass &compass = AP::compass(); const Vector3f &mag_field = compass.get_field(mag_instance); const Vector3f &mag_offsets = compass.get_offsets(mag_instance); const Vector3f &mag_motor_offsets = compass.get_motor_offsets(mag_instance); struct log_Compass pkt = { LOG_PACKET_HEADER_INIT(type), time_us : time_us, mag_x : (int16_t)mag_field.x, mag_y : (int16_t)mag_field.y, mag_z : (int16_t)mag_field.z, offset_x : (int16_t)mag_offsets.x, offset_y : (int16_t)mag_offsets.y, offset_z : (int16_t)mag_offsets.z, motor_offset_x : (int16_t)mag_motor_offsets.x, motor_offset_y : (int16_t)mag_motor_offsets.y, motor_offset_z : (int16_t)mag_motor_offsets.z, health : (uint8_t)compass.healthy(mag_instance), SUS : compass.last_update_usec(mag_instance) }; WriteBlock(&pkt, sizeof(pkt)); } // Write a Compass packet void AP_Logger::Write_Compass(uint64_t time_us) { if (time_us == 0) { time_us = AP_HAL::micros64(); } const Compass &compass = AP::compass(); if (compass.get_count() > 0) { Write_Compass_instance(time_us, 0, LOG_COMPASS_MSG); } if (compass.get_count() > 1) { Write_Compass_instance(time_us, 1, LOG_COMPASS2_MSG); } if (compass.get_count() > 2) { Write_Compass_instance(time_us, 2, LOG_COMPASS3_MSG); } } // Write a mode packet. bool AP_Logger_Backend::Write_Mode(uint8_t mode, uint8_t reason) { struct log_Mode pkt = { LOG_PACKET_HEADER_INIT(LOG_MODE_MSG), time_us : AP_HAL::micros64(), mode : mode, mode_num : mode, mode_reason : reason }; return WriteCriticalBlock(&pkt, sizeof(pkt)); } // Write ESC status messages // id starts from 0 // rpm is eRPM (rpm * 100) // voltage is in centi-volts // current is in centi-amps // temperature is in centi-degrees Celsius // current_tot is in centi-amp hours void AP_Logger::Write_ESC(uint8_t id, uint64_t time_us, int32_t rpm, uint16_t voltage, uint16_t current, int16_t temperature, uint16_t current_tot) { // sanity check id if (id >= 8) { return; } struct log_Esc pkt = { LOG_PACKET_HEADER_INIT(uint8_t(LOG_ESC1_MSG+id)), time_us : time_us, rpm : rpm, voltage : voltage, current : current, temperature : temperature, current_tot : current_tot }; WriteBlock(&pkt, sizeof(pkt)); } // Write a Yaw PID packet void AP_Logger::Write_PID(uint8_t msg_type, const PID_Info &info) { struct log_PID pkt = { LOG_PACKET_HEADER_INIT(msg_type), time_us : AP_HAL::micros64(), desired : info.desired, actual : info.actual, P : info.P, I : info.I, D : info.D, FF : info.FF }; WriteBlock(&pkt, sizeof(pkt)); } void AP_Logger::Write_Origin(uint8_t origin_type, const Location &loc) { uint64_t time_us = AP_HAL::micros64(); struct log_ORGN pkt = { LOG_PACKET_HEADER_INIT(LOG_ORGN_MSG), time_us : time_us, origin_type : origin_type, latitude : loc.lat, longitude : loc.lng, altitude : loc.alt }; WriteBlock(&pkt, sizeof(pkt)); } void AP_Logger::Write_RPM(const AP_RPM &rpm_sensor) { struct log_RPM pkt = { LOG_PACKET_HEADER_INIT(LOG_RPM_MSG), time_us : AP_HAL::micros64(), rpm1 : rpm_sensor.get_rpm(0), rpm2 : rpm_sensor.get_rpm(1) }; WriteBlock(&pkt, sizeof(pkt)); } // Write a rate packet void AP_Logger::Write_Rate(const AP_AHRS_View *ahrs, const AP_Motors &motors, const AC_AttitudeControl &attitude_control, const AC_PosControl &pos_control) { const Vector3f &rate_targets = attitude_control.rate_bf_targets(); const Vector3f &accel_target = pos_control.get_accel_target(); struct log_Rate pkt_rate = { LOG_PACKET_HEADER_INIT(LOG_RATE_MSG), time_us : AP_HAL::micros64(), control_roll : degrees(rate_targets.x), roll : degrees(ahrs->get_gyro().x), roll_out : motors.get_roll(), control_pitch : degrees(rate_targets.y), pitch : degrees(ahrs->get_gyro().y), pitch_out : motors.get_pitch(), control_yaw : degrees(rate_targets.z), yaw : degrees(ahrs->get_gyro().z), yaw_out : motors.get_yaw(), control_accel : (float)accel_target.z, accel : (float)(-(ahrs->get_accel_ef_blended().z + GRAVITY_MSS) * 100.0f), accel_out : motors.get_throttle() }; WriteBlock(&pkt_rate, sizeof(pkt_rate)); } // Write visual odometry sensor data void AP_Logger::Write_VisualOdom(float time_delta, const Vector3f &angle_delta, const Vector3f &position_delta, float confidence) { struct log_VisualOdom pkt_visualodom = { LOG_PACKET_HEADER_INIT(LOG_VISUALODOM_MSG), time_us : AP_HAL::micros64(), time_delta : time_delta, angle_delta_x : angle_delta.x, angle_delta_y : angle_delta.y, angle_delta_z : angle_delta.z, position_delta_x : position_delta.x, position_delta_y : position_delta.y, position_delta_z : position_delta.z, confidence : confidence }; WriteBlock(&pkt_visualodom, sizeof(log_VisualOdom)); } // Write AOA and SSA void AP_Logger::Write_AOA_SSA(AP_AHRS &ahrs) { struct log_AOA_SSA aoa_ssa = { LOG_PACKET_HEADER_INIT(LOG_AOA_SSA_MSG), time_us : AP_HAL::micros64(), AOA : ahrs.getAOA(), SSA : ahrs.getSSA() }; WriteBlock(&aoa_ssa, sizeof(aoa_ssa)); } // Write beacon sensor (position) data void AP_Logger::Write_Beacon(AP_Beacon &beacon) { if (!beacon.enabled()) { return; } // position Vector3f pos; float accuracy = 0.0f; beacon.get_vehicle_position_ned(pos, accuracy); struct log_Beacon pkt_beacon = { LOG_PACKET_HEADER_INIT(LOG_BEACON_MSG), time_us : AP_HAL::micros64(), health : (uint8_t)beacon.healthy(), count : (uint8_t)beacon.count(), dist0 : beacon.beacon_distance(0), dist1 : beacon.beacon_distance(1), dist2 : beacon.beacon_distance(2), dist3 : beacon.beacon_distance(3), posx : pos.x, posy : pos.y, posz : pos.z }; WriteBlock(&pkt_beacon, sizeof(pkt_beacon)); } // Write proximity sensor distances void AP_Logger::Write_Proximity(AP_Proximity &proximity) { // exit immediately if not enabled if (proximity.get_status() == AP_Proximity::Proximity_NotConnected) { return; } AP_Proximity::Proximity_Distance_Array dist_array {}; proximity.get_horizontal_distances(dist_array); float dist_up; if (!proximity.get_upward_distance(dist_up)) { dist_up = 0.0f; } float close_ang = 0.0f, close_dist = 0.0f; proximity.get_closest_object(close_ang, close_dist); struct log_Proximity pkt_proximity = { LOG_PACKET_HEADER_INIT(LOG_PROXIMITY_MSG), time_us : AP_HAL::micros64(), health : (uint8_t)proximity.get_status(), dist0 : dist_array.distance[0], dist45 : dist_array.distance[1], dist90 : dist_array.distance[2], dist135 : dist_array.distance[3], dist180 : dist_array.distance[4], dist225 : dist_array.distance[5], dist270 : dist_array.distance[6], dist315 : dist_array.distance[7], distup : dist_up, closest_angle : close_ang, closest_dist : close_dist }; WriteBlock(&pkt_proximity, sizeof(pkt_proximity)); } void AP_Logger::Write_SRTL(bool active, uint16_t num_points, uint16_t max_points, uint8_t action, const Vector3f& breadcrumb) { struct log_SRTL pkt_srtl = { LOG_PACKET_HEADER_INIT(LOG_SRTL_MSG), time_us : AP_HAL::micros64(), active : active, num_points : num_points, max_points : max_points, action : action, N : breadcrumb.x, E : breadcrumb.y, D : breadcrumb.z }; WriteBlock(&pkt_srtl, sizeof(pkt_srtl)); }