/* * This file is free software: you can redistribute it and/or modify it * under the terms of the GNU General Public License as published by the * Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This file is distributed in the hope that it will be useful, but * WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. * See the GNU General Public License for more details. * * You should have received a copy of the GNU General Public License along * with this program. If not, see . */ /* * * original code by: * BlueMark Innovations BV, Roel Schiphorst * Contributors: Tom Pittenger, Josh Henderson, Andrew Tridgell * Parts of this code are based on/copied from the Open Drone ID project https://github.com/opendroneid/opendroneid-core-c * * The code has been tested with the BlueMark DroneBeacon MAVLink transponder running this command in the ArduPlane folder: * sim_vehicle.py --console --map -A --serial1=uart:/dev/ttyUSB1:9600 * (and a DroneBeacon MAVLink transponder connected to ttyUSB1) * * See https://github.com/ArduPilot/ArduRemoteID for an open implementation of a transmitter module on serial * and DroneCAN */ #include "AP_OpenDroneID_config.h" #if AP_OPENDRONEID_ENABLED #include "AP_OpenDroneID.h" #include #include #include #include #include #include #include #include #include #include extern const AP_HAL::HAL &hal; const AP_Param::GroupInfo AP_OpenDroneID::var_info[] = { // @Param: ENABLE // @DisplayName: Enable ODID subsystem // @Description: Enable ODID subsystem // @Values: 0:Disabled,1:Enabled AP_GROUPINFO_FLAGS("ENABLE", 1, AP_OpenDroneID, _enable, 0, AP_PARAM_FLAG_ENABLE), // @Param: MAVPORT // @DisplayName: MAVLink serial port // @Description: Serial port number to send OpenDroneID MAVLink messages to. Can be -1 if using DroneCAN. // @Values: -1:Disabled,0:Serial0,1:Serial1,2:Serial2,3:Serial3,4:Serial4,5:Serial5,6:Serial6 AP_GROUPINFO("MAVPORT", 2, AP_OpenDroneID, _mav_port, -1), // @Param: CANDRIVER // @DisplayName: DroneCAN driver number // @Description: DroneCAN driver index, 0 to disable DroneCAN // @Values: 0:Disabled,1:Driver1,2:Driver2 AP_GROUPINFO("CANDRIVER", 3, AP_OpenDroneID, _can_driver, 0), // @Param: OPTIONS // @DisplayName: OpenDroneID options // @Description: Options for OpenDroneID subsystem // @Bitmask: 0:EnforceArming, 1:AllowNonGPSPosition, 2:LockUASIDOnFirstBasicIDRx AP_GROUPINFO("OPTIONS", 4, AP_OpenDroneID, _options, 0), // @Param: BARO_ACC // @DisplayName: Barometer vertical accuraacy // @Description: Barometer Vertical Accuracy when installed in the vehicle. Note this is dependent upon installation conditions and thus disabled by default // @Units: m // @User: Advanced AP_GROUPINFO("BARO_ACC", 5, AP_OpenDroneID, _baro_accuracy, -1.0), AP_GROUPEND }; #if defined(OPENDRONEID_UA_TYPE) // ensure the type is within the allowed range #if OPENDRONEID_UA_TYPE < 0 || OPENDRONEID_UA_TYPE > 15 #error "OPENDRONEID_UA_TYPE must be between 0 and 15" #endif #endif // constructor AP_OpenDroneID::AP_OpenDroneID() { #if CONFIG_HAL_BOARD == HAL_BOARD_SITL if (_singleton != nullptr) { AP_HAL::panic("OpenDroneID must be singleton"); } #endif _singleton = this; AP_Param::setup_object_defaults(this, var_info); } void AP_OpenDroneID::init() { if (_enable == 0) { return; } load_UAS_ID_from_persistent_memory(); _chan = mavlink_channel_t(gcs().get_channel_from_port_number(_mav_port)); _initialised = true; } void AP_OpenDroneID::load_UAS_ID_from_persistent_memory() { id_len = sizeof(id_str); size_t id_type_len = sizeof(id_type); size_t ua_type_len = sizeof(ua_type); if (hal.util->get_persistent_param_by_name("DID_UAS_ID", id_str, id_len) && hal.util->get_persistent_param_by_name("DID_UAS_ID_TYPE", id_type, id_type_len) && hal.util->get_persistent_param_by_name("DID_UA_TYPE", ua_type, ua_type_len)) { if (id_len && id_type_len && ua_type_len) { _options.set_and_save(_options.get() & ~LockUASIDOnFirstBasicIDRx); _options.notify(); GCS_SEND_TEXT(MAV_SEVERITY_INFO, "OpenDroneID: Locked UAS_ID: %s", id_str); } } else { id_len = 0; } } void AP_OpenDroneID::set_basic_id() { if (pkt_basic_id.id_type != MAV_ODID_ID_TYPE_NONE) { return; } if (id_len > 0) { // prepare basic id pkt uint8_t val = gcs().sysid_this_mav(); pkt_basic_id.target_system = val; pkt_basic_id.target_component = MAV_COMP_ID_ODID_TXRX_1; pkt_basic_id.id_type = atoi(id_type); pkt_basic_id.ua_type = atoi(ua_type); char buffer[21]; snprintf(buffer, sizeof(buffer), "%s", id_str); memcpy(pkt_basic_id.uas_id, buffer, sizeof(pkt_basic_id.uas_id)); } } void AP_OpenDroneID::get_persistent_params(ExpandingString &str) const { if ((pkt_basic_id.id_type == MAV_ODID_ID_TYPE_SERIAL_NUMBER) && (_options & LockUASIDOnFirstBasicIDRx) && id_len == 0) { GCS_SEND_TEXT(MAV_SEVERITY_CRITICAL, "OpenDroneID: ID is locked as %s", pkt_basic_id.uas_id); str.printf("DID_UAS_ID=%s\nDID_UAS_ID_TYPE=%u\nDID_UA_TYPE=%u\n", pkt_basic_id.uas_id, pkt_basic_id.id_type, pkt_basic_id.ua_type); } } // Perform the pre-arm checks and prevent arming if they are not satisifed // Except in the case of an in-flight reboot bool AP_OpenDroneID::pre_arm_check(char* failmsg, uint8_t failmsg_len) { WITH_SEMAPHORE(_sem); if (!option_enabled(Options::EnforceArming)) { return true; } if (pkt_basic_id.id_type == MAV_ODID_ID_TYPE_NONE) { strncpy(failmsg, "UA_TYPE required in BasicID", failmsg_len); return false; } if (pkt_system.operator_latitude == 0 && pkt_system.operator_longitude == 0) { strncpy(failmsg, "operator location must be set", failmsg_len); return false; } const uint32_t max_age_ms = 3000; const uint32_t now_ms = AP_HAL::millis(); if (last_arm_status_ms == 0 || now_ms - last_arm_status_ms > max_age_ms) { strncpy(failmsg, "ARM_STATUS not available", failmsg_len); return false; } if (last_system_ms == 0 || (now_ms - last_system_ms > max_age_ms && (now_ms - last_system_update_ms > max_age_ms))) { strncpy(failmsg, "SYSTEM not available", failmsg_len); return false; } if (arm_status.status != MAV_ODID_ARM_STATUS_GOOD_TO_ARM) { strncpy(failmsg, arm_status.error, failmsg_len); return false; } return true; } void AP_OpenDroneID::update() { if (_enable == 0) { return; } if ((pkt_basic_id.id_type == MAV_ODID_ID_TYPE_SERIAL_NUMBER) && (_options & LockUASIDOnFirstBasicIDRx) && id_len == 0 && !bootloader_flashed) { hal.util->flash_bootloader(); // reset the basic id on next set_basic_id call pkt_basic_id.id_type = MAV_ODID_ID_TYPE_NONE; bootloader_flashed = true; } set_basic_id(); const bool armed = hal.util->get_soft_armed(); if (armed && !_was_armed) { // use arm location as takeoff location AP::ahrs().get_location(_takeoff_location); } _was_armed = armed; send_dynamic_out(); send_static_out(); #if HAL_ENABLE_DRONECAN_DRIVERS uint8_t can_num_drivers = AP::can().get_num_drivers(); for (uint8_t i = 0; i < can_num_drivers; i++) { AP_DroneCAN *dronecan = AP_DroneCAN::get_dronecan(i); if (dronecan == nullptr) { continue; } if (dronecan->get_driver_index()+1 != _can_driver) { continue; } // send messages dronecan_send(dronecan); } #endif } // local payload space check which treats invalid channel as having space // needed to populate the message structures for the DroneCAN backend #define ODID_HAVE_PAYLOAD_SPACE(id) (_chan == MAV_CHAN_INVALID || HAVE_PAYLOAD_SPACE(_chan, id)) void AP_OpenDroneID::send_dynamic_out() { const uint32_t now = AP_HAL::millis(); if (now - _last_send_location_ms >= _mavlink_dynamic_period_ms && ODID_HAVE_PAYLOAD_SPACE(OPEN_DRONE_ID_LOCATION)) { _last_send_location_ms = now; send_location_message(); } // operator location needs to be sent at the same rate as location for FAA compliance if (now - _last_send_system_update_ms >= _mavlink_dynamic_period_ms && ODID_HAVE_PAYLOAD_SPACE(OPEN_DRONE_ID_SYSTEM_UPDATE)) { _last_send_system_update_ms = now; send_system_update_message(); } } void AP_OpenDroneID::send_static_out() { const uint32_t now_ms = AP_HAL::millis(); // we need to notify user if we lost the transmitter if (now_ms - last_arm_status_ms > 5000) { if (now_ms - last_lost_tx_ms > 5000) { last_lost_tx_ms = now_ms; GCS_SEND_TEXT(MAV_SEVERITY_WARNING, "ODID: lost transmitter"); } } else if (last_lost_tx_ms != 0) { // we're OK again last_lost_tx_ms = 0; GCS_SEND_TEXT(MAV_SEVERITY_INFO, "ODID: transmitter OK"); } // we need to notify user if we lost system msg with operator location if (now_ms - last_system_ms > 5000 && now_ms - last_lost_operator_msg_ms > 5000) { last_lost_operator_msg_ms = now_ms; GCS_SEND_TEXT(MAV_SEVERITY_WARNING, "ODID: lost operator location"); } const uint32_t msg_spacing_ms = _mavlink_static_period_ms / 4; if (now_ms - last_msg_send_ms >= msg_spacing_ms) { // allow update of channel during setup, this makes it easy to debug with a GCS _chan = mavlink_channel_t(gcs().get_channel_from_port_number(_mav_port)); bool sent_ok = false; switch (next_msg_to_send) { case NEXT_MSG_BASIC_ID: if (ODID_HAVE_PAYLOAD_SPACE(OPEN_DRONE_ID_BASIC_ID)) { send_basic_id_message(); sent_ok = true; } break; case NEXT_MSG_SYSTEM: if (ODID_HAVE_PAYLOAD_SPACE(OPEN_DRONE_ID_SYSTEM)) { send_system_message(); sent_ok = true; } break; case NEXT_MSG_SELF_ID: if (ODID_HAVE_PAYLOAD_SPACE(OPEN_DRONE_ID_SELF_ID)) { send_self_id_message(); sent_ok = true; } break; case NEXT_MSG_OPERATOR_ID: if (ODID_HAVE_PAYLOAD_SPACE(OPEN_DRONE_ID_OPERATOR_ID)) { send_operator_id_message(); sent_ok = true; } break; case NEXT_MSG_ENUM_END: break; } if (sent_ok) { last_msg_send_ms = now_ms; next_msg_to_send = next_msg((uint8_t(next_msg_to_send) + 1) % uint8_t(NEXT_MSG_ENUM_END)); } } } // The send_location_message // all open_drone_id send functions use data stored in the open drone id class. // This location send function is an exception. It uses live location data from the ArduPilot system. void AP_OpenDroneID::send_location_message() { auto &ahrs = AP::ahrs(); const auto &barometer = AP::baro(); const auto &gps = AP::gps(); const AP_GPS::GPS_Status gps_status = gps.status(); const bool got_bad_gps_fix = (gps_status < AP_GPS::GPS_Status::GPS_OK_FIX_3D); const bool armed = hal.util->get_soft_armed(); Location current_location; if (!ahrs.get_location(current_location)) { return; } uint8_t uav_status = hal.util->get_soft_armed()? MAV_ODID_STATUS_AIRBORNE : MAV_ODID_STATUS_GROUND; #if HAL_PARACHUTE_ENABLED // set emergency status if chute is released const auto *parachute = AP::parachute(); if (parachute != nullptr && parachute->released()) { uav_status = MAV_ODID_STATUS_EMERGENCY; } #endif if (AP::vehicle()->is_crashed()) { // if in crashed state also declare an emergency uav_status = MAV_ODID_STATUS_EMERGENCY; } // if we are armed with no GPS fix and we haven't specifically // allowed for non-GPS operation then declare an emergency if (got_bad_gps_fix && armed && !option_enabled(Options::AllowNonGPSPosition)) { uav_status = MAV_ODID_STATUS_EMERGENCY; } // if we are disarmed and falling at over 3m/s then declare an // emergency. This covers cases such as deliberate crash with // advanced failsafe and an unintended reboot or in-flight disarm if (!got_bad_gps_fix && !armed && gps.velocity().z > 3.0) { uav_status = MAV_ODID_STATUS_EMERGENCY; } // if we have watchdogged while armed then declare an emergency if (hal.util->was_watchdog_armed()) { uav_status = MAV_ODID_STATUS_EMERGENCY; } float direction = ODID_INV_DIR; if (!got_bad_gps_fix) { direction = wrap_360(degrees(ahrs.groundspeed_vector().angle())); // heading (degrees) } const float speed_horizontal = create_speed_horizontal(ahrs.groundspeed()); Vector3f velNED; UNUSED_RESULT(ahrs.get_velocity_NED(velNED)); const float climb_rate = create_speed_vertical(-velNED.z); //make sure climb_rate is within Remote ID limit int32_t latitude = 0; int32_t longitude = 0; if (current_location.check_latlng()) { //set location if they are valid latitude = current_location.lat; longitude = current_location.lng; } // altitude referenced against 1013.2mb const float base_press_mbar = 1013.2; const float altitude_barometric = create_altitude(barometer.get_altitude_difference(base_press_mbar*100, barometer.get_pressure())); float altitude_geodetic = -1000; int32_t alt_amsl_cm; float undulation; if (current_location.get_alt_cm(Location::AltFrame::ABSOLUTE, alt_amsl_cm)) { altitude_geodetic = alt_amsl_cm * 0.01; } if (gps.get_undulation(undulation)) { altitude_geodetic -= undulation; } // Compute the current height above the takeoff location float height_above_takeoff = 0; // height above takeoff (meters) if (hal.util->get_soft_armed()) { int32_t curr_alt_asml_cm; int32_t takeoff_alt_asml_cm; if (current_location.get_alt_cm(Location::AltFrame::ABSOLUTE, curr_alt_asml_cm) && _takeoff_location.get_alt_cm(Location::AltFrame::ABSOLUTE, takeoff_alt_asml_cm)) { height_above_takeoff = (curr_alt_asml_cm - takeoff_alt_asml_cm) * 0.01; } } // Accuracy // If we have GPS 3D lock we presume that the accuracies of the system will track the GPS's reported accuracy MAV_ODID_HOR_ACC horizontal_accuracy_mav = MAV_ODID_HOR_ACC_UNKNOWN; MAV_ODID_VER_ACC vertical_accuracy_mav = MAV_ODID_VER_ACC_UNKNOWN; MAV_ODID_SPEED_ACC speed_accuracy_mav = MAV_ODID_SPEED_ACC_UNKNOWN; MAV_ODID_TIME_ACC timestamp_accuracy_mav = MAV_ODID_TIME_ACC_UNKNOWN; float horizontal_accuracy; if (gps.horizontal_accuracy(horizontal_accuracy)) { horizontal_accuracy_mav = create_enum_horizontal_accuracy(horizontal_accuracy); } float vertical_accuracy; if (gps.vertical_accuracy(vertical_accuracy)) { vertical_accuracy_mav = create_enum_vertical_accuracy(vertical_accuracy); } float speed_accuracy; if (gps.speed_accuracy(speed_accuracy)) { speed_accuracy_mav = create_enum_speed_accuracy(speed_accuracy); } // if we have ever had GPS lock then we will have better than 1s // accuracy, as we use system timer to propogate time timestamp_accuracy_mav = create_enum_timestamp_accuracy(1.0); // Barometer altitude accuraacy will be highly dependent on the airframe and installation of the barometer in use // thus ArduPilot cannot reasonably fill this in. // Instead allow a manufacturer to use a parameter to fill this in uint8_t barometer_accuracy = MAV_ODID_VER_ACC_UNKNOWN; //ahrs class does not provide accuracy readings if (!is_equal(_baro_accuracy.get(), -1.0f)) { barometer_accuracy = create_enum_vertical_accuracy(_baro_accuracy); } // Timestamp here is the number of seconds after into the current hour referenced to UTC time (up to one hour) // FIX we need to only set this if w have a GPS lock is 2D good enough for that? float timestamp = ODID_INV_TIMESTAMP; if (!got_bad_gps_fix) { uint32_t time_week_ms = gps.time_week_ms(); timestamp = float(time_week_ms % (3600 * 1000)) * 0.001; timestamp = create_location_timestamp(timestamp); //make sure timestamp is within Remote ID limit } { WITH_SEMAPHORE(_sem); // take semaphore so CAN gets a consistent packet pkt_location = mavlink_open_drone_id_location_t{ latitude : latitude, longitude : longitude, altitude_barometric : altitude_barometric, altitude_geodetic : altitude_geodetic, height : height_above_takeoff, timestamp : timestamp, direction : uint16_t(direction * 100.0), // Heading (centi-degrees) speed_horizontal : uint16_t(speed_horizontal * 100.0), // Ground speed (cm/s) speed_vertical : int16_t(climb_rate * 100.0), // Climb rate (cm/s) target_system : 0, target_component : 0, id_or_mac : {}, status : uint8_t(uav_status), height_reference : MAV_ODID_HEIGHT_REF_OVER_TAKEOFF, // height reference enum: Above takeoff location or above ground horizontal_accuracy : uint8_t(horizontal_accuracy_mav), vertical_accuracy : uint8_t(vertical_accuracy_mav), barometer_accuracy : barometer_accuracy, speed_accuracy : uint8_t(speed_accuracy_mav), timestamp_accuracy : uint8_t(timestamp_accuracy_mav) }; need_send_location = dronecan_send_all; } if (_chan != MAV_CHAN_INVALID) { mavlink_msg_open_drone_id_location_send_struct(_chan, &pkt_location); } } void AP_OpenDroneID::send_basic_id_message() { // note that packet is filled in by the GCS need_send_basic_id |= dronecan_send_all; if (_chan != MAV_CHAN_INVALID) { mavlink_msg_open_drone_id_basic_id_send_struct(_chan, &pkt_basic_id); } } void AP_OpenDroneID::send_system_message() { // note that packet is filled in by the GCS need_send_system |= dronecan_send_all; if (_chan != MAV_CHAN_INVALID) { mavlink_msg_open_drone_id_system_send_struct(_chan, &pkt_system); } } void AP_OpenDroneID::send_self_id_message() { need_send_self_id |= dronecan_send_all; if (_chan != MAV_CHAN_INVALID) { mavlink_msg_open_drone_id_self_id_send_struct(_chan, &pkt_self_id); } } void AP_OpenDroneID::send_system_update_message() { need_send_system |= dronecan_send_all; // note that packet is filled in by the GCS if (_chan != MAV_CHAN_INVALID) { const auto pkt_system_update = mavlink_open_drone_id_system_update_t { operator_latitude : pkt_system.operator_latitude, operator_longitude : pkt_system.operator_longitude, operator_altitude_geo : pkt_system.operator_altitude_geo, timestamp : pkt_system.timestamp, target_system : pkt_system.target_system, target_component : pkt_system.target_component, }; mavlink_msg_open_drone_id_system_update_send_struct(_chan, &pkt_system_update); } } void AP_OpenDroneID::send_operator_id_message() { need_send_operator_id |= dronecan_send_all; // note that packet is filled in by the GCS if (_chan != MAV_CHAN_INVALID) { mavlink_msg_open_drone_id_operator_id_send_struct(_chan, &pkt_operator_id); } } /* * This converts a horizontal accuracy float value to the corresponding enum * * @param Accuracy The horizontal accuracy in meters * @return Enum value representing the accuracy */ MAV_ODID_HOR_ACC AP_OpenDroneID::create_enum_horizontal_accuracy(float accuracy) const { // Out of bounds return UKNOWN flag if (accuracy < 0.0 || accuracy >= 18520.0) { return MAV_ODID_HOR_ACC_UNKNOWN; } static const struct { float accuracy; // Accuracy bound in meters MAV_ODID_HOR_ACC mavoutput; // mavlink enum output } horiz_accuracy_table[] = { { 1.0, MAV_ODID_HOR_ACC_1_METER}, { 3.0, MAV_ODID_HOR_ACC_3_METER}, {10.0, MAV_ODID_HOR_ACC_10_METER}, {30.0, MAV_ODID_HOR_ACC_30_METER}, {92.6, MAV_ODID_HOR_ACC_0_05NM}, {185.2, MAV_ODID_HOR_ACC_0_1NM}, {555.6, MAV_ODID_HOR_ACC_0_3NM}, {926.0, MAV_ODID_HOR_ACC_0_5NM}, {1852.0, MAV_ODID_HOR_ACC_1NM}, {3704.0, MAV_ODID_HOR_ACC_2NM}, {7408.0, MAV_ODID_HOR_ACC_4NM}, {18520.0, MAV_ODID_HOR_ACC_10NM}, }; for (auto elem : horiz_accuracy_table) { if (accuracy < elem.accuracy) { return elem.mavoutput; } } // Should not reach this return MAV_ODID_HOR_ACC_UNKNOWN; } /** * This converts a vertical accuracy float value to the corresponding enum * * @param Accuracy The vertical accuracy in meters * @return Enum value representing the accuracy */ MAV_ODID_VER_ACC AP_OpenDroneID::create_enum_vertical_accuracy(float accuracy) const { // Out of bounds return UKNOWN flag if (accuracy < 0.0 || accuracy >= 150.0) { return MAV_ODID_VER_ACC_UNKNOWN; } static const struct { float accuracy; // Accuracy bound in meters MAV_ODID_VER_ACC mavoutput; // mavlink enum output } vertical_accuracy_table[] = { { 1.0, MAV_ODID_VER_ACC_1_METER}, { 3.0, MAV_ODID_VER_ACC_3_METER}, {10.0, MAV_ODID_VER_ACC_10_METER}, {25.0, MAV_ODID_VER_ACC_25_METER}, {45.0, MAV_ODID_VER_ACC_45_METER}, {150.0, MAV_ODID_VER_ACC_150_METER}, }; for (auto elem : vertical_accuracy_table) { if (accuracy < elem.accuracy) { return elem.mavoutput; } } // Should not reach this return MAV_ODID_VER_ACC_UNKNOWN; } /** * This converts a speed accuracy float value to the corresponding enum * * @param Accuracy The speed accuracy in m/s * @return Enum value representing the accuracy */ MAV_ODID_SPEED_ACC AP_OpenDroneID::create_enum_speed_accuracy(float accuracy) const { // Out of bounds return UKNOWN flag if (accuracy < 0.0 || accuracy >= 10.0) { return MAV_ODID_SPEED_ACC_UNKNOWN; } if (accuracy < 0.3) { return MAV_ODID_SPEED_ACC_0_3_METERS_PER_SECOND; } else if (accuracy < 1.0) { return MAV_ODID_SPEED_ACC_1_METERS_PER_SECOND; } else if (accuracy < 3.0) { return MAV_ODID_SPEED_ACC_3_METERS_PER_SECOND; } else if (accuracy < 10.0) { return MAV_ODID_SPEED_ACC_10_METERS_PER_SECOND; } // Should not reach this return MAV_ODID_SPEED_ACC_UNKNOWN; } /** * This converts a timestamp accuracy float value to the corresponding enum * * @param Accuracy The timestamp accuracy in seconds * @return Enum value representing the accuracy */ MAV_ODID_TIME_ACC AP_OpenDroneID::create_enum_timestamp_accuracy(float accuracy) const { // Out of bounds return UKNOWN flag if (accuracy < 0.0 || accuracy >= 1.5) { return MAV_ODID_TIME_ACC_UNKNOWN; } static const MAV_ODID_TIME_ACC mavoutput [15] = { MAV_ODID_TIME_ACC_0_1_SECOND, MAV_ODID_TIME_ACC_0_2_SECOND, MAV_ODID_TIME_ACC_0_3_SECOND, MAV_ODID_TIME_ACC_0_4_SECOND, MAV_ODID_TIME_ACC_0_5_SECOND, MAV_ODID_TIME_ACC_0_6_SECOND, MAV_ODID_TIME_ACC_0_7_SECOND, MAV_ODID_TIME_ACC_0_8_SECOND, MAV_ODID_TIME_ACC_0_9_SECOND, MAV_ODID_TIME_ACC_1_0_SECOND, MAV_ODID_TIME_ACC_1_1_SECOND, MAV_ODID_TIME_ACC_1_2_SECOND, MAV_ODID_TIME_ACC_1_3_SECOND, MAV_ODID_TIME_ACC_1_4_SECOND, MAV_ODID_TIME_ACC_1_5_SECOND, }; for (int8_t i = 1; i <= 15; i++) { if (accuracy <= 0.1 * i) { return mavoutput[i-1]; } } // Should not reach this return MAV_ODID_TIME_ACC_UNKNOWN; } // make sure value is within limits of remote ID standard uint16_t AP_OpenDroneID::create_speed_horizontal(uint16_t speed) const { if (speed > ODID_MAX_SPEED_H) { // constraint function can't be used, because out of range value is invalid speed = ODID_INV_SPEED_H; } return speed; } // make sure value is within limits of remote ID standard int16_t AP_OpenDroneID::create_speed_vertical(int16_t speed) const { if (speed > ODID_MAX_SPEED_V) { // constraint function can't be used, because out of range value is invalid speed = ODID_INV_SPEED_V; } else if (speed < ODID_MIN_SPEED_V) { speed = ODID_INV_SPEED_V; } return speed; } // make sure value is within limits of remote ID standard float AP_OpenDroneID::create_altitude(float altitude) const { if (altitude > ODID_MAX_ALT) { // constraint function can't be used, because out of range value is invalid altitude = ODID_INV_ALT; } else if (altitude < ODID_MIN_ALT) { altitude = ODID_INV_ALT; } return altitude; } // make sure value is within limits of remote ID standard float AP_OpenDroneID::create_location_timestamp(float timestamp) const { if (timestamp > ODID_MAX_TIMESTAMP) { // constraint function can't be used, because out of range value is invalid timestamp = ODID_INV_TIMESTAMP; } else if (timestamp < 0) { timestamp = ODID_INV_TIMESTAMP; } return timestamp; } // handle a message from the GCS void AP_OpenDroneID::handle_msg(mavlink_channel_t chan, const mavlink_message_t &msg) { if (!_initialised) { return; } WITH_SEMAPHORE(_sem); switch (msg.msgid) { // only accept ARM_STATUS from the transmitter case MAVLINK_MSG_ID_OPEN_DRONE_ID_ARM_STATUS: { if (chan == _chan) { mavlink_msg_open_drone_id_arm_status_decode(&msg, &arm_status); last_arm_status_ms = AP_HAL::millis(); } break; } // accept other messages from the GCS case MAVLINK_MSG_ID_OPEN_DRONE_ID_OPERATOR_ID: mavlink_msg_open_drone_id_operator_id_decode(&msg, &pkt_operator_id); break; case MAVLINK_MSG_ID_OPEN_DRONE_ID_SELF_ID: mavlink_msg_open_drone_id_self_id_decode(&msg, &pkt_self_id); break; case MAVLINK_MSG_ID_OPEN_DRONE_ID_BASIC_ID: if (id_len == 0) { mavlink_msg_open_drone_id_basic_id_decode(&msg, &pkt_basic_id); } break; case MAVLINK_MSG_ID_OPEN_DRONE_ID_SYSTEM: mavlink_msg_open_drone_id_system_decode(&msg, &pkt_system); last_system_ms = AP_HAL::millis(); break; case MAVLINK_MSG_ID_OPEN_DRONE_ID_SYSTEM_UPDATE: { mavlink_open_drone_id_system_update_t pkt_system_update; mavlink_msg_open_drone_id_system_update_decode(&msg, &pkt_system_update); pkt_system.operator_latitude = pkt_system_update.operator_latitude; pkt_system.operator_longitude = pkt_system_update.operator_longitude; pkt_system.operator_altitude_geo = pkt_system_update.operator_altitude_geo; pkt_system.timestamp = pkt_system_update.timestamp; last_system_update_ms = AP_HAL::millis(); if (last_system_ms != 0) { // we can only mark system as updated if we have the other // information already last_system_ms = last_system_update_ms; } break; } } } // singleton instance AP_OpenDroneID *AP_OpenDroneID::_singleton; namespace AP { AP_OpenDroneID &opendroneid() { return *AP_OpenDroneID::get_singleton(); } } #endif //AP_OPENDRONEID_ENABLED