/* This program is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see . */ /* Original C Code by Marvelmind (https://github.com/MarvelmindRobotics/marvelmind.c) Adapted into Ardupilot by Karthik Desai, Amilcar Lucas April 2017 */ #include "AP_Beacon_Marvelmind.h" #if AP_BEACON_MARVELMIND_ENABLED #include #include #define AP_BEACON_MARVELMIND_POSITION_DATAGRAM_ID 0x0001 #define AP_BEACON_MARVELMIND_POSITIONS_DATAGRAM_ID 0x0002 #define AP_BEACON_MARVELMIND_DISTANCES_DATAGRAM_ID 0x0004 #define AP_BEACON_MARVELMIND_POSITION_DATAGRAM_HIGHRES_ID 0x0011 #define AP_BEACON_MARVELMIND_POSITIONS_DATAGRAM_HIGHRES_ID 0x0012 extern const AP_HAL::HAL& hal; #define MM_DEBUG_LEVEL 0 #if MM_DEBUG_LEVEL #include #define Debug(level, fmt, args ...) do { if (level <= MM_DEBUG_LEVEL) { gcs().send_text(MAV_SEVERITY_INFO, fmt, ## args); } } while (0) #else #define Debug(level, fmt, args ...) #endif void AP_Beacon_Marvelmind::process_position_datagram() { hedge.cur_position.address = input_buffer[16]; hedge.cur_position.timestamp = input_buffer[5] | (((uint32_t) input_buffer[6]) << 8) | (((uint32_t) input_buffer[7]) << 16) | (((uint32_t) input_buffer[8]) << 24); const int16_t vx = input_buffer[9] | (((uint16_t) input_buffer[10]) << 8); hedge.cur_position.x__mm = vx * 10; // centimeters -> millimeters const int16_t vy = input_buffer[11] | (((uint16_t) input_buffer[12]) << 8); hedge.cur_position.y__mm = vy * 10; // centimeters -> millimeters const int16_t vz = input_buffer[13] | (((uint16_t) input_buffer[14]) << 8); hedge.cur_position.z__mm = vz * 10; // centimeters -> millimeters hedge.cur_position.high_resolution = false; hedge._have_new_values = true; } void AP_Beacon_Marvelmind::process_position_highres_datagram() { hedge.cur_position.address = input_buffer[22]; hedge.cur_position.timestamp = input_buffer[5] | (((uint32_t) input_buffer[6]) << 8) | (((uint32_t) input_buffer[7]) << 16) | (((uint32_t) input_buffer[8]) << 24); hedge.cur_position.x__mm = input_buffer[9] | (((uint32_t) input_buffer[10]) << 8) | (((uint32_t) input_buffer[11]) << 16) | (((uint32_t) input_buffer[12]) << 24); hedge.cur_position.y__mm = input_buffer[13] | (((uint32_t) input_buffer[14]) << 8) | (((uint32_t) input_buffer[15]) << 16) | (((uint32_t) input_buffer[16]) << 24); hedge.cur_position.z__mm = input_buffer[17] | (((uint32_t) input_buffer[18]) << 8) | (((uint32_t) input_buffer[19]) << 16) | (((uint32_t) input_buffer[20]) << 24); hedge.cur_position.high_resolution = true; hedge._have_new_values = true; } AP_Beacon_Marvelmind::StationaryBeaconPosition* AP_Beacon_Marvelmind::get_or_alloc_beacon(uint8_t address) { const uint8_t n_used = hedge.positions_beacons.num_beacons; for (uint8_t i = 0; i < n_used; i++) { if (hedge.positions_beacons.beacons[i].address == address) { return &hedge.positions_beacons.beacons[i]; } } if (n_used >= AP_BEACON_MAX_BEACONS) { return nullptr; } hedge.positions_beacons.num_beacons = (n_used + 1); return &hedge.positions_beacons.beacons[n_used]; } void AP_Beacon_Marvelmind::process_beacons_positions_datagram() { const uint8_t n = input_buffer[5]; // number of beacons in packet StationaryBeaconPosition *stationary_beacon; if ((1 + n * 8) != input_buffer[4]) { Debug(1, "beacon pos lo pkt size %d != %d", input_buffer[4], (1 + n * 8)); return; // incorrect size } for (uint8_t i = 0; i < n; i++) { const uint8_t ofs = 6 + i * 8; const uint8_t address = input_buffer[ofs]; const int16_t x = input_buffer[ofs + 1] | (((uint16_t) input_buffer[ofs + 2]) << 8); const int16_t y = input_buffer[ofs + 3] | (((uint16_t) input_buffer[ofs + 4]) << 8); const int16_t z = input_buffer[ofs + 5] | (((uint16_t) input_buffer[ofs + 6]) << 8); stationary_beacon = get_or_alloc_beacon(address); if (stationary_beacon != nullptr) { stationary_beacon->address = address; //The instance and the address are the same stationary_beacon->x__mm = x * 10; // centimeters -> millimeters stationary_beacon->y__mm = y * 10; // centimeters -> millimeters stationary_beacon->z__mm = z * 10; // centimeters -> millimeters stationary_beacon->high_resolution = false; hedge.positions_beacons.updated = true; } } order_stationary_beacons(); } void AP_Beacon_Marvelmind::process_beacons_positions_highres_datagram() { const uint8_t n = input_buffer[5]; // number of beacons in packet StationaryBeaconPosition *stationary_beacon; if ((1 + n * 14) != input_buffer[4]) { Debug(1, "beacon pos hi pkt size %d != %d", input_buffer[4], (1 + n * 14)); return; // incorrect size } for (uint8_t i = 0; i < n; i++) { const uint8_t ofs = 6 + i * 14; const uint8_t address = input_buffer[ofs]; const int32_t x = input_buffer[ofs + 1] | (((uint32_t) input_buffer[ofs + 2]) << 8) | (((uint32_t) input_buffer[ofs + 3]) << 16) | (((uint32_t) input_buffer[ofs + 4]) << 24); const int32_t y = input_buffer[ofs + 5] | (((uint32_t) input_buffer[ofs + 6]) << 8) | (((uint32_t) input_buffer[ofs + 7]) << 16) | (((uint32_t) input_buffer[ofs + 8]) << 24); const int32_t z = input_buffer[ofs + 9] | (((uint32_t) input_buffer[ofs + 10]) << 8) | (((uint32_t) input_buffer[ofs + 11]) << 16) | (((uint32_t) input_buffer[ofs + 12]) << 24); stationary_beacon = get_or_alloc_beacon(address); if (stationary_beacon != nullptr) { stationary_beacon->address = address; //The instance and the address are the same stationary_beacon->x__mm = x; // millimeters stationary_beacon->y__mm = y; // millimeters stationary_beacon->z__mm = z; // millimeters stationary_beacon->high_resolution = true; hedge.positions_beacons.updated = true; } } order_stationary_beacons(); } void AP_Beacon_Marvelmind::process_beacons_distances_datagram() { if (32 != input_buffer[4]) { Debug(1, "beacon dist pkt size %d != 32", input_buffer[4]); return; // incorrect size } bool set = false; for (uint8_t i = 0; i < hedge.positions_beacons.num_beacons; i++) { const uint8_t ofs = 6 + i * 6; const uint8_t address = input_buffer[ofs]; const int8_t instance = find_beacon_instance(address); if (instance != -1) { const uint32_t distance = input_buffer[ofs + 1] | (((uint32_t) input_buffer[ofs + 2]) << 8) | (((uint32_t) input_buffer[ofs + 3]) << 16) | (((uint32_t) input_buffer[ofs + 4]) << 24); hedge.positions_beacons.beacons[instance].distance__m = distance * 0.001f; // millimeters -> meters set_beacon_distance(instance, hedge.positions_beacons.beacons[instance].distance__m); set = true; Debug(2, "Beacon %d is %.2fm", instance, hedge.positions_beacons.beacons[instance].distance__m); } } if (set) { last_update_ms = AP_HAL::millis(); } } int8_t AP_Beacon_Marvelmind::find_beacon_instance(uint8_t address) const { for (uint8_t i = 0; i < hedge.positions_beacons.num_beacons; i++) { if (hedge.positions_beacons.beacons[i].address == address) { return i; } } return -1; } void AP_Beacon_Marvelmind::update(void) { if (uart == nullptr) { return; } // read any available characters int32_t num_bytes_read = uart->available(); uint8_t received_char = 0; if (num_bytes_read < 0) { return; } while (num_bytes_read-- > 0) { bool good_byte = false; received_char = uart->read(); input_buffer[num_bytes_in_block_received] = received_char; switch (parse_state) { case RECV_HDR: switch (num_bytes_in_block_received) { case 0: good_byte = (received_char == 0xff); break; case 1: good_byte = (received_char == 0x47); break; case 2: good_byte = true; break; case 3: data_id = (((uint16_t)received_char) << 8) + input_buffer[2]; good_byte = (data_id == AP_BEACON_MARVELMIND_POSITION_DATAGRAM_ID) || (data_id == AP_BEACON_MARVELMIND_POSITIONS_DATAGRAM_ID) || (data_id == AP_BEACON_MARVELMIND_DISTANCES_DATAGRAM_ID) || (data_id == AP_BEACON_MARVELMIND_POSITION_DATAGRAM_HIGHRES_ID) || (data_id == AP_BEACON_MARVELMIND_POSITIONS_DATAGRAM_HIGHRES_ID); break; case 4: { switch (data_id) { case AP_BEACON_MARVELMIND_POSITION_DATAGRAM_ID: { good_byte = (received_char == 0x10); break; } case AP_BEACON_MARVELMIND_DISTANCES_DATAGRAM_ID: case AP_BEACON_MARVELMIND_POSITIONS_DATAGRAM_ID: case AP_BEACON_MARVELMIND_POSITIONS_DATAGRAM_HIGHRES_ID: good_byte = true; break; case AP_BEACON_MARVELMIND_POSITION_DATAGRAM_HIGHRES_ID: { good_byte = (received_char == 0x16); break; } } if (good_byte) { parse_state = RECV_DGRAM; } break; } } if (good_byte) { // correct header byte num_bytes_in_block_received++; } else { // ...or incorrect parse_state = RECV_HDR; num_bytes_in_block_received = 0; } break; case RECV_DGRAM: num_bytes_in_block_received++; if (num_bytes_in_block_received >= 7 + input_buffer[4]) { // parse dgram uint16_t block_crc = calc_crc_modbus(input_buffer, num_bytes_in_block_received); if (block_crc == 0) { switch (data_id) { case AP_BEACON_MARVELMIND_POSITION_DATAGRAM_ID: { // add to position_buffer process_position_datagram(); vehicle_position_initialized = true; set_stationary_beacons_positions(); break; } case AP_BEACON_MARVELMIND_POSITIONS_DATAGRAM_ID: { process_beacons_positions_datagram(); beacon_position_initialized = true; set_stationary_beacons_positions(); break; } case AP_BEACON_MARVELMIND_DISTANCES_DATAGRAM_ID: { process_beacons_distances_datagram(); break; } case AP_BEACON_MARVELMIND_POSITION_DATAGRAM_HIGHRES_ID: { process_position_highres_datagram(); vehicle_position_initialized = true; set_stationary_beacons_positions(); break; } case AP_BEACON_MARVELMIND_POSITIONS_DATAGRAM_HIGHRES_ID: { process_beacons_positions_highres_datagram(); beacon_position_initialized = true; set_stationary_beacons_positions(); break; } } } // and repeat parse_state = RECV_HDR; num_bytes_in_block_received = 0; } break; } } } bool AP_Beacon_Marvelmind::healthy() { // healthy if we have parsed a message within the past 300ms return ((AP_HAL::millis() - last_update_ms) < AP_BEACON_TIMEOUT_MS); } void AP_Beacon_Marvelmind::set_stationary_beacons_positions() { bool set = false; if (vehicle_position_initialized && beacon_position_initialized) { if (hedge._have_new_values) { vehicle_position_NED__m = Vector3f(hedge.cur_position.y__mm * 0.001f, hedge.cur_position.x__mm * 0.001f, -hedge.cur_position.z__mm * 0.001f); //Transform Marvelmind ENU to Ardupilot NED //TODO: Calculate Accuracy of the received signal. Marvelmind *advertises* +/- 2cms // But we are conservative here and use 20cm instead (until MM provides us with a proper accuracy value) set_vehicle_position(vehicle_position_NED__m, 0.2f); set = true; Debug(2, "Hedge is at N%.2f, E%.2f, D%.2f", vehicle_position_NED__m[0], vehicle_position_NED__m[1], vehicle_position_NED__m[2]); } hedge._have_new_values = false; for (uint8_t i = 0; i < hedge.positions_beacons.num_beacons; ++i) { if (hedge.positions_beacons.updated) { beacon_position_NED__m[i] = Vector3f(hedge.positions_beacons.beacons[i].y__mm * 0.001f, hedge.positions_beacons.beacons[i].x__mm * 0.001f, -hedge.positions_beacons.beacons[i].z__mm * 0.001f); //Transform Marvelmind ENU to Ardupilot NED set_beacon_position(i, beacon_position_NED__m[i]); set = true; Debug(2, "Beacon %d is at N%.2f, E%.2f, D%.2f", i, beacon_position_NED__m[i][0], beacon_position_NED__m[i][1], beacon_position_NED__m[i][2]); } } hedge.positions_beacons.updated = false; } if (set) { last_update_ms = AP_HAL::millis(); } } void AP_Beacon_Marvelmind::order_stationary_beacons() { if (hedge.positions_beacons.updated) { bool swapped = false; uint8_t j = hedge.positions_beacons.num_beacons; do { swapped = false; StationaryBeaconPosition beacon_to_swap; for (uint8_t i = 1; i < j; i++) { if (hedge.positions_beacons.beacons[i-1].address > hedge.positions_beacons.beacons[i].address) { beacon_to_swap = hedge.positions_beacons.beacons[i]; hedge.positions_beacons.beacons[i] = hedge.positions_beacons.beacons[i-1]; hedge.positions_beacons.beacons[i-1] = beacon_to_swap; swapped = true; } } j--; } while(swapped); } } #endif // AP_BEACON_MARVELMIND_ENABLED