// -*- tab-width: 4; Mode: C++; c-basic-offset: 4; indent-tabs-mode: t -*- #if GCS_PROTOCOL == GCS_PROTOCOL_IMU // This is the standard GCS output file for ArduPilot /* Message Prefixes !!! Position Low rate telemetry +++ Attitude High rate telemetry ### Mode Change in control mode %%% Waypoint Current and previous waypoints XXX Alert Text alert - NOTE: Alert message generation is not localized to a function PPP IMU Performance Sent every 20 seconds for performance monitoring Message Suffix *** All messages use this suffix */ /* void acknowledge(byte id, byte check1, byte check2) {} void send_message(byte id) {} void send_message(byte id, long param) {} void send_message(byte severity, const char *str) {} */ void acknowledge(byte id, byte check1, byte check2) { } void send_message(byte id) { send_message(id,0l); } void send_message(byte id, long param) { switch(id) { case MSG_ATTITUDE: print_attitude(); break; case MSG_LOCATION: // ** Location/GPS message print_location(); break; } } void send_message(byte severity, const char *str) { if(severity >= DEBUG_LEVEL){ Serial.print("MSG: "); Serial.println(str); } } void print_current_waypoints() { } void print_control_mode(void) { } void print_attitude(void) { //Serial.print("!!!VER:"); //Serial.print(SOFTWARE_VER); //output the software version //Serial.print(","); // Analogs Serial.print("AN0:"); Serial.print(read_adc(0)); //Reversing the sign. Serial.print(",AN1:"); Serial.print(read_adc(1)); Serial.print(",AN2:"); Serial.print(read_adc(2)); Serial.print(",AN3:"); Serial.print(read_adc(3)); Serial.print (",AN4:"); Serial.print(read_adc(4)); Serial.print (",AN5:"); Serial.print(read_adc(5)); Serial.print (","); // DCM Serial.print ("EX0:"); Serial.print(convert_to_dec(DCM_Matrix[0][0])); Serial.print (",EX1:"); Serial.print(convert_to_dec(DCM_Matrix[0][1])); Serial.print (",EX2:"); Serial.print(convert_to_dec(DCM_Matrix[0][2])); Serial.print (",EX3:"); Serial.print(convert_to_dec(DCM_Matrix[1][0])); Serial.print (",EX4:"); Serial.print(convert_to_dec(DCM_Matrix[1][1])); Serial.print (",EX5:"); Serial.print(convert_to_dec(DCM_Matrix[1][2])); Serial.print (",EX6:"); Serial.print(convert_to_dec(DCM_Matrix[2][0])); Serial.print (",EX7:"); Serial.print(convert_to_dec(DCM_Matrix[2][1])); Serial.print (",EX8:"); Serial.print(convert_to_dec(DCM_Matrix[2][2])); Serial.print (","); // Euler Serial.print("RLL:"); Serial.print(ToDeg(roll)); Serial.print(",PCH:"); Serial.print(ToDeg(pitch)); Serial.print(",YAW:"); Serial.print(ToDeg(yaw)); Serial.print(",IMUH:"); Serial.print(((int)imu_health>>8)&0xff); Serial.print (","); /* #if USE_MAGNETOMETER == 1 Serial.print("MGX:"); Serial.print(magnetom_x); Serial.print (",MGY:"); Serial.print(magnetom_y); Serial.print (",MGZ:"); Serial.print(magnetom_z); Serial.print (",MGH:"); Serial.print(MAG_Heading); Serial.print (","); #endif */ //Serial.print("Temp:"); //Serial.print(temp_unfilt/20.0); // Convert into degrees C //alti(); //Serial.print(",Pressure: "); //Serial.print(press); //Serial.print(",Alt: "); //Serial.print(pressure_altitude/1000); // Original floating point full solution in meters //Serial.print (","); Serial.println("***"); } void print_location(void) { Serial.print("LAT:"); Serial.print(current_loc.lat); Serial.print(",LON:"); Serial.print(current_loc.lng); Serial.print(",ALT:"); Serial.print(current_loc.alt/100); // meters Serial.print(",COG:"); Serial.print(gps->ground_course); Serial.print(",SOG:"); Serial.print(gps->ground_speed); Serial.print(",FIX:"); Serial.print((int)gps->fix); Serial.print(",SAT:"); Serial.print((int)gps->num_sats); Serial.print (","); Serial.print("TOW:"); Serial.print(gps->time); Serial.println("***"); } void print_waypoints() { } void print_waypoint(struct Location *cmd,byte index) { Serial.print("command #: "); Serial.print(index, DEC); Serial.print(" id: "); Serial.print(cmd->id,DEC); Serial.print(" p1: "); Serial.print(cmd->p1,DEC); Serial.print(" p2: "); Serial.print(cmd->alt,DEC); Serial.print(" p3: "); Serial.print(cmd->lat,DEC); Serial.print(" p4: "); Serial.println(cmd->lng,DEC); } long convert_to_dec(float x) { return x*10000000; } #endif