/* 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 . */ /* simulate GPS sensors Usage example: param set SERIAL5_PROTOCOL 5 sim_vehicle.py -D --console --map -A --serial5=sim:gps:2 */ #pragma once #include "SIM_config.h" #if HAL_SIM_GPS_ENABLED #include "SIM_SerialDevice.h" namespace SITL { // for delay simulation: struct GPS_Data { uint32_t timestamp_ms; double latitude; double longitude; float altitude; double speedN; double speedE; double speedD; double yaw_deg; double roll_deg; double pitch_deg; bool have_lock; float horizontal_acc; float vertical_acc; float speed_acc; uint8_t num_sats; // Get course over ground [rad], where 0 = North in WGS-84 coordinate system. // Calculated from 2D velocity. float ground_track_rad() const WARN_IF_UNUSED; // Get 2D speed [m/s] in WGS-84 coordinate system float speed_2d() const WARN_IF_UNUSED; }; class GPS_Backend { public: CLASS_NO_COPY(GPS_Backend); GPS_Backend(class GPS &front, uint8_t _instance); virtual ~GPS_Backend() {} // 0 baud means "unset" i.e. baud-rate checks should not apply virtual uint32_t device_baud() const { return 0; } ssize_t write_to_autopilot(const char *p, size_t size) const; ssize_t read_from_autopilot(char *buffer, size_t size) const; // read and process config from autopilot (e.g.) virtual void update_read(); // writing fix information to autopilot (e.g.) virtual void publish(const GPS_Data *d) = 0; struct GPS_TOW { // Number of weeks since midnight 5-6 January 1980 uint16_t week; // Time since start of the GPS week [mS] uint32_t ms; }; static GPS_TOW gps_time(); protected: uint8_t instance; GPS &front; class SIM *_sitl; static void simulation_timeval(struct timeval *tv); }; class GPS : public SerialDevice { public: CLASS_NO_COPY(GPS); enum Type { NONE = 0, #if AP_SIM_GPS_UBLOX_ENABLED UBLOX = 1, #endif #if AP_SIM_GPS_NMEA_ENABLED NMEA = 5, #endif #if AP_SIM_GPS_SBP_ENABLED SBP = 6, #endif #if AP_SIM_GPS_FILE_ENABLED FILE = 7, #endif #if AP_SIM_GPS_NOVA_ENABLED NOVA = 8, #endif #if AP_SIM_GPS_SBP2_ENABLED SBP2 = 9, #endif #if AP_SIM_GPS_TRIMBLE_ENABLED TRIMBLE = 11, // matches GPS_TYPE #endif #if AP_SIM_GPS_MSP_ENABLED MSP = 19, #endif }; GPS(uint8_t _instance); // update state void update(); ssize_t write_to_autopilot(const char *p, size_t size) const override; uint32_t device_baud() const override; // 0 meaning unset private: uint8_t instance; // The last time GPS data was written [mS] uint32_t last_write_update_ms; // last 20 samples, allowing for up to 20 samples of delay GPS_Data _gps_history[20]; // state of jamming simulation struct { uint32_t last_jam_ms; uint32_t jam_start_ms; uint32_t last_sats_change_ms; uint32_t last_vz_change_ms; uint32_t last_vel_change_ms; uint32_t last_pos_change_ms; uint32_t last_acc_change_ms; double latitude; double longitude; } jamming[2]; bool _gps_has_basestation_position; GPS_Data _gps_basestation_data; void simulate_jamming(GPS_Data &d); // get delayed data GPS_Data interpolate_data(const GPS_Data &d, uint32_t delay_ms); uint8_t allocated_type; GPS_Backend *backend; void check_backend_allocation(); }; } #endif // HAL_SIM_GPS_ENABLED