#pragma once // if you add any new types, units or multipliers, please update README.md /* Format characters in the format string for binary log messages a : int16_t[32] b : int8_t B : uint8_t h : int16_t H : uint16_t i : int32_t I : uint32_t f : float d : double n : char[4] N : char[16] Z : char[64] c : int16_t * 100 C : uint16_t * 100 e : int32_t * 100 E : uint32_t * 100 L : int32_t latitude/longitude M : uint8_t flight mode q : int64_t Q : uint64_t */ struct UnitStructure { const char ID; const char *unit; }; struct MultiplierStructure { const char ID; const double multiplier; }; // all units here should be base units // This does mean battery capacity is here as "amp*second" // Please keep the names consistent with Tools/autotest/param_metadata/param.py:33 const struct UnitStructure log_Units[] = { { '-', "" }, // no units e.g. Pi, or a string { '?', "UNKNOWN" }, // Units which haven't been worked out yet.... { 'A', "A" }, // Ampere { 'd', "deg" }, // of the angular variety, -180 to 180 { 'b', "B" }, // bytes { 'k', "deg/s" }, // degrees per second. Degrees are NOT SI, but is some situations more user-friendly than radians { 'D', "deglatitude" }, // degrees of latitude { 'e', "deg/s/s" }, // degrees per second per second. Degrees are NOT SI, but is some situations more user-friendly than radians { 'E', "rad/s" }, // radians per second { 'G', "Gauss" }, // Gauss is not an SI unit, but 1 tesla = 10000 gauss so a simple replacement is not possible here { 'h', "degheading" }, // 0.? to 359.? { 'i', "A.s" }, // Ampere second { 'J', "W.s" }, // Joule (Watt second) // { 'l', "l" }, // litres { 'L', "rad/s/s" }, // radians per second per second { 'm', "m" }, // metres { 'n', "m/s" }, // metres per second // { 'N', "N" }, // Newton { 'o', "m/s/s" }, // metres per second per second { 'O', "degC" }, // degrees Celsius. Not SI, but Kelvin is too cumbersome for most users { '%', "%" }, // percent { 'S', "satellites" }, // number of satellites { 's', "s" }, // seconds { 'q', "rpm" }, // rounds per minute. Not SI, but sometimes more intuitive than Hertz { 'r', "rad" }, // radians { 'U', "deglongitude" }, // degrees of longitude { 'u', "ppm" }, // pulses per minute { 'v', "V" }, // Volt { 'P', "Pa" }, // Pascal { 'w', "Ohm" }, // Ohm // { 'W', "Watt" }, // Watt { 'Y', "us" }, // pulse width modulation in microseconds { 'z', "Hz" }, // Hertz { '#', "instance" } // (e.g.)Sensor instance number }; // this multiplier information applies to the raw value present in the // log. Any adjustment implied by the format field (e.g. the "centi" // in "centidegrees" is *IGNORED* for the purposes of scaling. // Essentially "format" simply tells you the C-type, and format-type h // (int16_t) is equivalent to format-type c (int16_t*100) // tl;dr a GCS shouldn't/mustn't infer any scaling from the unit name const struct MultiplierStructure log_Multipliers[] = { { '-', 0 }, // no multiplier e.g. a string { '?', 1 }, // multipliers which haven't been worked out yet.... // { '2', 1e2 }, { '1', 1e1 }, { '0', 1e0 }, { 'A', 1e-1 }, { 'B', 1e-2 }, { 'C', 1e-3 }, { 'D', 1e-4 }, { 'E', 1e-5 }, { 'F', 1e-6 }, { 'G', 1e-7 }, // { '!', 3.6 }, // (ampere*second => milliampere*hour) and (km/h => m/s) { '/', 3600 }, // (ampere*second => ampere*hour) }; /* unfortunately these need to be macros because of a limitation of named member structure initialisation in g++ */ #define LOG_PACKET_HEADER uint8_t head1, head2, msgid; #define LOG_PACKET_HEADER_INIT(id) head1 : HEAD_BYTE1, head2 : HEAD_BYTE2, msgid : id #define LOG_PACKET_HEADER_LEN 3 // bytes required for LOG_PACKET_HEADER // once the logging code is all converted we will remove these from // this header #define HEAD_BYTE1 0xA3 // Decimal 163 #define HEAD_BYTE2 0x95 // Decimal 149 // structure used to define logging format struct LogStructure { uint8_t msg_type; uint8_t msg_len; const char *name; const char *format; const char *labels; const char *units; const char *multipliers; }; // maximum lengths of fields in LogStructure, including trailing nulls static const uint8_t LS_NAME_SIZE = 5; static const uint8_t LS_FORMAT_SIZE = 17; static const uint8_t LS_LABELS_SIZE = 65; static const uint8_t LS_UNITS_SIZE = 17; static const uint8_t LS_MULTIPLIERS_SIZE = 17; /* log structures common to all vehicle types */ struct PACKED log_Format { LOG_PACKET_HEADER; uint8_t type; uint8_t length; char name[4]; char format[16]; char labels[64]; }; struct PACKED log_Unit { LOG_PACKET_HEADER; uint64_t time_us; char type; char unit[64]; // you know, this might be overkill... }; struct PACKED log_Format_Multiplier { LOG_PACKET_HEADER; uint64_t time_us; char type; double multiplier; }; struct PACKED log_Format_Units { LOG_PACKET_HEADER; uint64_t time_us; uint8_t format_type; char units[16]; char multipliers[16]; }; struct PACKED log_Parameter { LOG_PACKET_HEADER; uint64_t time_us; char name[16]; float value; }; struct PACKED log_DSF { LOG_PACKET_HEADER; uint64_t time_us; uint32_t dropped; uint16_t blocks; uint32_t bytes; uint32_t buf_space_min; uint32_t buf_space_max; uint32_t buf_space_avg; }; struct PACKED log_Event { LOG_PACKET_HEADER; uint64_t time_us; uint8_t id; }; struct PACKED log_Error { LOG_PACKET_HEADER; uint64_t time_us; uint8_t sub_system; uint8_t error_code; }; struct PACKED log_GPS { LOG_PACKET_HEADER; uint64_t time_us; uint8_t status; uint32_t gps_week_ms; uint16_t gps_week; uint8_t num_sats; uint16_t hdop; int32_t latitude; int32_t longitude; int32_t altitude; float ground_speed; float ground_course; float vel_z; float yaw; uint8_t used; }; struct PACKED log_GPA { LOG_PACKET_HEADER; uint64_t time_us; uint16_t vdop; uint16_t hacc; uint16_t vacc; uint16_t sacc; float yaw_accuracy; uint8_t have_vv; uint32_t sample_ms; uint16_t delta_ms; }; struct PACKED log_Message { LOG_PACKET_HEADER; uint64_t time_us; char msg[64]; }; struct PACKED log_IMU { LOG_PACKET_HEADER; uint64_t time_us; float gyro_x, gyro_y, gyro_z; float accel_x, accel_y, accel_z; uint32_t gyro_error, accel_error; float temperature; uint8_t gyro_health, accel_health; uint16_t gyro_rate, accel_rate; }; struct PACKED log_IMUDT { LOG_PACKET_HEADER; uint64_t time_us; float delta_time, delta_vel_dt, delta_ang_dt; float delta_ang_x, delta_ang_y, delta_ang_z; float delta_vel_x, delta_vel_y, delta_vel_z; }; struct PACKED log_ISBH { LOG_PACKET_HEADER; uint64_t time_us; uint16_t seqno; uint8_t sensor_type; // e.g. GYRO or ACCEL uint8_t instance; uint16_t multiplier; uint16_t sample_count; uint64_t sample_us; float sample_rate_hz; }; static_assert(sizeof(log_ISBH) < 256, "log_ISBH is over-size"); struct PACKED log_ISBD { LOG_PACKET_HEADER; uint64_t time_us; uint16_t isb_seqno; uint16_t seqno; // seqno within isb_seqno int16_t x[32]; int16_t y[32]; int16_t z[32]; }; static_assert(sizeof(log_ISBD) < 256, "log_ISBD is over-size"); struct PACKED log_Vibe { LOG_PACKET_HEADER; uint64_t time_us; float vibe_x, vibe_y, vibe_z; uint32_t clipping_0, clipping_1, clipping_2; }; struct PACKED log_RCIN { LOG_PACKET_HEADER; uint64_t time_us; uint16_t chan1; uint16_t chan2; uint16_t chan3; uint16_t chan4; uint16_t chan5; uint16_t chan6; uint16_t chan7; uint16_t chan8; uint16_t chan9; uint16_t chan10; uint16_t chan11; uint16_t chan12; uint16_t chan13; uint16_t chan14; }; struct PACKED log_RCOUT { LOG_PACKET_HEADER; uint64_t time_us; uint16_t chan1; uint16_t chan2; uint16_t chan3; uint16_t chan4; uint16_t chan5; uint16_t chan6; uint16_t chan7; uint16_t chan8; uint16_t chan9; uint16_t chan10; uint16_t chan11; uint16_t chan12; uint16_t chan13; uint16_t chan14; }; struct PACKED log_MAV { LOG_PACKET_HEADER; uint64_t time_us; uint8_t chan; uint16_t packet_tx_count; uint16_t packet_rx_success_count; uint16_t packet_rx_drop_count; uint8_t flags; uint16_t stream_slowdown_ms; uint16_t times_full; }; struct PACKED log_RSSI { LOG_PACKET_HEADER; uint64_t time_us; float RXRSSI; }; struct PACKED log_BARO { LOG_PACKET_HEADER; uint64_t time_us; float altitude; float pressure; int16_t temperature; float climbrate; uint32_t sample_time_ms; float drift_offset; float ground_temp; uint8_t healthy; }; struct PACKED log_Optflow { LOG_PACKET_HEADER; uint64_t time_us; uint8_t surface_quality; float flow_x; float flow_y; float body_x; float body_y; }; struct PACKED log_AHRS { LOG_PACKET_HEADER; uint64_t time_us; int16_t roll; int16_t pitch; uint16_t yaw; float alt; int32_t lat; int32_t lng; float q1, q2, q3, q4; }; struct PACKED log_POS { LOG_PACKET_HEADER; uint64_t time_us; int32_t lat; int32_t lng; float alt; float rel_home_alt; float rel_origin_alt; }; struct PACKED log_POWR { LOG_PACKET_HEADER; uint64_t time_us; float Vcc; float Vservo; uint16_t flags; uint16_t accumulated_flags; uint8_t safety_and_arm; }; struct PACKED log_EKF1 { LOG_PACKET_HEADER; uint64_t time_us; uint8_t core; int16_t roll; int16_t pitch; uint16_t yaw; float velN; float velE; float velD; float posD_dot; float posN; float posE; float posD; int16_t gyrX; int16_t gyrY; int16_t gyrZ; int32_t originHgt; }; struct PACKED log_EKF2 { LOG_PACKET_HEADER; uint64_t time_us; uint8_t core; int8_t Ratio; int8_t AZ1bias; int8_t AZ2bias; int16_t windN; int16_t windE; int16_t magN; int16_t magE; int16_t magD; int16_t magX; int16_t magY; int16_t magZ; }; struct PACKED log_NKF2 { LOG_PACKET_HEADER; uint64_t time_us; uint8_t core; int8_t AZbias; int16_t scaleX; int16_t scaleY; int16_t scaleZ; int16_t windN; int16_t windE; int16_t magN; int16_t magE; int16_t magD; int16_t magX; int16_t magY; int16_t magZ; uint8_t index; }; struct PACKED log_XKF2 { LOG_PACKET_HEADER; uint64_t time_us; uint8_t core; int16_t accBiasX; int16_t accBiasY; int16_t accBiasZ; int16_t windN; int16_t windE; int16_t magN; int16_t magE; int16_t magD; int16_t magX; int16_t magY; int16_t magZ; uint8_t index; }; struct PACKED log_EKF3 { LOG_PACKET_HEADER; uint64_t time_us; uint8_t core; int16_t innovVN; int16_t innovVE; int16_t innovVD; int16_t innovPN; int16_t innovPE; int16_t innovPD; int16_t innovMX; int16_t innovMY; int16_t innovMZ; int16_t innovVT; }; struct PACKED log_NKF3 { LOG_PACKET_HEADER; uint64_t time_us; uint8_t core; int16_t innovVN; int16_t innovVE; int16_t innovVD; int16_t innovPN; int16_t innovPE; int16_t innovPD; int16_t innovMX; int16_t innovMY; int16_t innovMZ; int16_t innovYaw; int16_t innovVT; }; struct PACKED log_EKF4 { LOG_PACKET_HEADER; uint64_t time_us; uint8_t core; int16_t sqrtvarV; int16_t sqrtvarP; int16_t sqrtvarH; int16_t sqrtvarMX; int16_t sqrtvarMY; int16_t sqrtvarMZ; int16_t sqrtvarVT; int8_t offsetNorth; int8_t offsetEast; uint16_t faults; uint8_t timeouts; uint16_t solution; uint16_t gps; }; struct PACKED log_NKF4 { LOG_PACKET_HEADER; uint64_t time_us; uint8_t core; int16_t sqrtvarV; int16_t sqrtvarP; int16_t sqrtvarH; int16_t sqrtvarM; int16_t sqrtvarVT; float tiltErr; int8_t offsetNorth; int8_t offsetEast; uint16_t faults; uint8_t timeouts; uint32_t solution; uint16_t gps; int8_t primary; }; struct PACKED log_EKF5 { LOG_PACKET_HEADER; uint64_t time_us; uint8_t normInnov; int16_t FIX; int16_t FIY; int16_t AFI; int16_t HAGL; int16_t offset; int16_t RI; uint16_t meaRng; uint16_t errHAGL; }; struct PACKED log_NKF5 { LOG_PACKET_HEADER; uint64_t time_us; uint8_t normInnov; int16_t FIX; int16_t FIY; int16_t AFI; int16_t HAGL; int16_t offset; int16_t RI; uint16_t meaRng; uint16_t errHAGL; float angErr; float velErr; float posErr; }; struct PACKED log_Quaternion { LOG_PACKET_HEADER; uint64_t time_us; uint8_t core; float q1; float q2; float q3; float q4; }; struct PACKED log_RngBcnDebug { LOG_PACKET_HEADER; uint64_t time_us; uint8_t ID; // beacon identifier int16_t rng; // beacon range (cm) int16_t innov; // beacon range innovation (cm) uint16_t sqrtInnovVar; // sqrt of beacon range innovation variance (cm) uint16_t testRatio; // beacon range innovation consistency test ratio *100 int16_t beaconPosN; // beacon north position (cm) int16_t beaconPosE; // beacon east position (cm) int16_t beaconPosD; // beacon down position (cm) int16_t offsetHigh; // high estimate of vertical position offset of beacons rel to EKF origin (cm) int16_t offsetLow; // low estimate of vertical position offset of beacons rel to EKF origin (cm) int16_t posN; // North position of receiver rel to EKF origin (cm) int16_t posE; // East position of receiver rel to EKF origin (cm) int16_t posD; // Down position of receiver rel to EKF origin (cm) }; // visual odometry sensor data struct PACKED log_VisualOdom { LOG_PACKET_HEADER; uint64_t time_us; float time_delta; float angle_delta_x; float angle_delta_y; float angle_delta_z; float position_delta_x; float position_delta_y; float position_delta_z; float confidence; }; // visual position data struct PACKED log_VisualPosition { LOG_PACKET_HEADER; uint64_t time_us; uint64_t remote_time_us; uint32_t time_ms; float pos_x; float pos_y; float pos_z; float roll; // degrees float pitch; // degrees float yaw; // degrees float pos_err; // meters float ang_err; // radians uint8_t reset_counter; }; struct PACKED log_VisualVelocity { LOG_PACKET_HEADER; uint64_t time_us; uint64_t remote_time_us; uint32_t time_ms; float vel_x; float vel_y; float vel_z; float vel_err; uint8_t reset_counter; }; struct PACKED log_ekfBodyOdomDebug { LOG_PACKET_HEADER; uint64_t time_us; float velInnovX; float velInnovY; float velInnovZ; float velInnovVarX; float velInnovVarY; float velInnovVarZ; }; struct PACKED log_ekfStateVar { LOG_PACKET_HEADER; uint64_t time_us; float v00; float v01; float v02; float v03; float v04; float v05; float v06; float v07; float v08; float v09; float v10; float v11; }; struct PACKED log_Cmd { LOG_PACKET_HEADER; uint64_t time_us; uint16_t command_total; uint16_t sequence; uint16_t command; float param1; float param2; float param3; float param4; int32_t latitude; int32_t longitude; float altitude; uint8_t frame; }; struct PACKED log_MAVLink_Command { LOG_PACKET_HEADER; uint64_t time_us; uint8_t target_system; uint8_t target_component; uint8_t frame; uint16_t command; uint8_t current; uint8_t autocontinue; float param1; float param2; float param3; float param4; int32_t x; int32_t y; float z; uint8_t result; bool was_command_long; }; struct PACKED log_Radio { LOG_PACKET_HEADER; uint64_t time_us; uint8_t rssi; uint8_t remrssi; uint8_t txbuf; uint8_t noise; uint8_t remnoise; uint16_t rxerrors; uint16_t fixed; }; struct PACKED log_Camera { LOG_PACKET_HEADER; uint64_t time_us; uint32_t gps_time; uint16_t gps_week; int32_t latitude; int32_t longitude; int32_t altitude; int32_t altitude_rel; int32_t altitude_gps; int16_t roll; int16_t pitch; uint16_t yaw; }; struct PACKED log_Attitude { LOG_PACKET_HEADER; uint64_t time_us; int16_t control_roll; int16_t roll; int16_t control_pitch; int16_t pitch; uint16_t control_yaw; uint16_t yaw; uint16_t error_rp; uint16_t error_yaw; }; struct PACKED log_PID { LOG_PACKET_HEADER; uint64_t time_us; float target; float actual; float error; float P; float I; float D; float FF; float Dmod; }; struct PACKED log_Current { LOG_PACKET_HEADER; uint64_t time_us; uint8_t instance; float voltage; float voltage_resting; float current_amps; float current_total; float consumed_wh; int16_t temperature; // degrees C * 100 float resistance; }; struct PACKED log_WheelEncoder { LOG_PACKET_HEADER; uint64_t time_us; float distance_0; uint8_t quality_0; float distance_1; uint8_t quality_1; }; struct PACKED log_ADSB { LOG_PACKET_HEADER; uint64_t time_us; uint32_t ICAO_address; int32_t lat; int32_t lng; int32_t alt; uint16_t heading; uint16_t hor_velocity; int16_t ver_velocity; uint16_t squawk; }; struct PACKED log_Current_Cells { LOG_PACKET_HEADER; uint64_t time_us; uint8_t instance; float voltage; uint16_t cell_voltages[12]; }; struct PACKED log_Compass { LOG_PACKET_HEADER; uint64_t time_us; int16_t mag_x; int16_t mag_y; int16_t mag_z; int16_t offset_x; int16_t offset_y; int16_t offset_z; int16_t motor_offset_x; int16_t motor_offset_y; int16_t motor_offset_z; uint8_t health; uint32_t SUS; }; struct PACKED log_Mode { LOG_PACKET_HEADER; uint64_t time_us; uint8_t mode; uint8_t mode_num; uint8_t mode_reason; }; /* rangefinder - support for 4 sensors */ struct PACKED log_RFND { LOG_PACKET_HEADER; uint64_t time_us; uint8_t instance; uint16_t dist; uint8_t status; uint8_t orient; }; /* terrain log structure */ struct PACKED log_TERRAIN { LOG_PACKET_HEADER; uint64_t time_us; uint8_t status; int32_t lat; int32_t lng; uint16_t spacing; float terrain_height; float current_height; uint16_t pending; uint16_t loaded; }; /* UBlox logging */ struct PACKED log_Ubx1 { LOG_PACKET_HEADER; uint64_t time_us; uint8_t instance; uint16_t noisePerMS; uint8_t jamInd; uint8_t aPower; uint16_t agcCnt; uint32_t config; }; struct PACKED log_Ubx2 { LOG_PACKET_HEADER; uint64_t time_us; uint8_t instance; int8_t ofsI; uint8_t magI; int8_t ofsQ; uint8_t magQ; }; struct PACKED log_GPS_RAW { LOG_PACKET_HEADER; uint64_t time_us; int32_t iTOW; int16_t week; uint8_t numSV; uint8_t sv; double cpMes; double prMes; float doMes; int8_t mesQI; int8_t cno; uint8_t lli; }; struct PACKED log_GPS_RAWH { LOG_PACKET_HEADER; uint64_t time_us; double rcvTow; uint16_t week; int8_t leapS; uint8_t numMeas; uint8_t recStat; }; struct PACKED log_GPS_RAWS { LOG_PACKET_HEADER; uint64_t time_us; double prMes; double cpMes; float doMes; uint8_t gnssId; uint8_t svId; uint8_t freqId; uint16_t locktime; uint8_t cno; uint8_t prStdev; uint8_t cpStdev; uint8_t doStdev; uint8_t trkStat; }; struct PACKED log_Esc { LOG_PACKET_HEADER; uint64_t time_us; uint8_t instance; int32_t rpm; uint16_t voltage; uint16_t current; int16_t esc_temp; uint16_t current_tot; int16_t motor_temp; }; struct PACKED log_CSRV { LOG_PACKET_HEADER; uint64_t time_us; uint8_t id; float position; float force; float speed; uint8_t power_pct; }; struct PACKED log_CESC { LOG_PACKET_HEADER; uint64_t time_us; uint8_t id; uint32_t error_count; float voltage; float current; float temperature; int32_t rpm; uint8_t power_pct; }; struct PACKED log_AIRSPEED { LOG_PACKET_HEADER; uint64_t time_us; float airspeed; float diffpressure; int16_t temperature; float rawpressure; float offset; bool use; bool healthy; float health_prob; uint8_t primary; }; struct PACKED log_ACCEL { LOG_PACKET_HEADER; uint64_t time_us; uint64_t sample_us; float AccX, AccY, AccZ; }; struct PACKED log_GYRO { LOG_PACKET_HEADER; uint64_t time_us; uint64_t sample_us; float GyrX, GyrY, GyrZ; }; struct PACKED log_MAV_Stats { LOG_PACKET_HEADER; uint64_t timestamp; uint32_t seqno; uint32_t dropped; uint32_t retries; uint32_t resends; uint8_t state_free_avg; uint8_t state_free_min; uint8_t state_free_max; uint8_t state_pending_avg; uint8_t state_pending_min; uint8_t state_pending_max; uint8_t state_sent_avg; uint8_t state_sent_min; uint8_t state_sent_max; // uint8_t state_retry_avg; // uint8_t state_retry_min; // uint8_t state_retry_max; }; struct PACKED log_ORGN { LOG_PACKET_HEADER; uint64_t time_us; uint8_t origin_type; int32_t latitude; int32_t longitude; int32_t altitude; }; struct PACKED log_RPM { LOG_PACKET_HEADER; uint64_t time_us; float rpm1; float rpm2; }; struct PACKED log_Rate { LOG_PACKET_HEADER; uint64_t time_us; float control_roll; float roll; float roll_out; float control_pitch; float pitch; float pitch_out; float control_yaw; float yaw; float yaw_out; float control_accel; float accel; float accel_out; }; struct PACKED log_SbpLLH { LOG_PACKET_HEADER; uint64_t time_us; uint32_t tow; int32_t lat; int32_t lon; int32_t alt; uint8_t n_sats; uint8_t flags; }; struct PACKED log_SbpHealth { LOG_PACKET_HEADER; uint64_t time_us; uint32_t crc_error_counter; uint32_t last_injected_data_ms; uint32_t last_iar_num_hypotheses; }; struct PACKED log_SbpRAWH { LOG_PACKET_HEADER; uint64_t time_us; uint16_t msg_type; uint16_t sender_id; uint8_t index; uint8_t pages; uint8_t msg_len; uint8_t res; uint8_t data[48]; }; struct PACKED log_SbpRAWM { LOG_PACKET_HEADER; uint64_t time_us; uint16_t msg_type; uint16_t sender_id; uint8_t index; uint8_t pages; uint8_t msg_len; uint8_t res; uint8_t data[104]; }; struct PACKED log_SbpEvent { LOG_PACKET_HEADER; uint64_t time_us; uint16_t wn; uint32_t tow; int32_t ns_residual; uint8_t level; uint8_t quality; }; struct PACKED log_Rally { LOG_PACKET_HEADER; uint64_t time_us; uint8_t total; uint8_t sequence; int32_t latitude; int32_t longitude; int16_t altitude; }; struct PACKED log_AOA_SSA { LOG_PACKET_HEADER; uint64_t time_us; float AOA; float SSA; }; struct PACKED log_Beacon { LOG_PACKET_HEADER; uint64_t time_us; uint8_t health; uint8_t count; float dist0; float dist1; float dist2; float dist3; float posx; float posy; float posz; }; // proximity sensor logging struct PACKED log_Proximity { LOG_PACKET_HEADER; uint64_t time_us; uint8_t health; float dist0; float dist45; float dist90; float dist135; float dist180; float dist225; float dist270; float dist315; float distup; float closest_angle; float closest_dist; }; struct PACKED log_Performance { LOG_PACKET_HEADER; uint64_t time_us; uint16_t num_long_running; uint16_t num_loops; uint32_t max_time; uint32_t mem_avail; uint16_t load; uint32_t internal_errors; uint32_t internal_error_count; uint32_t spi_count; uint32_t i2c_count; uint32_t i2c_isr_count; uint32_t extra_loop_us; }; struct PACKED log_SRTL { LOG_PACKET_HEADER; uint64_t time_us; uint8_t active; uint16_t num_points; uint16_t max_points; uint8_t action; float N; float E; float D; }; struct PACKED log_OABendyRuler { LOG_PACKET_HEADER; uint64_t time_us; uint8_t active; uint16_t target_yaw; uint16_t yaw; bool resist_chg; float margin; int32_t final_lat; int32_t final_lng; int32_t oa_lat; int32_t oa_lng; }; struct PACKED log_OADijkstra { LOG_PACKET_HEADER; uint64_t time_us; uint8_t state; uint8_t error_id; uint8_t curr_point; uint8_t tot_points; int32_t final_lat; int32_t final_lng; int32_t oa_lat; int32_t oa_lng; }; struct PACKED log_SimpleAvoid { LOG_PACKET_HEADER; uint64_t time_us; uint8_t state; float desired_vel_x; float desired_vel_y; float modified_vel_x; float modified_vel_y; uint8_t backing_up; }; struct PACKED log_DSTL { LOG_PACKET_HEADER; uint64_t time_us; uint8_t stage; float target_heading; int32_t target_lat; int32_t target_lng; int32_t target_alt; int16_t crosstrack_error; int16_t travel_distance; float l1_i; int32_t loiter_sum_cd; float desired; float P; float I; float D; }; struct PACKED log_Arm_Disarm { LOG_PACKET_HEADER; uint64_t time_us; uint8_t arm_state; uint32_t arm_checks; uint8_t forced; uint8_t method; }; struct PACKED log_Winch { LOG_PACKET_HEADER; uint64_t time_us; uint8_t healthy; uint8_t thread_end; uint8_t moving; uint8_t clutch; uint8_t mode; float desired_length; float length; float desired_rate; uint16_t tension; float voltage; int8_t temp; }; // FMT messages define all message formats other than FMT // UNIT messages define units which can be referenced by FMTU messages // FMTU messages associate types (e.g. centimeters/second/second) to FMT message fields #define ACC_LABELS "TimeUS,SampleUS,AccX,AccY,AccZ" #define ACC_FMT "QQfff" #define ACC_UNITS "ssnnn" #define ACC_MULTS "FF000" // see "struct sensor" in AP_Baro.h and "Write_Baro": #define BARO_LABELS "TimeUS,Alt,Press,Temp,CRt,SMS,Offset,GndTemp,Health" #define BARO_FMT "QffcfIffB" #define BARO_UNITS "smPOnsmO-" #define BARO_MULTS "F00B0C?0-" #define GPA_LABELS "TimeUS,VDop,HAcc,VAcc,SAcc,YAcc,VV,SMS,Delta" #define GPA_FMT "QCCCCfBIH" #define GPA_UNITS "smmmnd-ss" #define GPA_MULTS "FBBBB0-CC" // see "struct GPS_State" and "Write_GPS": #define GPS_LABELS "TimeUS,Status,GMS,GWk,NSats,HDop,Lat,Lng,Alt,Spd,GCrs,VZ,Yaw,U" #define GPS_FMT "QBIHBcLLeffffB" #define GPS_UNITS "s---SmDUmnhnh-" #define GPS_MULTS "F---0BGGB000--" #define GYR_LABELS "TimeUS,SampleUS,GyrX,GyrY,GyrZ" #define GYR_FMT "QQfff" #define GYR_UNITS "ssEEE" #define GYR_MULTS "FF000" #define IMT_LABELS "TimeUS,DelT,DelvT,DelaT,DelAX,DelAY,DelAZ,DelVX,DelVY,DelVZ" #define IMT_FMT "Qfffffffff" #define IMT_UNITS "ssssrrrnnn" #define IMT_MULTS "FF00000000" #define ISBH_LABELS "TimeUS,N,type,instance,mul,smp_cnt,SampleUS,smp_rate" #define ISBH_FMT "QHBBHHQf" #define ISBH_UNITS "s-----sz" #define ISBH_MULTS "F-----F-" #define ISBD_LABELS "TimeUS,N,seqno,x,y,z" #define ISBD_FMT "QHHaaa" #define ISBD_UNITS "s--ooo" #define ISBD_MULTS "F--???" #define IMU_LABELS "TimeUS,GyrX,GyrY,GyrZ,AccX,AccY,AccZ,EG,EA,T,GH,AH,GHz,AHz" #define IMU_FMT "QffffffIIfBBHH" #define IMU_UNITS "sEEEooo--O--zz" #define IMU_MULTS "F000000-----00" #define MAG_LABELS "TimeUS,MagX,MagY,MagZ,OfsX,OfsY,OfsZ,MOfsX,MOfsY,MOfsZ,Health,S" #define MAG_FMT "QhhhhhhhhhBI" #define MAG_UNITS "sGGGGGGGGG-s" #define MAG_MULTS "FCCCCCCCCC-F" #define PID_LABELS "TimeUS,Tar,Act,Err,P,I,D,FF,Dmod" #define PID_FMT "Qffffffff" #define PID_UNITS "s--------" #define PID_MULTS "F--------" #define QUAT_LABELS "TimeUS,C,Q1,Q2,Q3,Q4" #define QUAT_FMT "QBffff" #define QUAT_UNITS "s#????" #define QUAT_MULTS "F-????" #define ARSP_LABELS "TimeUS,Airspeed,DiffPress,Temp,RawPress,Offset,U,Health,Hfp,Pri" #define ARSP_FMT "QffcffBBfB" #define ARSP_UNITS "snPOPP----" #define ARSP_MULTS "F00B00----" // @LoggerMessage: ACC1,ACC2,ACC3 // @Description: IMU accelerometer data // @Field: TimeUS: Time since system startup // @Field: SampleUS: time since system startup this sample was taken // @Field: AccX: acceleration along X axis // @Field: AccY: acceleration along Y axis // @Field: AccZ: acceleration along Z axis // @LoggerMessage: ADSB // @Description: Automatic Dependant Serveillance - Broadcast detected vehicle information // @Field: TimeUS: Time since system startup // @Field: ICAO_address: Transponder address // @Field: Lat: Vehicle latitude // @Field: Lng: Vehicle longitude // @Field: Alt: Vehicle altitude // @Field: Heading: Vehicle heading // @Field: Hor_vel: Vehicle horizontal velocity // @Field: Ver_vel: Vehicle vertical velocity // @Field: Squark: Transponder squawk code // @LoggerMessage: AHR2 // @Description: Backup AHRS data // @Field: TimeUS: Time since system startup // @Field: Roll: Estimated roll // @Field: Pitch: Estimated pitch // @Field: Yaw: Estimated yaw // @Field: Alt: Estimated altitude // @Field: Lat: Estimated latitude // @Field: Lng: Estimated longitude // @Field: Q1: Estimated attitude quaternion component 1 // @Field: Q2: Estimated attitude quaternion component 2 // @Field: Q3: Estimated attitude quaternion component 3 // @Field: Q4: Estimated attitude quaternion component 4 // @LoggerMessage: ARM // @Description: Arming status changes // @Field: TimeUS: Time since system startup // @Field: ArmState: true if vehicle is now armed // @Field: ArmChecks: arming bitmask at time of arming // @Field: Forced: true if arm/disarm was forced // @Field: Method: method used for arming // @LoggerMessage: ARSP,ASP2 // @Description: Airspeed sensor data // @Field: TimeUS: Time since system startup // @Field: Airspeed: Current airspeed // @Field: DiffPress: Pressure difference between static and dynamic port // @Field: Temp: Temperature used for calculation // @Field: RawPress: Raw pressure less offset // @Field: Offset: Offset from parameter // @Field: U: True if sensor is being used // @Field: Health: True if sensor is healthy // @Field: Hfp: Probability sensor has failed // @Field: Pri: True if sensor is the primary sensor // @LoggerMessage: ATT // @Description: Canonical vehicle attitude // @Field: TimeUS: Time since system startup // @Field: DesRoll: vehicle desired roll // @Field: Roll: achieved vehicle roll // @Field: DesPitch: vehicle desired pitch // @Field: Pitch: achieved vehicle pitch // @Field: DesYaw: vehicle desired yaw // @Field: Yaw: achieved vehicle yaw // @Field: ErrRP: lowest estimated gyro drift error // @Field: ErrYaw: difference between measured yaw and DCM yaw estimate // @LoggerMessage: BARO,BAR2,BAR3 // @Description: Gathered Barometer data // @Field: TimeUS: Time since system startup // @Field: Alt: calculated altitude // @Field: Press: measured atmospheric pressure // @Field: Temp: measured atmospheric temperature // @Field: CRt: derived climb rate from primary barometer // @Field: SMS: time last sample was taken // @Field: Offset: raw adjustment of barometer altitude, zeroed on calibration, possibly set by GCS // @Field: GndTemp: temperature on ground, specified by parameter or measured while on ground // @Field: Health: true if barometer is considered healthy // @LoggerMessage: BAT // @Description: Gathered battery data // @Field: TimeUS: Time since system startup // @Field: Instance: battery instance number // @Field: Volt: measured voltage // @Field: VoltR: estimated resting voltage // @Field: Curr: measured current // @Field: CurrTot: current * time // @Field: EnrgTot: energy this battery has produced // @Field: Temp: measured temperature // @Field: Res: estimated temperature resistance // @LoggerMessage: BCL // @Description: Battery cell voltage information // @Field: TimeUS: Time since system startup // @Field: Instance: battery instance number // @Field: Volt: battery voltage // @Field: V1: first cell voltage // @Field: V2: second cell voltage // @Field: V3: third cell voltage // @Field: V4: fourth cell voltage // @Field: V5: fifth cell voltage // @Field: V6: sixth cell voltage // @Field: V7: seventh cell voltage // @Field: V8: eighth cell voltage // @Field: V9: ninth cell voltage // @Field: V10: tenth cell voltage // @Field: V11: eleventh cell voltage // @Field: V12: twelfth cell voltage // @LoggerMessage: BCN // @Description: Beacon informtaion // @Field: TimeUS: Time since system startup // @Field: Health: True if beacon sensor is healthy // @Field: Cnt: Number of beacons being used // @Field: D0: Distance to first beacon // @Field: D1: Distance to second beacon // @Field: D2: Distance to third beacon // @Field: D3: Distance to fouth beacon // @Field: PosX: Calculated beacon position, x-axis // @Field: PosY: Calculated beacon position, y-axis // @Field: PosZ: Calculated beacon position, z-axis // @LoggerMessage: CAM,TRIG // @Description: Camera shutter information // @Field: TimeUS: Time since system startup // @Field: GPSTime: milliseconds since start of GPS week // @Field: GPSWeek: weeks since 5 Jan 1980 // @Field: Lat: current latitude // @Field: Lng: current longitude // @Field: Alt: current altitude // @Field: RelAlt: current altitude relative to home // @Field: GPSAlt: altitude as reported by GPS // @Field: Roll: current vehicle roll // @Field: Pitch: current vehicle pitch // @Field: Yaw: current vehicle yaw // @LoggerMessage: CESC // @Description: CAN ESC data // @Field: TimeUS: Time since system startup // @Field: Id: ESC identifier // @Field: ECnt: Error count // @Field: Voltage: Battery voltage measurement // @Field: Curr: Battery current measurement // @Field: Temp: Temperature // @Field: RPM: Measured RPM // @Field: Pow: Rated power output // @LoggerMessage: CMD // @Description: Executed mission command information // @Field: TimeUS: Time since system startup // @Field: CTot: Total number of mission commands // @Field: CNum: This command's offset in mission // @Field: CId: Command type // @Field: Prm1: Parameter 1 // @Field: Prm2: Parameter 2 // @Field: Prm3: Parameter 3 // @Field: Prm4: Parameter 4 // @Field: Lat: Command latitude // @Field: Lng: Command longitude // @Field: Alt: Command altitude // @Field: Frame: Frame used for position // @LoggerMessage: CSRV // @Description: Servo feedback data // @Field: TimeUS: Time since system startup // @Field: Id: Servo number this data relates to // @Field: Pos: Current servo position // @Field: Force: Force being applied // @Field: Speed: Current servo movement speed // @Field: Pow: Amount of rated power being applied // @LoggerMessage: DMS // @Description: DataFlash-Over-MAVLink statistics // @Field: TimeUS: Time since system startup // @Field: N: Current block number // @Field: Dp: Number of times we rejected a write to the backend // @Field: RT: Number of blocks sent from the retry queue // @Field: RS: Number of resends of unacknowledged data made // @Field: Fa: Average number of blocks on the free list // @Field: Fmn: Minimum number of blocks on the free list // @Field: Fmx: Maximum number of blocks on the free list // @Field: Pa: Average number of blocks on the pending list // @Field: Pmn: Minimum number of blocks on the pending list // @Field: Pmx: Maximum number of blocks on the pending list // @Field: Sa: Average number of blocks on the sent list // @Field: Smn: Minimum number of blocks on the sent list // @Field: Smx: Maximum number of blocks on the sent list // @LoggerMessage: DSF // @Description: Onboard logging statistics // @Field: TimeUS: Time since system startup // @Field: Dp: Number of times we rejected a write to the backend // @Field: Blk: Current block number // @Field: Bytes: Current write offset // @Field: FMn: Minimum free space in write buffer in last time period // @Field: FMx: Maximum free space in write buffer in last time period // @Field: FAv: Average free space in write buffer in last time period // @LoggerMessage: DSTL // @Description: Deepstall Landing data // @Field: TimeUS: Time since system startup // @Field: Stg: Deepstall landing stage // @Field: THdg: Target heading // @Field: Lat: Landing point latitude // @Field: Lng: Landing point longitude // @Field: Alt: Landing point altitude // @Field: XT: Crosstrack error // @Field: Travel: Expected travel distance vehicle will travel from this point // @Field: L1I: L1 controller crosstrack integrator value // @Field: Loiter: wind estimate loiter angle flown // @Field: Des: Deepstall steering PID desired value // @Field: P: Deepstall steering PID Proportional response component // @Field: I: Deepstall steering PID Integral response component // @Field: D: Deepstall steering PID Derivative response component // @LoggerMessage: ERR // @Description: Specifically coded error messages // @Field: TimeUS: Time since system startup // @Field: Subsys: Subsystem in which the error occurred // @Field: ECode: Subsystem-specific error code // @LoggerMessage: ESC // @Description: Feedback received from ESCs // @Field: TimeUS: microseconds since system startup // @Field: Instance: ESC instance number // @Field: RPM: reported motor rotation rate // @Field: Volt: Perceived input voltage for the ESC // @Field: Curr: Perceived current through the ESC // @Field: Temp: ESC temperature // @Field: CTot: current consumed total // @Field: MotTemp: measured motor temperature // @LoggerMessage: EV // @Description: Specifically coded event messages // @Field: TimeUS: Time since system startup // @Field: Id: Event identifier // @LoggerMessage: FMT // @Description: Message defining the format of messages in this file // @URL: https://ardupilot.org/dev/docs/code-overview-adding-a-new-log-message.html // @Field: Type: unique-to-this-log identifier for message being defined // @Field: Length: the number of bytes taken up by this message (including all headers) // @Field: Name: name of the message being defined // @Field: Format: character string defining the C-storage-type of the fields in this message // @Field: Columns: the labels of the message being defined // @LoggerMessage: FMTU // @Description: Message defining units and multipliers used for fields of other messages // @Field: TimeUS: Time since system startup // @Field: FmtType: numeric reference to associated FMT message // @Field: UnitIds: each character refers to a UNIT message. The unit at an offset corresponds to the field at the same offset in FMT.Format // @Field: MultIds: each character refers to a MULT message. The multiplier at an offset corresponds to the field at the same offset in FMT.Format // @LoggerMessage: GPA,GPA2 // @Description: GPS accuracy information // @Field: TimeUS: Time since system startup // @Field: VDop: vertical degree of procession // @Field: HAcc: horizontal position accuracy // @Field: VAcc: vertical position accuracy // @Field: SAcc: speed accuracy // @Field: YAcc: yaw accuracy // @Field: VV: true if vertical velocity is available // @Field: SMS: time since system startup this sample was taken // @Field: Delta: system time delta between the last two reported positions //note: GPAB is a copy of GPA and GPA2! // @LoggerMessage: GPAB // @Description: Blended GPS accuracy information // @Field: TimeUS: Time since system startup // @Field: VDop: vertical degree of procession // @Field: HAcc: horizontal position accuracy // @Field: VAcc: vertical position accuracy // @Field: SAcc: speed accuracy // @Field: YAcc: yaw accuracy // @Field: VV: true if vertical velocity is available // @Field: SMS: time since system startup this sample was taken // @Field: Delta: system time delta between the last two reported positions // @LoggerMessage: GPS,GPS2 // @Description: Information received from GNSS systems attached to the autopilot // @Field: TimeUS: Time since system startup // @Field: Status: GPS Fix type; 2D fix, 3D fix etc. // @Field: GMS: milliseconds since start of GPS Week // @Field: GWk: weeks since 5 Jan 1980 // @Field: NSats: number of satellites visible // @Field: HDop: horizontal precision // @Field: Lat: latitude // @Field: Lng: longitude // @Field: Alt: altitude // @Field: Spd: ground speed // @Field: GCrs: ground course // @Field: VZ: vertical speed // @Field: Yaw: vehicle yaw // @Field: U: boolean value indicating whether this GPS is in use // Note: GPSB is a copy of GPS! // @LoggerMessage: GPSB // @Description: Information blended from GNSS systems attached to the autopilot // @Field: TimeUS: Time since system startup // @Field: Status: GPS Fix type; 2D fix, 3D fix etc. // @Field: GMS: milliseconds since start of GPS Week // @Field: GWk: weeks since 5 Jan 1980 // @Field: NSats: number of satellites visible // @Field: HDop: horizontal precision // @Field: Lat: latitude // @Field: Lng: longitude // @Field: Alt: altitude // @Field: Spd: ground speed // @Field: GCrs: ground course // @Field: VZ: vertical speed // @Field: Yaw: vehicle yaw // @Field: U: boolean value indicating whether this GPS is in use // @LoggerMessage: GRAW // @Description: Raw uBlox data // @Field: TimeUS: Time since system startup // @Field: WkMS: receiver TimeOfWeek measurement // @Field: Week: GPS week // @Field: numSV: number of space vehicles seen // @Field: sv: space vehicle number of first vehicle // @Field: cpMes: carrier phase measurement // @Field: prMes: pseudorange measurement // @Field: doMes: Doppler measurement // @Field: mesQI: measurement quality index // @Field: cno: carrier-to-noise density ratio // @Field: lli: loss of lock indicator // @LoggerMessage: GRXH // @Description: Raw uBlox data - header // @Field: TimeUS: Time since system startup // @Field: rcvTime: receiver TimeOfWeek measurement // @Field: week: GPS week // @Field: leapS: GPS leap seconds // @Field: numMeas: number of space-vehicle measurements to follow // @Field: recStat: receiver tracking status bitfield // @LoggerMessage: GRXS // @Description: Raw uBlox data - space-vehicle data // @Field: TimeUS: Time since system startup // @Field: prMes: Pseudorange measurement // @Field: cpMes: Carrier phase measurement // @Field: doMes: Doppler measurement // @Field: gnss: GNSS identifier // @Field: sv: Satellite identifier // @Field: freq: GLONASS frequency slot // @Field: lock: carrier phase locktime counter // @Field: cno: carrier-to-noise density ratio // @Field: prD: estimated pseudorange measurement standard deviation // @Field: cpD: estimated carrier phase measurement standard deviation // @Field: doD: estimated Doppler measurement standard deviation // @Field: trk: tracking status bitfield // @LoggerMessage: GYR1,GYR2,GYR3 // @Description: IMU gyroscope data // @Field: TimeUS: Time since system startup // @Field: SampleUS: time since system startup this sample was taken // @Field: GyrX: measured rotation rate about X axis // @Field: GyrY: measured rotation rate about Y axis // @Field: GyrZ: measured rotation rate about Z axis // @LoggerMessage: IMT,IMT2,IMT3 // @Description: Inertial Measurement Unit timing data // @Field: TimeUS: Time since system startup // @Field: DelT: Delta time // @Field: DelvT: Delta velocity accumulation time // @Field: DelaT: Delta angle accumulation time // @Field: DelAX: Accumulated delta angle X // @Field: DelAY: Accumulated delta angle Y // @Field: DelAZ: Accumulated delta angle Z // @Field: DelVX: Accumulated delta velocity X // @Field: DelVY: Accumulated delta velocity Y // @Field: DelVZ: Accumulated delta velocity Z // @LoggerMessage: IMU,IMU2,IMU3 // @Description: Inertial Measurement Unit data // @Field: TimeUS: Time since system startup // @Field: GyrX: measured rotation rate about X axis // @Field: GyrY: measured rotation rate about Y axis // @Field: GyrZ: measured rotation rate about Z axis // @Field: AccX: acceleration along X axis // @Field: AccY: acceleration along Y axis // @Field: AccZ: acceleration along Z axis // @Field: EG: gyroscope error count // @Field: EA: accelerometer error count // @Field: T: IMU temperature // @Field: GH: gyroscope health // @Field: AH: accelerometer health // @Field: GHz: gyroscope measurement rate // @Field: AHz: accelerometer measurement rate // @LoggerMessage: LGR // @Description: Landing gear information // @Field: TimeUS: Time since system startup // @Field: LandingGear: Current landing gear state // @Field: WeightOnWheels: True if there is weight on wheels // @LoggerMessage: MAG,MAG2,MAG3 // @Description: Information received from compasses // @Field: TimeUS: Time since system startup // @Field: MagX: magnetic field strength in body frame // @Field: MagY: magnetic field strength in body frame // @Field: MagZ: magnetic field strength in body frame // @Field: OfsX: magnetic field offset in body frame // @Field: OfsY: magnetic field offset in body frame // @Field: OfsZ: magnetic field offset in body frame // @Field: MOfsX: motor interference magnetic field offset in body frame // @Field: MOfsY: motor interference magnetic field offset in body frame // @Field: MOfsZ: motor interference magnetic field offset in body frame // @Field: Health: true if the compass is considered healthy // @Field: S: time measurement was taken // @LoggerMessage: MAV // @Description: GCS MAVLink link statistics // @Field: TimeUS: Time since system startup // @Field: chan: mavlink channel number // @Field: txp: transmitted packet count // @Field: rxp: received packet count // @Field: rxdp: perceived number of packets we never received // @Field: flags: compact representation of some stage of the channel // @Field: ss: stream slowdown is the number of ms being added to each message to fit within bandwidth // @Field: tf: times buffer was full when a message was going to be sent // @LoggerMessage: MAVC // @Description: MAVLink command we have just executed // @Field: TimeUS: Time since system startup // @Field: TS: target system for command // @Field: TC: target component for command // @Field: Fr: command frame // @Field: Cmd: mavlink command enum value // @Field: Cur: current flag from mavlink packet // @Field: AC: autocontinue flag from mavlink packet // @Field: P1: first parameter from mavlink packet // @Field: P2: second parameter from mavlink packet // @Field: P3: third parameter from mavlink packet // @Field: P4: fourth parameter from mavlink packet // @Field: X: X coordinate from mavlink packet // @Field: Y: Y coordinate from mavlink packet // @Field: Z: Z coordinate from mavlink packet // @Field: Res: command result being returned from autopilot // @Field: WL: true if this command arrived via a COMMAND_LONG rather than COMMAND_INT // @LoggerMessage: MODE // @Description: vehicle control mode information // @Field: TimeUS: Time since system startup // @Field: Mode: vehicle-specific mode number // @Field: ModeNum: alias for Mode // @Field: Rsn: reason for entering this mode; enumeration value // @LoggerMessage: MON // @Description: Main loop stuck data // @Field: TimeUS: Time since system startup // @Field: LDelay: Time main loop has been stuck for // @Field: Task: Current scheduler task number // @Field: IErr: Internal error mask; which internal errors have been detected // @Field: IErrCnt: Internal error count; how many internal errors have been detected // @Field: IErrLn: Line on which internal error ocurred // @Field: MavMsg: Id of the last mavlink message processed // @Field: MavCmd: Id of the last mavlink command processed // @Field: SemLine: Line number of semaphore most recently taken // @Field: SPICnt: Number of SPI transactions processed // @Field: I2CCnt: Number of i2c transactions processed // @LoggerMessage: MSG // @Description: Textual messages // @Field: TimeUS: Time since system startup // @Field: Message: message text // @LoggerMessage: MULT // @Description: Message mapping from single character to numeric multiplier // @Field: TimeUS: Time since system startup // @Field: Id: character referenced by FMTU // @Field: Mult: numeric multiplier // @LoggerMessage: NKF0 // @Description: EKF2 beacon sensor diagnostics // @Field: TimeUS: Time since system startup // @Field: ID: Beacon sensor ID // @Field: rng: Beacon range // @Field: innov: Beacon range innovation // @Field: SIV: sqrt of beacon range innovation variance // @Field: TR: Beacon range innovation consistency test ratio // @Field: BPN: Beacon north position // @Field: BPE: Beacon east position // @Field: BPD: Beacon down position // @Field: OFH: High estimate of vertical position offset of beacons rel to EKF origin // @Field: OFL: Low estimate of vertical position offset of beacons rel to EKF origin // @Field: OFN: always zero // @Field: OFE: always zero // @Field: OFD: always zero // @LoggerMessage: NKF1 // @Description: EKF2 estimator outputs // @Field: TimeUS: Time since system startup // @Field: C: EKF2 core this data is for // @Field: Roll: Estimated roll // @Field: Pitch: Estimated pitch // @Field: Yaw: Estimated yaw // @Field: VN: Estimated velocity (North component) // @Field: VE: Estimated velocity (East component) // @Field: VD: Estimated velocity (Down component) // @Field: dPD: Filtered derivative of vertical position (down) // @Field: PN: Estimated distance from origin (North component) // @Field: PE: Estimated distance from origin (East component) // @Field: PD: Estimated distance from origin (Down component) // @Field: GX: Estimated gyro bias, X axis // @Field: GY: Estimated gyro bias, Y axis // @Field: GZ: Estimated gyro bias, Z axis // @Field: OH: Height of origin above WGS-84 // @LoggerMessage: NKF2 // @Description: EKF2 estimator secondary outputs // @Field: TimeUS: Time since system startup // @Field: C: EKF2 core this data is for // @Field: AZbias: Estimated accelerometer Z bias // @Field: GSX: Gyro Scale Factor (X-axis) // @Field: GSY: Gyro Scale Factor (Y-axis) // @Field: GSZ: Gyro Scale Factor (Z-axis) // @Field: VWN: Estimated wind velocity (North component) // @Field: VWE: Estimated wind velocity (East component) // @Field: MN: Magnetic field strength (North component) // @Field: ME: Magnetic field strength (East component) // @Field: MD: Magnetic field strength (Down component) // @Field: MX: Magnetic field strength (body X-axis) // @Field: MY: Magnetic field strength (body Y-axis) // @Field: MZ: Magnetic field strength (body Z-axis) // @Field: MI: Magnetometer used for data // @LoggerMessage: NKF3 // @Description: EKF2 innovations // @Field: TimeUS: Time since system startup // @Field: C: EKF2 core this data is for // @Field: IVN: Innovation in velocity (North component) // @Field: IVE: Innovation in velocity (East component) // @Field: IVD: Innovation in velocity (Down component) // @Field: IPN: Innovation in position (North component) // @Field: IPE: Innovation in position (East component) // @Field: IPD: Innovation in position (Down component) // @Field: IMX: Innovation in magnetic field strength (X-axis component) // @Field: IMY: Innovation in magnetic field strength (Y-axis component) // @Field: IMZ: Innovation in magnetic field strength (Z-axis component) // @Field: IYAW: Innovation in vehicle yaw // @Field: IVT: Innovation in true-airspeed // @LoggerMessage: NKF4 // @Description: EKF2 variances // @Field: TimeUS: Time since system startup // @Field: C: EKF2 core this data is for // @Field: SV: Square root of the velocity variance // @Field: SP: Square root of the position variance // @Field: SH: Square root of the height variance // @Field: SM: Magnetic field variance // @Field: SVT: Square root of the total airspeed variance // @Field: errRP: Filtered error in roll/pitch estimate // @Field: OFN: Most recent position recent magnitude (North component) // @Field: OFE: Most recent position recent magnitude (East component) // @Field: FS: Filter fault status // @Field: TS: Filter timeout status // @Field: SS: Filter solution status // @Field: GPS: Filter GPS status // @Field: PI: Primary core index // @LoggerMessage: NKF5 // @Description: EKF2 Sensor innovations (primary core) and general dumping ground // @Field: TimeUS: Time since system startup // @Field: NI: Normalised flow variance // @Field: FIX: Optical flow LOS rate vector innovations from the main nav filter (X-axis) // @Field: FIY: Optical flow LOS rate vector innovations from the main nav filter (Y-axis) // @Field: AFI: Optical flow LOS rate innovation from terrain offset estimator // @Field: HAGL: Height above ground level // @Field: offset: Estimated vertical position of the terrain relative to the nav filter zero datum // @Field: RI: Range finder innovations // @Field: rng: Measured range // @Field: Herr: Filter ground offset state error // @Field: eAng: Magnitude of angular error // @Field: eVel: Magnitude of velocity error // @Field: ePos: Magnitude of position error // @LoggerMessage: NKQ // @Description: EKF2 quaternion defining the rotation from NED to XYZ (autopilot) axes // @Field: TimeUS: Time since system startup // @Field: C: EKF2 core this data is for // @Field: Q1: Quaternion a term // @Field: Q2: Quaternion b term // @Field: Q3: Quaternion c term // @Field: Q4: Quaternion d term // @LoggerMessage: OABR // @Description: Object avoidance (Bendy Ruler) diagnostics // @Field: TimeUS: Time since system startup // @Field: Active: True if Bendy Ruler avoidance is being used // @Field: DesYaw: Best yaw chosen to avoid obstacle // @Field: Yaw: Current vehicle yaw // @Field: ResChg: True if BendyRuler resisted changing bearing and continued in last calculated bearing // @Field: Mar: Margin from path to obstacle on best yaw chosen // @Field: DLat: Destination latitude // @Field: DLng: Destination longitude // @Field: OALat: Intermediate location chosen for avoidance // @Field: OALng: Intermediate location chosen for avoidance // @LoggerMessage: OADJ // @Description: Object avoidance (Dijkstra) diagnostics // @Field: TimeUS: Time since system startup // @Field: State: Dijkstra avoidance library state // @Field: Err: Dijkstra library error condition // @Field: CurrPoint: Destination point in calculated path to destination // @Field: TotPoints: Number of points in path to destination // @Field: DLat: Destination latitude // @Field: DLng: Destination longitude // @Field: OALat: Object Avoidance chosen destination point latitude // @Field: OALng: Object Avoidance chosen destination point longitude // @LoggerMessage: OF // @Description: Optical flow sensor data // @Field: TimeUS: Time since system startup // @Field: Qual: Estimated sensor data quality // @Field: flowX: Sensor flow rate, X-axis // @Field: flowY: Sensor flow rate,Y-axis // @Field: bodyX: derived velocity, X-axis // @Field: bodyY: derived velocity, Y-axis // @LoggerMessage: ORGN // @Description: Vehicle navigation origin or other notable position // @Field: TimeUS: Time since system startup // @Field: Type: Position type // @Field: Lat: Position latitude // @Field: Lng: Position longitude // @Field: Alt: Position altitude // @LoggerMessage: PARM // @Description: parameter value // @Field: TimeUS: Time since system startup // @Field: Name: parameter name // @Field: Value: parameter vlaue // @LoggerMessage: PIDR,PIDP,PIDY,PIDA,PIDS // @Description: Proportional/Integral/Derivative gain values for Roll/Pitch/Yaw/Altitude/Steering // @Field: TimeUS: Time since system startup // @Field: Tar: desired value // @Field: Act: achieved value // @Field: Err: error between target and achieved // @Field: P: proportional part of PID // @Field: I: integral part of PID // @Field: D: derivative part of PID // @Field: FF: controller feed-forward portion of response // @Field: Dmod: scaler applied to D gain to reduce limit cycling // @LoggerMessage: PM // @Description: autopilot system performance and general data dumping ground // @Field: TimeUS: Time since system startup // @Field: NLon: Number of long loops detected // @Field: NLoop: Number of measurement loops for this message // @Field: MaxT: Maximum loop time // @Field: Mem: Free memory available // @Field: Load: System processor load // @Field: IntE: Internal error mask; which internal errors have been detected // @Field: IntEC: Internal error count; how many internal errors have been detected // @Field: SPIC: Number of SPI transactions processed // @Field: I2CC: Number of i2c transactions processed // @Field: I2CI: Number of i2c interrupts serviced // @Field: ExUS: number of microseconds being added to each loop to address scheduler overruns // @LoggerMessage: POS // @Description: Canonical vehicle position // @Field: TimeUS: Time since system startup // @Field: Lat: Canonical vehicle latitude // @Field: Lng: Canonical vehicle longitude // @Field: Alt: Canonical vehicle altitude // @Field: RelHomeAlt: Canonical vehicle altitude relative to home // @Field: RelOriginAlt: Canonical vehicle altitude relative to navigation origin // @LoggerMessage: POWR // @Description: System power information // @Field: TimeUS: Time since system startup // @Field: Vcc: Flight board voltage // @Field: VServo: Servo rail voltage // @Field: Flags: System power flags // @Field: AccFlags: Accumulated System power flags; all flags which have ever been set // @Field: Safety: Hardware Safety Switch status // @LoggerMessage: PRX // @Description: Proximity sensor data // @Field: TimeUS: Time since system startup // @Field: Health: True if proximity sensor is healthy // @Field: D0: Nearest object in sector surrounding 0-degrees // @Field: D45: Nearest object in sector surrounding 45-degrees // @Field: D90: Nearest object in sector surrounding 90-degrees // @Field: D135: Nearest object in sector surrounding 135-degrees // @Field: D180: Nearest object in sector surrounding 180-degrees // @Field: D225: Nearest object in sector surrounding 225-degrees // @Field: D270: Nearest object in sector surrounding 270-degrees // @Field: D315: Nearest object in sector surrounding 315-degrees // @Field: DUp: Nearest object in upwards direction // @Field: CAn: Angle to closest object // @Field: CDis: Distance to closest object // @LoggerMessage: RAD // @Description: Telemetry radio statistics // @Field: TimeUS: Time since system startup // @Field: RSSI: RSSI // @Field: RemRSSI: RSSI reported from remote radio // @Field: TxBuf: number of bytes in radio ready to be sent // @Field: Noise: local noise floor // @Field: RemNoise: local noise floor reported from remote radio // @Field: RxErrors: damaged packet count // @Field: Fixed: fixed damaged packet count // @LoggerMessage: RALY // @Description: Rally point information // @Field: TimeUS: Time since system startup // @Field: Tot: total number of rally points onboard // @Field: Seq: this rally point's sequence number // @Field: Lat: latitude of rally point // @Field: Lng: longitude of rally point // @Field: Alt: altitude of rally point // @LoggerMessage: RATE // @Description: Desired and achieved vehicle attitude rates // @Field: TimeUS: Time since system startup // @Field: RDes: vehicle desired roll rate // @Field: R: achieved vehicle roll rate // @Field: ROut: normalized output for Roll // @Field: PDes: vehicle desired pitch rate // @Field: P: vehicle pitch rate // @Field: POut: normalized output for Pitch // @Field: YDes: vehicle desired yaw rate // @Field: Y: achieved vehicle yaw rate // @Field: YOut: normalized output for Yaw // @Field: YDes: vehicle desired yaw rate // @Field: Y: achieved vehicle yaw rate // @Field: ADes: desired vehicle vertical acceleration // @Field: A: achieved vehicle vertical acceleration // @Field: AOut: percentage of vertical thrust output current being used // @LoggerMessage: RCIN // @Description: RC input channels to vehicle // @Field: TimeUS: Time since system startup // @Field: C1: channel 1 input // @Field: C2: channel 2 input // @Field: C3: channel 3 input // @Field: C4: channel 4 input // @Field: C5: channel 5 input // @Field: C6: channel 6 input // @Field: C7: channel 7 input // @Field: C8: channel 8 input // @Field: C9: channel 9 input // @Field: C10: channel 10 input // @Field: C11: channel 11 input // @Field: C12: channel 12 input // @Field: C13: channel 13 input // @Field: C14: channel 14 input // @LoggerMessage: RCOU // @Description: Servo channel output values // @Field: TimeUS: Time since system startup // @Field: C1: channel 1 output // @Field: C2: channel 2 output // @Field: C3: channel 3 output // @Field: C4: channel 4 output // @Field: C5: channel 5 output // @Field: C6: channel 6 output // @Field: C7: channel 7 output // @Field: C8: channel 8 output // @Field: C9: channel 9 output // @Field: C10: channel 10 output // @Field: C11: channel 11 output // @Field: C12: channel 12 output // @Field: C13: channel 13 output // @Field: C14: channel 14 output // @LoggerMessage: RFND // @Description: Rangefinder sensor information // @Field: TimeUS: Time since system startup // @Field: Instance: rangefinder instance number this data is from // @Field: Dist: Reported distance from sensor // @Field: Stat: Sensor state // @Field: Orient: Sensor orientation // @LoggerMessage: RPM // @Description: Data from RPM sensors // @Field: TimeUS: Time since system startup // @Field: rpm1: First sensor's data // @Field: rpm2: Second sensor's data // @LoggerMessage: RSSI // @Description: Received Signal Strength Indicator for RC receiver // @Field: TimeUS: Time since system startup // @Field: RXRSSI: RSSI // @LoggerMessage: SIM // @Description: SITL simulator state // @Field: TimeUS: Time since system startup // @Field: Roll: Simulated roll // @Field: Pitch: Simulated pitch // @Field: Yaw: Simulated yaw // @Field: Alt: Simulated altitude // @Field: Lat: Simulated latitude // @Field: Lng: Simulated longitude // @Field: Q1: Attitude quaternion component 1 // @Field: Q2: Attitude quaternion component 2 // @Field: Q3: Attitude quaternion component 3 // @Field: Q4: Attitude quaternion component 4 // @LoggerMessage: SRTL // @Description: SmartRTL statistics // @Field: TimeUS: Time since system startup // @Field: Active: true if SmartRTL could be used right now // @Field: NumPts: number of points currently in use // @Field: MaxPts: maximum number of points that could be used // @Field: Action: most recent internal action taken by SRTL library // @Field: N: point associated with most recent action (North component) // @Field: E: point associated with most recent action (East component) // @Field: D: point associated with most recent action (Down component) // @LoggerMessage: SA // @Description: Simple Avoidance messages // @Field: TimeUS: Time since system startup // @Field: State: True if Simple Avoidance is active // @Field: DVelX: Desired velocity, X-Axis (Velocity before Avoidance) // @Field: DVelY: Desired velocity, Y-Axis (Velocity before Avoidance) // @Field: MVelX: Modified velocity, X-Axis (Velocity after Avoidance) // @Field: MVelY: Modified velocity, Y-Axis (Velocity after Avoidance) // @Field: Back: True if vehicle is backing away // @LoggerMessage: TERR // @Description: Terrain database infomration // @Field: TimeUS: Time since system startup // @Field: Status: Terrain database status // @Field: Lat: Current vehicle latitude // @Field: Lng: Current vehicle longitude // @Field: Spacing: terrain Tile spacing // @Field: TerrH: current Terrain height // @Field: CHeight: Vehicle height above terrain // @Field: Pending: Number of tile requests outstanding // @Field: Loaded: Number of tiles in memory // @LoggerMessage: TSYN // @Description: Time synchronisation response information // @Field: TimeUS: Time since system startup // @Field: SysID: system ID this data is for // @Field: RTT: round trip time for this system // @LoggerMessage: UBX1 // @Description: uBlox-specific GPS information (part 1) // @Field: TimeUS: Time since system startup // @Field: Instance: GPS instance number // @Field: noisePerMS: noise level as measured by GPS // @Field: jamInd: jamming indicator; higher is more likely jammed // @Field: aPower: antenna power indicator; 2 is don't know // @Field: agcCnt: automatic gain control monitor // @Field: config: bitmask for messages which haven't been seen // @LoggerMessage: UBX2 // @Description: uBlox-specific GPS information (part 2) // @Field: TimeUS: Time since system startup // @Field: Instance: GPS instance number // @Field: ofsI: imbalance of I part of complex signal // @Field: magI: magnitude of I part of complex signal // @Field: ofsQ: imbalance of Q part of complex signal // @Field: magQ: magnitude of Q part of complex signal // @LoggerMessage: UNIT // @Description: Message mapping from single character to SI unit // @Field: TimeUS: Time since system startup // @Field: Id: character referenced by FMTU // @Field: Label: Unit - SI where available // @LoggerMessage: VIBE // @Description: Processed (acceleration) vibration information // @Field: TimeUS: Time since system startup // @Field: VibeX: Primary accelerometer filtered vibration, x-axis // @Field: VibeY: Primary accelerometer filtered vibration, y-axis // @Field: VibeZ: Primary accelerometer filtered vibration, z-axis // @Field: Clip0: Number of clipping events on 1st accelerometer // @Field: Clip1: Number of clipping events on 2nd accelerometer // @Field: Clip2: Number of clipping events on 3rd accelerometer // @LoggerMessage: VISO // @Description: Visual Odometry // @Field: TimeUS: System time // @Field: dt: Time period this data covers // @Field: AngDX: Angular change for body-frame roll axis // @Field: AngDY: Angular change for body-frame pitch axis // @Field: AngDZ: Angular change for body-frame z axis // @Field: PosDX: Position change for body-frame X axis (Forward-Back) // @Field: PosDY: Position change for body-frame Y axis (Right-Left) // @Field: PosDZ: Position change for body-frame Z axis (Down-Up) // @Field: conf: Confidence // @LoggerMessage: VISP // @Description: Vision Position // @Field: TimeUS: System time // @Field: RTimeUS: Remote system time // @Field: CTimeMS: Corrected system time // @Field: PX: Position X-axis (North-South) // @Field: PY: Position Y-axis (East-West) // @Field: PZ: Position Z-axis (Down-Up) // @Field: Roll: Roll lean angle // @Field: Pitch: Pitch lean angle // @Field: Yaw: Yaw angle // @Field: PErr: Position estimate error // @Field: AErr: Attitude estimate error // @Field: RstCnt: Position reset counter // @LoggerMessage: VISV // @Description: Vision Velocity // @Field: TimeUS: System time // @Field: RTimeUS: Remote system time // @Field: CTimeMS: Corrected system time // @Field: VX: Velocity X-axis (North-South) // @Field: VY: Velocity Y-axis (East-West) // @Field: VZ: Velocity Z-axis (Down-Up) // @Field: VErr: Velocity estimate error // @Field: RstCnt: Velocity reset counter // @LoggerMessage: WENC // @Description: Wheel encoder measurements // @Field: TimeUS: Time since system startup // @Field: Dist0: First wheel distance travelled // @Field: Qual0: Quality measurement of Dist0 // @Field: Dist1: Second wheel distance travelled // @Field: Qual1: Quality measurement of Dist1 // @LoggerMessage: XKF0 // @Description: EKF3 beacon sensor diagnostics // @Field: TimeUS: Time since system startup // @Field: ID: Beacon sensor ID // @Field: rng: Beacon range // @Field: innov: Beacon range innovation // @Field: SIV: sqrt of beacon range innovation variance // @Field: TR: Beacon range innovation consistency test ratio // @Field: BPN: Beacon north position // @Field: BPE: Beacon east position // @Field: BPD: Beacon down position // @Field: OFH: High estimate of vertical position offset of beacons rel to EKF origin // @Field: OFL: Low estimate of vertical position offset of beacons rel to EKF origin // @Field: OFN: North position of receiver rel to EKF origin // @Field: OFE: East position of receiver rel to EKF origin // @Field: OFD: Down position of receiver rel to EKF origin // @LoggerMessage: XKF1 // @Description: EKF3 estimator outputs // @Field: TimeUS: Time since system startup // @Field: C: EKF3 core this data is for // @Field: Roll: Estimated roll // @Field: Pitch: Estimated pitch // @Field: Yaw: Estimated yaw // @Field: VN: Estimated velocity (North component) // @Field: VE: Estimated velocity (East component) // @Field: VD: Estimated velocity (Down component) // @Field: dPD: Filtered derivative of vertical position (down) // @Field: PN: Estimated distance from origin (North component) // @Field: PE: Estimated distance from origin (East component) // @Field: PD: Estimated distance from origin (Down component) // @Field: GX: Estimated gyro bias, X axis // @Field: GY: Estimated gyro bias, Y axis // @Field: GZ: Estimated gyro bias, Z axis // @Field: OH: Height of origin above WGS-84 // @LoggerMessage: XKF2 // @Description: EKF3 estimator secondary outputs // @Field: TimeUS: Time since system startup // @Field: C: EKF3 core this data is for // @Field: AX: Estimated accelerometer X bias // @Field: AY: Estimated accelerometer Y bias // @Field: AZ: Estimated accelerometer Z bias // @Field: VWN: Estimated wind velocity (North component) // @Field: VWE: Estimated wind velocity (East component) // @Field: MN: Magnetic field strength (North component) // @Field: ME: Magnetic field strength (East component) // @Field: MD: Magnetic field strength (Down component) // @Field: MX: Magnetic field strength (body X-axis) // @Field: MY: Magnetic field strength (body Y-axis) // @Field: MZ: Magnetic field strength (body Z-axis) // @Field: MI: Magnetometer used for data // @LoggerMessage: XKF3 // @Description: EKF3 innovations // @Field: TimeUS: Time since system startup // @Field: C: EKF3 core this data is for // @Field: IVN: Innovation in velocity (North component) // @Field: IVE: Innovation in velocity (East component) // @Field: IVD: Innovation in velocity (Down component) // @Field: IPN: Innovation in position (North component) // @Field: IPE: Innovation in position (East component) // @Field: IPD: Innovation in position (Down component) // @Field: IMX: Innovation in magnetic field strength (X-axis component) // @Field: IMY: Innovation in magnetic field strength (Y-axis component) // @Field: IMZ: Innovation in magnetic field strength (Z-axis component) // @Field: IYAW: Innovation in vehicle yaw // @Field: IVT: Innovation in true-airspeed // @LoggerMessage: XKF4 // @Description: EKF3 variances // @Field: TimeUS: Time since system startup // @Field: C: EKF3 core this data is for // @Field: SV: Square root of the velocity variance // @Field: SP: Square root of the position variance // @Field: SH: Square root of the height variance // @Field: SM: Magnetic field variance // @Field: SVT: Square root of the total airspeed variance // @Field: errRP: Filtered error in roll/pitch estimate // @Field: OFN: Most recent position recent magnitude (North component) // @Field: OFE: Most recent position recent magnitude (East component) // @Field: FS: Filter fault status // @Field: TS: Filter timeout status // @Field: SS: Filter solution status // @Field: GPS: Filter GPS status // @Field: PI: Primary core index // @LoggerMessage: XKF5 // @Description: EKF3 Sensor innovations (primary core) and general dumping ground // @Field: TimeUS: Time since system startup // @Field: NI: Normalised flow variance // @Field: FIX: Optical flow LOS rate vector innovations from the main nav filter (X-axis) // @Field: FIY: Optical flow LOS rate vector innovations from the main nav filter (Y-axis) // @Field: AFI: Optical flow LOS rate innovation from terrain offset estimator // @Field: HAGL: Height above ground level // @Field: offset: Estimated vertical position of the terrain relative to the nav filter zero datum // @Field: RI: Range finder innovations // @Field: rng: Measured range // @Field: Herr: Filter ground offset state error // @Field: eAng: Magnitude of angular error // @Field: eVel: Magnitude of velocity error // @Field: ePos: Magnitude of position error // @LoggerMessage: XKFD // @Description: EKF3 Body Frame Odometry errors // @Field: TimeUS: Time since system startup // @Field: IX: Innovation in velocity (X-axis) // @Field: IY: Innovation in velocity (Y-axis) // @Field: IZ: Innovation in velocity (Z-axis) // @Field: IVX: Variance in velocity (X-axis) // @Field: IVY: Variance in velocity (Y-axis) // @Field: IVZ: Variance in velocity (Z-axis) // @LoggerMessage: XKQ // @Description: EKF3 quaternion defining the rotation from NED to XYZ (autopilot) axes // @Field: TimeUS: Time since system startup // @Field: C: EKF3 core this data is for // @Field: Q1: Quaternion a term // @Field: Q2: Quaternion b term // @Field: Q3: Quaternion c term // @Field: Q4: Quaternion d term // @LoggerMessage: XKV1 // @Description: EKF3 State variances (primary core) // @Field: TimeUS: Time since system startup // @Field: V00: Variance for state 0 // @Field: V01: Variance for state 1 // @Field: V02: Variance for state 2 // @Field: V03: Variance for state 3 // @Field: V04: Variance for state 4 // @Field: V05: Variance for state 5 // @Field: V06: Variance for state 6 // @Field: V07: Variance for state 7 // @Field: V08: Variance for state 8 // @Field: V09: Variance for state 9 // @Field: V10: Variance for state 10 // @Field: V11: Variance for state 11 // @LoggerMessage: XKV2 // @Description: more EKF3 State Variances (primary core) // @Field: TimeUS: Time since system startup // @Field: V12: Variance for state 12 // @Field: V13: Variance for state 13 // @Field: V14: Variance for state 14 // @Field: V15: Variance for state 15 // @Field: V16: Variance for state 16 // @Field: V17: Variance for state 17 // @Field: V18: Variance for state 18 // @Field: V19: Variance for state 19 // @Field: V20: Variance for state 20 // @Field: V21: Variance for state 21 // @Field: V22: Variance for state 22 // @Field: V23: Variance for state 23 // @LoggerMessage: WINC // @Description: Winch // @Field: TimeUS: Time since system startup // @Field: Heal: Healthy // @Field: ThEnd: Reached end of thread // @Field: Mov: Motor is moving // @Field: Clut: Clutch is engaged (motor can move freely) // @Field: Mode: 0 is Relaxed, 1 is Position Control, 2 is Rate Control // @Field: DLen: Desired Length // @Field: Len: Estimated Length // @Field: DRate: Desired Rate // @Field: Tens: Tension on line // @Field: Vcc: Voltage to Motor // @Field: Temp: Motor temperature // messages for all boards #define LOG_BASE_STRUCTURES \ { LOG_FORMAT_MSG, sizeof(log_Format), \ "FMT", "BBnNZ", "Type,Length,Name,Format,Columns", "-b---", "-----" }, \ { LOG_UNIT_MSG, sizeof(log_Unit), \ "UNIT", "QbZ", "TimeUS,Id,Label", "s--","F--" }, \ { LOG_FORMAT_UNITS_MSG, sizeof(log_Format_Units), \ "FMTU", "QBNN", "TimeUS,FmtType,UnitIds,MultIds","s---", "F---" }, \ { LOG_MULT_MSG, sizeof(log_Format_Multiplier), \ "MULT", "Qbd", "TimeUS,Id,Mult", "s--","F--" }, \ { LOG_PARAMETER_MSG, sizeof(log_Parameter), \ "PARM", "QNf", "TimeUS,Name,Value", "s--", "F--" }, \ { LOG_GPS_MSG, sizeof(log_GPS), \ "GPS", GPS_FMT, GPS_LABELS, GPS_UNITS, GPS_MULTS }, \ { LOG_GPS2_MSG, sizeof(log_GPS), \ "GPS2", GPS_FMT, GPS_LABELS, GPS_UNITS, GPS_MULTS }, \ { LOG_GPSB_MSG, sizeof(log_GPS), \ "GPSB", GPS_FMT, GPS_LABELS, GPS_UNITS, GPS_MULTS }, \ { LOG_GPA_MSG, sizeof(log_GPA), \ "GPA", GPA_FMT, GPA_LABELS, GPA_UNITS, GPA_MULTS }, \ { LOG_GPA2_MSG, sizeof(log_GPA), \ "GPA2", GPA_FMT, GPA_LABELS, GPA_UNITS, GPA_MULTS }, \ { LOG_GPAB_MSG, sizeof(log_GPA), \ "GPAB", GPA_FMT, GPA_LABELS, GPA_UNITS, GPA_MULTS }, \ { LOG_IMU_MSG, sizeof(log_IMU), \ "IMU", IMU_FMT, IMU_LABELS, IMU_UNITS, IMU_MULTS }, \ { LOG_MESSAGE_MSG, sizeof(log_Message), \ "MSG", "QZ", "TimeUS,Message", "s-", "F-"}, \ { LOG_RCIN_MSG, sizeof(log_RCIN), \ "RCIN", "QHHHHHHHHHHHHHH", "TimeUS,C1,C2,C3,C4,C5,C6,C7,C8,C9,C10,C11,C12,C13,C14", "sYYYYYYYYYYYYYY", "F--------------" }, \ { LOG_RCOUT_MSG, sizeof(log_RCOUT), \ "RCOU", "QHHHHHHHHHHHHHH", "TimeUS,C1,C2,C3,C4,C5,C6,C7,C8,C9,C10,C11,C12,C13,C14", "sYYYYYYYYYYYYYY", "F--------------" }, \ { LOG_RSSI_MSG, sizeof(log_RSSI), \ "RSSI", "Qf", "TimeUS,RXRSSI", "s-", "F-" }, \ { LOG_BARO_MSG, sizeof(log_BARO), \ "BARO", BARO_FMT, BARO_LABELS, BARO_UNITS, BARO_MULTS }, \ { LOG_POWR_MSG, sizeof(log_POWR), \ "POWR","QffHHB","TimeUS,Vcc,VServo,Flags,AccFlags,Safety", "svv---", "F00---" }, \ { LOG_CMD_MSG, sizeof(log_Cmd), \ "CMD", "QHHHffffLLfB","TimeUS,CTot,CNum,CId,Prm1,Prm2,Prm3,Prm4,Lat,Lng,Alt,Frame", "s-------DUm-", "F-------GG0-" }, \ { LOG_MAVLINK_COMMAND_MSG, sizeof(log_MAVLink_Command), \ "MAVC", "QBBBHBBffffiifBB","TimeUS,TS,TC,Fr,Cmd,Cur,AC,P1,P2,P3,P4,X,Y,Z,Res,WL", "s---------------", "F---------------" }, \ { LOG_RADIO_MSG, sizeof(log_Radio), \ "RAD", "QBBBBBHH", "TimeUS,RSSI,RemRSSI,TxBuf,Noise,RemNoise,RxErrors,Fixed", "s-------", "F-------" }, \ { LOG_CAMERA_MSG, sizeof(log_Camera), \ "CAM", "QIHLLeeeccC","TimeUS,GPSTime,GPSWeek,Lat,Lng,Alt,RelAlt,GPSAlt,Roll,Pitch,Yaw", "s--DUmmmddd", "F--GGBBBBBB" }, \ { LOG_TRIGGER_MSG, sizeof(log_Camera), \ "TRIG", "QIHLLeeeccC","TimeUS,GPSTime,GPSWeek,Lat,Lng,Alt,RelAlt,GPSAlt,Roll,Pitch,Yaw", "s--DUmmmddd", "F--GGBBBBBB" }, \ { LOG_ARSP_MSG, sizeof(log_AIRSPEED), "ARSP", ARSP_FMT, ARSP_LABELS, ARSP_UNITS, ARSP_MULTS }, \ { LOG_ASP2_MSG, sizeof(log_AIRSPEED), "ASP2", ARSP_FMT, ARSP_LABELS, ARSP_UNITS, ARSP_MULTS }, \ { LOG_CURRENT_MSG, sizeof(log_Current), \ "BAT", "QBfffffcf", "TimeUS,Instance,Volt,VoltR,Curr,CurrTot,EnrgTot,Temp,Res", "s#vvAiJOw", "F-000!/?0" }, \ { LOG_CURRENT_CELLS_MSG, sizeof(log_Current_Cells), \ "BCL", "QBfHHHHHHHHHHHH", "TimeUS,Instance,Volt,V1,V2,V3,V4,V5,V6,V7,V8,V9,V10,V11,V12", "s#vvvvvvvvvvvvv", "F-0CCCCCCCCCCCC" }, \ { LOG_ATTITUDE_MSG, sizeof(log_Attitude),\ "ATT", "QccccCCCC", "TimeUS,DesRoll,Roll,DesPitch,Pitch,DesYaw,Yaw,ErrRP,ErrYaw", "sddddhhdh", "FBBBBBBBB" }, \ { LOG_COMPASS_MSG, sizeof(log_Compass), \ "MAG", MAG_FMT, MAG_LABELS, MAG_UNITS, MAG_MULTS }, \ { LOG_MODE_MSG, sizeof(log_Mode), \ "MODE", "QMBB", "TimeUS,Mode,ModeNum,Rsn", "s---", "F---" }, \ { LOG_RFND_MSG, sizeof(log_RFND), \ "RFND", "QBCBB", "TimeUS,Instance,Dist,Stat,Orient", "s#m--", "F-B--" }, \ { LOG_MAV_STATS, sizeof(log_MAV_Stats), \ "DMS", "QIIIIBBBBBBBBB", "TimeUS,N,Dp,RT,RS,Fa,Fmn,Fmx,Pa,Pmn,Pmx,Sa,Smn,Smx", "s-------------", "F-------------" }, \ { LOG_BEACON_MSG, sizeof(log_Beacon), \ "BCN", "QBBfffffff", "TimeUS,Health,Cnt,D0,D1,D2,D3,PosX,PosY,PosZ", "s--mmmmmmm", "F--BBBBBBB" }, \ { LOG_PROXIMITY_MSG, sizeof(log_Proximity), \ "PRX", "QBfffffffffff", "TimeUS,Health,D0,D45,D90,D135,D180,D225,D270,D315,DUp,CAn,CDis", "s-mmmmmmmmmhm", "F-00000000000" }, \ { LOG_PERFORMANCE_MSG, sizeof(log_Performance), \ "PM", "QHHIIHIIIIII", "TimeUS,NLon,NLoop,MaxT,Mem,Load,IntE,IntEC,SPIC,I2CC,I2CI,ExUS", "s---b%-----s", "F---0A-----F" }, \ { LOG_SRTL_MSG, sizeof(log_SRTL), \ "SRTL", "QBHHBfff", "TimeUS,Active,NumPts,MaxPts,Action,N,E,D", "s----mmm", "F----000" }, \ { LOG_OA_BENDYRULER_MSG, sizeof(log_OABendyRuler), \ "OABR","QBHHBfLLLL","TimeUS,Active,DesYaw,Yaw,ResChg,Mar,DLat,DLng,OALat,OALng", "sbdd-mDUDU", "F-----GGGG" }, \ { LOG_OA_DIJKSTRA_MSG, sizeof(log_OADijkstra), \ "OADJ","QBBBBLLLL","TimeUS,State,Err,CurrPoint,TotPoints,DLat,DLng,OALat,OALng", "sbbbbDUDU", "F----GGGG" }, \ { LOG_SIMPLE_AVOID_MSG, sizeof(log_SimpleAvoid), \ "SA", "QBffffB","TimeUS,State,DVelX,DVelY,MVelX,MVelY,Back", "sbnnnnb", "F------"}, \ { LOG_IMU2_MSG, sizeof(log_IMU), \ "IMU2", IMU_FMT, IMU_LABELS, IMU_UNITS, IMU_MULTS }, \ { LOG_IMU3_MSG, sizeof(log_IMU), \ "IMU3", IMU_FMT, IMU_LABELS, IMU_UNITS, IMU_MULTS }, \ { LOG_AHR2_MSG, sizeof(log_AHRS), \ "AHR2","QccCfLLffff","TimeUS,Roll,Pitch,Yaw,Alt,Lat,Lng,Q1,Q2,Q3,Q4","sddhmDU????", "FBBB0GG????" }, \ { LOG_POS_MSG, sizeof(log_POS), \ "POS","QLLfff","TimeUS,Lat,Lng,Alt,RelHomeAlt,RelOriginAlt", "sDUmmm", "FGG000" }, \ { LOG_SIMSTATE_MSG, sizeof(log_AHRS), \ "SIM","QccCfLLffff","TimeUS,Roll,Pitch,Yaw,Alt,Lat,Lng,Q1,Q2,Q3,Q4", "sddhmDU????", "FBBB0GG????" }, \ { LOG_NKF1_MSG, sizeof(log_EKF1), \ "NKF1","QBccCfffffffccce","TimeUS,C,Roll,Pitch,Yaw,VN,VE,VD,dPD,PN,PE,PD,GX,GY,GZ,OH", "s#ddhnnnnmmmkkkm", "F-BBB0000000BBBB" }, \ { LOG_NKF2_MSG, sizeof(log_NKF2), \ "NKF2","QBbccccchhhhhhB","TimeUS,C,AZbias,GSX,GSY,GSZ,VWN,VWE,MN,ME,MD,MX,MY,MZ,MI", "s#----nnGGGGGG-", "F-----BBCCCCCC-" }, \ { LOG_NKF3_MSG, sizeof(log_NKF3), \ "NKF3","QBcccccchhhcc","TimeUS,C,IVN,IVE,IVD,IPN,IPE,IPD,IMX,IMY,IMZ,IYAW,IVT", "s#nnnmmmGGG??", "F-BBBBBBCCCBB" }, \ { LOG_NKF4_MSG, sizeof(log_NKF4), \ "NKF4","QBcccccfbbHBIHb","TimeUS,C,SV,SP,SH,SM,SVT,errRP,OFN,OFE,FS,TS,SS,GPS,PI", "s#------??-----", "F-------??-----" }, \ { LOG_NKF5_MSG, sizeof(log_NKF5), \ "NKF5","QBhhhcccCCfff","TimeUS,NI,FIX,FIY,AFI,HAGL,offset,RI,rng,Herr,eAng,eVel,ePos", "s----m???mrnm", "F----BBBBB000" }, \ { LOG_NKF10_MSG, sizeof(log_RngBcnDebug), \ "NKF0","QBccCCcccccccc","TimeUS,ID,rng,innov,SIV,TR,BPN,BPE,BPD,OFH,OFL,OFN,OFE,OFD", "s-m---mmmmmmmm", "F-B---BBBBBBBB" }, \ { LOG_NKQ_MSG, sizeof(log_Quaternion), "NKQ", QUAT_FMT, QUAT_LABELS, QUAT_UNITS, QUAT_MULTS }, \ { LOG_XKF1_MSG, sizeof(log_EKF1), \ "XKF1","QBccCfffffffccce","TimeUS,C,Roll,Pitch,Yaw,VN,VE,VD,dPD,PN,PE,PD,GX,GY,GZ,OH", "s#ddhnnnnmmmkkkm", "F-BBB0000000BBBB" }, \ { LOG_XKF2_MSG, sizeof(log_XKF2), \ "XKF2","QBccccchhhhhhB","TimeUS,C,AX,AY,AZ,VWN,VWE,MN,ME,MD,MX,MY,MZ,MI", "s#---nnGGGGGG-", "F----BBCCCCCC-" }, \ { LOG_XKF3_MSG, sizeof(log_NKF3), \ "XKF3","QBcccccchhhcc","TimeUS,C,IVN,IVE,IVD,IPN,IPE,IPD,IMX,IMY,IMZ,IYAW,IVT", "s#nnnmmmGGG??", "F-BBBBBBCCCBB" }, \ { LOG_XKF4_MSG, sizeof(log_NKF4), \ "XKF4","QBcccccfbbHBIHb","TimeUS,C,SV,SP,SH,SM,SVT,errRP,OFN,OFE,FS,TS,SS,GPS,PI", "s#------??-----", "F-------??-----" }, \ { LOG_XKF5_MSG, sizeof(log_NKF5), \ "XKF5","QBhhhcccCCfff","TimeUS,NI,FIX,FIY,AFI,HAGL,offset,RI,rng,Herr,eAng,eVel,ePos", "s----m???mrnm", "F----BBBBB000" }, \ { LOG_XKF10_MSG, sizeof(log_RngBcnDebug), \ "XKF0","QBccCCcccccccc","TimeUS,ID,rng,innov,SIV,TR,BPN,BPE,BPD,OFH,OFL,OFN,OFE,OFD", "s-m---mmmmmmmm", "F-B---BBBBBBBB" }, \ { LOG_XKQ_MSG, sizeof(log_Quaternion), "XKQ", QUAT_FMT, QUAT_LABELS, QUAT_UNITS, QUAT_MULTS }, \ { LOG_XKFD_MSG, sizeof(log_ekfBodyOdomDebug), \ "XKFD","Qffffff","TimeUS,IX,IY,IZ,IVX,IVY,IVZ", "s------", "F------" }, \ { LOG_XKV1_MSG, sizeof(log_ekfStateVar), \ "XKV1","Qffffffffffff","TimeUS,V00,V01,V02,V03,V04,V05,V06,V07,V08,V09,V10,V11", "s------------", "F------------" }, \ { LOG_XKV2_MSG, sizeof(log_ekfStateVar), \ "XKV2","Qffffffffffff","TimeUS,V12,V13,V14,V15,V16,V17,V18,V19,V20,V21,V22,V23", "s------------", "F------------" }, \ { LOG_TERRAIN_MSG, sizeof(log_TERRAIN), \ "TERR","QBLLHffHH","TimeUS,Status,Lat,Lng,Spacing,TerrH,CHeight,Pending,Loaded", "s-DU-mm--", "F-GG-00--" }, \ { LOG_GPS_UBX1_MSG, sizeof(log_Ubx1), \ "UBX1", "QBHBBHI", "TimeUS,Instance,noisePerMS,jamInd,aPower,agcCnt,config", "s#-----", "F------" }, \ { LOG_GPS_UBX2_MSG, sizeof(log_Ubx2), \ "UBX2", "QBbBbB", "TimeUS,Instance,ofsI,magI,ofsQ,magQ", "s#----", "F-----" }, \ { LOG_GPS_RAW_MSG, sizeof(log_GPS_RAW), \ "GRAW", "QIHBBddfBbB", "TimeUS,WkMS,Week,numSV,sv,cpMes,prMes,doMes,mesQI,cno,lli", "s--S-------", "F--0-------" }, \ { LOG_GPS_RAWH_MSG, sizeof(log_GPS_RAWH), \ "GRXH", "QdHbBB", "TimeUS,rcvTime,week,leapS,numMeas,recStat", "s-----", "F-----" }, \ { LOG_GPS_RAWS_MSG, sizeof(log_GPS_RAWS), \ "GRXS", "QddfBBBHBBBBB", "TimeUS,prMes,cpMes,doMes,gnss,sv,freq,lock,cno,prD,cpD,doD,trk", "s------------", "F------------" }, \ { LOG_ESC_MSG, sizeof(log_Esc), \ "ESC", "QBeCCcHc", "TimeUS,Instance,RPM,Volt,Curr,Temp,CTot,MotTemp", "s#qvAO-O", "F-BBBB-B" }, \ { LOG_CSRV_MSG, sizeof(log_CSRV), \ "CSRV","QBfffB","TimeUS,Id,Pos,Force,Speed,Pow", "s#---%", "F-0000" }, \ { LOG_CESC_MSG, sizeof(log_CESC), \ "CESC","QBIfffiB","TimeUS,Id,ECnt,Voltage,Curr,Temp,RPM,Pow", "s#-vAOq%", "F-000000" }, \ { LOG_COMPASS2_MSG, sizeof(log_Compass), \ "MAG2",MAG_FMT, MAG_LABELS, MAG_UNITS, MAG_MULTS }, \ { LOG_COMPASS3_MSG, sizeof(log_Compass), \ "MAG3",MAG_FMT, MAG_LABELS, MAG_UNITS, MAG_MULTS }, \ { LOG_ACC1_MSG, sizeof(log_ACCEL), \ "ACC1", ACC_FMT, ACC_LABELS, ACC_UNITS, ACC_MULTS }, \ { LOG_ACC2_MSG, sizeof(log_ACCEL), \ "ACC2", ACC_FMT, ACC_LABELS, ACC_UNITS, ACC_MULTS }, \ { LOG_ACC3_MSG, sizeof(log_ACCEL), \ "ACC3", ACC_FMT, ACC_LABELS, ACC_UNITS, ACC_MULTS }, \ { LOG_GYR1_MSG, sizeof(log_GYRO), \ "GYR1", GYR_FMT, GYR_LABELS, GYR_UNITS, GYR_MULTS }, \ { LOG_GYR2_MSG, sizeof(log_GYRO), \ "GYR2", GYR_FMT, GYR_LABELS, GYR_UNITS, GYR_MULTS }, \ { LOG_GYR3_MSG, sizeof(log_GYRO), \ "GYR3", GYR_FMT, GYR_LABELS, GYR_UNITS, GYR_MULTS }, \ { LOG_PIDR_MSG, sizeof(log_PID), \ "PIDR", PID_FMT, PID_LABELS, PID_UNITS, PID_MULTS }, \ { LOG_PIDP_MSG, sizeof(log_PID), \ "PIDP", PID_FMT, PID_LABELS, PID_UNITS, PID_MULTS }, \ { LOG_PIDY_MSG, sizeof(log_PID), \ "PIDY", PID_FMT, PID_LABELS, PID_UNITS, PID_MULTS }, \ { LOG_PIDA_MSG, sizeof(log_PID), \ "PIDA", PID_FMT, PID_LABELS, PID_UNITS, PID_MULTS }, \ { LOG_PIDS_MSG, sizeof(log_PID), \ "PIDS", PID_FMT, PID_LABELS, PID_UNITS, PID_MULTS }, \ { LOG_DSTL_MSG, sizeof(log_DSTL), \ "DSTL", "QBfLLeccfeffff", "TimeUS,Stg,THdg,Lat,Lng,Alt,XT,Travel,L1I,Loiter,Des,P,I,D", "s??DUm--------", "F??000--------" }, \ { LOG_BAR2_MSG, sizeof(log_BARO), \ "BAR2", BARO_FMT, BARO_LABELS, BARO_UNITS, BARO_MULTS }, \ { LOG_BAR3_MSG, sizeof(log_BARO), \ "BAR3", BARO_FMT, BARO_LABELS, BARO_UNITS, BARO_MULTS }, \ { LOG_VIBE_MSG, sizeof(log_Vibe), \ "VIBE", "QfffIII", "TimeUS,VibeX,VibeY,VibeZ,Clip0,Clip1,Clip2", "s------", "F------" }, \ { LOG_IMUDT_MSG, sizeof(log_IMUDT), \ "IMT",IMT_FMT,IMT_LABELS, IMT_UNITS, IMT_MULTS }, \ { LOG_IMUDT2_MSG, sizeof(log_IMUDT), \ "IMT2",IMT_FMT,IMT_LABELS, IMT_UNITS, IMT_MULTS }, \ { LOG_IMUDT3_MSG, sizeof(log_IMUDT), \ "IMT3",IMT_FMT,IMT_LABELS, IMT_UNITS, IMT_MULTS }, \ { LOG_ISBH_MSG, sizeof(log_ISBH), \ "ISBH",ISBH_FMT,ISBH_LABELS,ISBH_UNITS,ISBH_MULTS }, \ { LOG_ISBD_MSG, sizeof(log_ISBD), \ "ISBD",ISBD_FMT,ISBD_LABELS, ISBD_UNITS, ISBD_MULTS }, \ { LOG_ORGN_MSG, sizeof(log_ORGN), \ "ORGN","QBLLe","TimeUS,Type,Lat,Lng,Alt", "s-DUm", "F-GGB" }, \ { LOG_DF_FILE_STATS, sizeof(log_DSF), \ "DSF", "QIHIIII", "TimeUS,Dp,Blk,Bytes,FMn,FMx,FAv", "s--b---", "F--0---" }, \ { LOG_RPM_MSG, sizeof(log_RPM), \ "RPM", "Qff", "TimeUS,rpm1,rpm2", "sqq", "F00" }, \ { LOG_RATE_MSG, sizeof(log_Rate), \ "RATE", "Qffffffffffff", "TimeUS,RDes,R,ROut,PDes,P,POut,YDes,Y,YOut,ADes,A,AOut", "skk-kk-kk-oo-", "F?????????BB-" }, \ { LOG_RALLY_MSG, sizeof(log_Rally), \ "RALY", "QBBLLh", "TimeUS,Tot,Seq,Lat,Lng,Alt", "s--DUm", "F--GGB" }, \ { LOG_MAV_MSG, sizeof(log_MAV), \ "MAV", "QBHHHBHH", "TimeUS,chan,txp,rxp,rxdp,flags,ss,tf", "s#----s-", "F-000-C-" }, \ { LOG_VISUALODOM_MSG, sizeof(log_VisualOdom), \ "VISO", "Qffffffff", "TimeUS,dt,AngDX,AngDY,AngDZ,PosDX,PosDY,PosDZ,conf", "ssrrrmmm-", "FF000000-" }, \ { LOG_VISUALPOS_MSG, sizeof(log_VisualPosition), \ "VISP", "QQIffffffffB", "TimeUS,RTimeUS,CTimeMS,PX,PY,PZ,Roll,Pitch,Yaw,PErr,AErr,RstCnt", "sssmmmddhmd-", "FFC00000000-" }, \ { LOG_VISUALVEL_MSG, sizeof(log_VisualVelocity), \ "VISV", "QQIffffB", "TimeUS,RTimeUS,CTimeMS,VX,VY,VZ,VErr,RstCnt", "sssnnnn-", "FFC0000-" }, \ { LOG_OPTFLOW_MSG, sizeof(log_Optflow), \ "OF", "QBffff", "TimeUS,Qual,flowX,flowY,bodyX,bodyY", "s-EEnn", "F-0000" }, \ { LOG_WHEELENCODER_MSG, sizeof(log_WheelEncoder), \ "WENC", "Qfbfb", "TimeUS,Dist0,Qual0,Dist1,Qual1", "sm-m-", "F0-0-" }, \ { LOG_ADSB_MSG, sizeof(log_ADSB), \ "ADSB", "QIiiiHHhH", "TimeUS,ICAO_address,Lat,Lng,Alt,Heading,Hor_vel,Ver_vel,Squark", "s-DUmhnn-", "F-GGCBCC-" }, \ { LOG_EVENT_MSG, sizeof(log_Event), \ "EV", "QB", "TimeUS,Id", "s-", "F-" }, \ { LOG_ARM_DISARM_MSG, sizeof(log_Arm_Disarm), \ "ARM", "QBIBB", "TimeUS,ArmState,ArmChecks,Forced,Method", "s----", "F----" }, \ { LOG_ERROR_MSG, sizeof(log_Error), \ "ERR", "QBB", "TimeUS,Subsys,ECode", "s--", "F--" }, \ { LOG_WINCH_MSG, sizeof(log_Winch), \ "WINC", "QBBBBBfffHfb", "TimeUS,Heal,ThEnd,Mov,Clut,Mode,DLen,Len,DRate,Tens,Vcc,Temp", "s-----mmn?vO", "F-----000000" } // @LoggerMessage: SBPH // @Description: Swift Health Data // @Field: TimeUS: Time since system startup // @Field: CrcError: Number of packet CRC errors on serial connection // @Field: LastInject: Timestamp of last raw data injection to GPS // @Field: IARhyp: Current number of integer ambiguity hypotheses // @LoggerMessage: SBRH // @Description: Swift Raw Message Data // @Field: TimeUS: Time since system startup // @Field: msg_flag: Swift message type // @Field: 1: Sender ID // @Field: 2: index; always 1 // @Field: 3: pages; number of pages received // @Field: 4: msg length; number of bytes received // @Field: 5: unused; always zero // @Field: 6: data received from device #define LOG_SBP_STRUCTURES \ { LOG_MSG_SBPHEALTH, sizeof(log_SbpHealth), \ "SBPH", "QIII", "TimeUS,CrcError,LastInject,IARhyp", "s---", "F---" }, \ { LOG_MSG_SBPRAWH, sizeof(log_SbpRAWH), \ "SBRH", "QQQQQQQQ", "TimeUS,msg_flag,1,2,3,4,5,6", "s--b----", "F--0----" }, \ { LOG_MSG_SBPRAWM, sizeof(log_SbpRAWM), \ "SBRM", "QQQQQQQQQQQQQQQ", "TimeUS,msg_flag,1,2,3,4,5,6,7,8,9,10,11,12,13", "s??????????????", "F??????????????" }, \ { LOG_MSG_SBPEVENT, sizeof(log_SbpEvent), \ "SBRE", "QHIiBB", "TimeUS,GWk,GMS,ns_residual,level,quality", "s?????", "F?????" } #define LOG_COMMON_STRUCTURES LOG_BASE_STRUCTURES, LOG_SBP_STRUCTURES // message types 0 to 63 reserved for vehicle specific use // message types for common messages enum LogMessages : uint8_t { LOG_NKF1_MSG = 64, LOG_NKF2_MSG, LOG_NKF3_MSG, LOG_NKF4_MSG, LOG_NKF5_MSG, LOG_NKF10_MSG, LOG_NKQ_MSG, LOG_XKF1_MSG, LOG_XKF2_MSG, LOG_XKF3_MSG, LOG_XKF4_MSG, LOG_XKF5_MSG, LOG_XKF10_MSG, LOG_XKQ_MSG, LOG_XKFD_MSG, LOG_XKV1_MSG, LOG_XKV2_MSG, LOG_PARAMETER_MSG, LOG_GPS_MSG, LOG_GPS2_MSG, LOG_GPSB_MSG, LOG_IMU_MSG, LOG_MESSAGE_MSG, LOG_RCIN_MSG, LOG_RCOUT_MSG, LOG_RSSI_MSG, LOG_IMU2_MSG, LOG_BARO_MSG, LOG_POWR_MSG, LOG_AHR2_MSG, LOG_SIMSTATE_MSG, LOG_CMD_MSG, LOG_MAVLINK_COMMAND_MSG, LOG_RADIO_MSG, LOG_ATRP_MSG, LOG_CAMERA_MSG, LOG_IMU3_MSG, LOG_TERRAIN_MSG, LOG_GPS_UBX1_MSG, LOG_GPS_UBX2_MSG, LOG_ESC_MSG, LOG_CSRV_MSG, LOG_CESC_MSG, LOG_BAR2_MSG, LOG_ARSP_MSG, LOG_ATTITUDE_MSG, LOG_CURRENT_MSG, LOG_CURRENT_CELLS_MSG, LOG_COMPASS_MSG, LOG_COMPASS2_MSG, LOG_COMPASS3_MSG, LOG_MODE_MSG, LOG_GPS_RAW_MSG, // LOG_GPS_RAWH_MSG is used as a check for duplicates. Do not add between this and LOG_FORMAT_MSG LOG_GPS_RAWH_MSG, LOG_FORMAT_MSG = 128, // this must remain #128 LOG_GPS_RAWS_MSG, LOG_ACC1_MSG, LOG_ACC2_MSG, LOG_ACC3_MSG, LOG_GYR1_MSG, LOG_GYR2_MSG, LOG_GYR3_MSG, LOG_POS_MSG, LOG_PIDR_MSG, LOG_PIDP_MSG, LOG_PIDY_MSG, LOG_PIDA_MSG, LOG_PIDS_MSG, LOG_DSTL_MSG, LOG_VIBE_MSG, LOG_IMUDT_MSG, LOG_IMUDT2_MSG, LOG_IMUDT3_MSG, LOG_ORGN_MSG, LOG_RPM_MSG, LOG_GPA_MSG, LOG_GPA2_MSG, LOG_GPAB_MSG, LOG_RFND_MSG, LOG_BAR3_MSG, LOG_MAV_STATS, LOG_FORMAT_UNITS_MSG, LOG_UNIT_MSG, LOG_MULT_MSG, LOG_MSG_SBPHEALTH, LOG_MSG_SBPLLH, LOG_MSG_SBPBASELINE, LOG_MSG_SBPTRACKING1, LOG_MSG_SBPTRACKING2, LOG_MSG_SBPRAWH, LOG_MSG_SBPRAWM, LOG_MSG_SBPEVENT, LOG_TRIGGER_MSG, LOG_RATE_MSG, LOG_RALLY_MSG, LOG_VISUALODOM_MSG, LOG_VISUALPOS_MSG, LOG_AOA_SSA_MSG, LOG_BEACON_MSG, LOG_PROXIMITY_MSG, LOG_DF_FILE_STATS, LOG_SRTL_MSG, LOG_ISBH_MSG, LOG_ISBD_MSG, LOG_ASP2_MSG, LOG_PERFORMANCE_MSG, LOG_OPTFLOW_MSG, LOG_EVENT_MSG, LOG_WHEELENCODER_MSG, LOG_MAV_MSG, LOG_ERROR_MSG, LOG_ADSB_MSG, LOG_ARM_DISARM_MSG, LOG_OA_BENDYRULER_MSG, LOG_OA_DIJKSTRA_MSG, LOG_VISUALVEL_MSG, LOG_SIMPLE_AVOID_MSG, LOG_WINCH_MSG, _LOG_LAST_MSG_ }; static_assert(_LOG_LAST_MSG_ <= 255, "Too many message formats"); static_assert(LOG_GPS_RAWH_MSG < 128, "Duplicate message format IDs"); enum LogOriginType { ekf_origin = 0, ahrs_home = 1 };