// -*- tab-width: 4; Mode: C++; c-basic-offset: 4; indent-tabs-mode: nil -*- // Functions called from the setup menu static int8_t setup_radio (uint8_t argc, const Menu::arg *argv); static int8_t setup_motors (uint8_t argc, const Menu::arg *argv); static int8_t setup_accel (uint8_t argc, const Menu::arg *argv); static int8_t setup_factory (uint8_t argc, const Menu::arg *argv); static int8_t setup_erase (uint8_t argc, const Menu::arg *argv); static int8_t setup_flightmodes (uint8_t argc, const Menu::arg *argv); static int8_t setup_pid (uint8_t argc, const Menu::arg *argv); static int8_t setup_frame (uint8_t argc, const Menu::arg *argv); static int8_t setup_current (uint8_t argc, const Menu::arg *argv); static int8_t setup_sonar (uint8_t argc, const Menu::arg *argv); static int8_t setup_compass (uint8_t argc, const Menu::arg *argv); static int8_t setup_declination (uint8_t argc, const Menu::arg *argv); static int8_t setup_show (uint8_t argc, const Menu::arg *argv); // Command/function table for the setup menu const struct Menu::command setup_menu_commands[] PROGMEM = { // command function called // ======= =============== {"erase", setup_erase}, {"reset", setup_factory}, {"pid", setup_pid}, {"radio", setup_radio}, {"motors", setup_motors}, {"level", setup_accel}, {"modes", setup_flightmodes}, {"frame", setup_frame}, {"current", setup_current}, {"sonar", setup_sonar}, {"compass", setup_compass}, {"declination", setup_declination}, {"show", setup_show} }; // Create the setup menu object. MENU(setup_menu, "setup", setup_menu_commands); // Called from the top-level menu to run the setup menu. int8_t setup_mode(uint8_t argc, const Menu::arg *argv) { // Give the user some guidance Serial.printf_P(PSTR("Setup Mode\n")); //"\n" //"IMPORTANT: if you have not previously set this system up, use the\n" //"'reset' command to initialize the EEPROM to sensible default values\n" //"and then the 'radio' command to configure for your radio.\n" //"\n")); if(g.rc_1.radio_min >= 1300){ delay(1000); Serial.printf_P(PSTR("\n!!!Warning, your radio is not configured!!!")); delay(1000); Serial.printf_P(PSTR("\n Type 'radio' to configure now.\n\n")); } // Run the setup menu. When the menu exits, we will return to the main menu. setup_menu.run(); } // Print the current configuration. // Called by the setup menu 'show' command. static int8_t setup_show(uint8_t argc, const Menu::arg *argv) { uint8_t i; // clear the area print_blanks(8); report_version(); report_radio(); report_frame(); report_current(); report_sonar(); report_gains(); report_xtrack(); report_throttle(); report_flight_modes(); report_imu(); report_compass(); AP_Var_menu_show(argc, argv); return(0); } // Initialise the EEPROM to 'factory' settings (mostly defined in APM_Config.h or via defaults). // Called by the setup menu 'factoryreset' command. static int8_t setup_factory(uint8_t argc, const Menu::arg *argv) { uint8_t i; int c; Serial.printf_P(PSTR("\n'Y' + Enter to factory reset, any other key to abort:\n")); do { c = Serial.read(); } while (-1 == c); if (('y' != c) && ('Y' != c)) return(-1); AP_Var::erase_all(); Serial.printf_P(PSTR("\nFACTORY RESET complete - reboot APM")); delay(1000); default_log_bitmask(); default_gains(); for (;;) { } // note, cannot actually return here return(0); } // Perform radio setup. // Called by the setup menu 'radio' command. static int8_t setup_radio(uint8_t argc, const Menu::arg *argv) { Serial.println("\n\nRadio Setup:"); uint8_t i; for(i = 0; i < 100;i++){ delay(20); read_radio(); } if(g.rc_1.radio_in < 500){ while(1){ //Serial.printf_P(PSTR("\nNo radio; Check connectors.")); delay(1000); // stop here } } g.rc_1.radio_min = g.rc_1.radio_in; g.rc_2.radio_min = g.rc_2.radio_in; g.rc_3.radio_min = g.rc_3.radio_in; g.rc_4.radio_min = g.rc_4.radio_in; g.rc_5.radio_min = g.rc_5.radio_in; g.rc_6.radio_min = g.rc_6.radio_in; g.rc_7.radio_min = g.rc_7.radio_in; g.rc_8.radio_min = g.rc_8.radio_in; g.rc_1.radio_max = g.rc_1.radio_in; g.rc_2.radio_max = g.rc_2.radio_in; g.rc_3.radio_max = g.rc_3.radio_in; g.rc_4.radio_max = g.rc_4.radio_in; g.rc_5.radio_max = g.rc_5.radio_in; g.rc_6.radio_max = g.rc_6.radio_in; g.rc_7.radio_max = g.rc_7.radio_in; g.rc_8.radio_max = g.rc_8.radio_in; g.rc_1.radio_trim = g.rc_1.radio_in; g.rc_2.radio_trim = g.rc_2.radio_in; g.rc_4.radio_trim = g.rc_4.radio_in; // 3 is not trimed g.rc_5.radio_trim = 1500; g.rc_6.radio_trim = 1500; g.rc_7.radio_trim = 1500; g.rc_8.radio_trim = 1500; Serial.printf_P(PSTR("\nMove all controls to each extreme. Hit Enter to save: ")); while(1){ delay(20); // Filters radio input - adjust filters in the radio.pde file // ---------------------------------------------------------- read_radio(); g.rc_1.update_min_max(); g.rc_2.update_min_max(); g.rc_3.update_min_max(); g.rc_4.update_min_max(); g.rc_5.update_min_max(); g.rc_6.update_min_max(); g.rc_7.update_min_max(); g.rc_8.update_min_max(); if(Serial.available() > 0){ delay(20); Serial.flush(); save_EEPROM_radio(); print_done(); break; } } report_radio(); return(0); } static int8_t setup_motors(uint8_t argc, const Menu::arg *argv) { report_frame(); init_rc_in(); // read the radio to set trims // --------------------------- trim_radio(); print_hit_enter(); delay(1000); int out_min = g.rc_3.radio_min + 70; while(1){ delay(20); read_radio(); motor_out[CH_1] = g.rc_3.radio_min; motor_out[CH_2] = g.rc_3.radio_min; motor_out[CH_3] = g.rc_3.radio_min; motor_out[CH_4] = g.rc_3.radio_min; if(g.frame_type == PLUS_FRAME){ if(g.rc_1.control_in > 0){ motor_out[CH_1] = out_min; Serial.println("0"); }else if(g.rc_1.control_in < 0){ motor_out[CH_2] = out_min; Serial.println("1"); } if(g.rc_2.control_in > 0){ motor_out[CH_4] = out_min; Serial.println("3"); }else if(g.rc_2.control_in < 0){ motor_out[CH_3] = out_min; Serial.println("2"); } }else if(g.frame_type == X_FRAME){ // lower right if((g.rc_1.control_in > 0) && (g.rc_2.control_in > 0)){ motor_out[CH_4] = out_min; Serial.println("3"); // lower left }else if((g.rc_1.control_in < 0) && (g.rc_2.control_in > 0)){ motor_out[CH_2] = out_min; Serial.println("1"); // upper left }else if((g.rc_1.control_in < 0) && (g.rc_2.control_in < 0)){ motor_out[CH_3] = out_min; Serial.println("2"); // upper right }else if((g.rc_1.control_in > 0) && (g.rc_2.control_in < 0)){ motor_out[CH_1] = out_min; Serial.println("0"); } }else if(g.frame_type == TRI_FRAME){ if(g.rc_1.control_in > 0){ motor_out[CH_1] = out_min; }else if(g.rc_1.control_in < 0){ motor_out[CH_2] = out_min; } if(g.rc_2.control_in > 0){ motor_out[CH_4] = out_min; } if(g.rc_4.control_in > 0){ g.rc_4.servo_out = 2000; }else if(g.rc_4.control_in < 0){ g.rc_4.servo_out = -2000; } g.rc_4.calc_pwm(); motor_out[CH_3] = g.rc_4.radio_out; } if(g.rc_3.control_in > 0){ APM_RC.OutputCh(CH_1, g.rc_3.radio_in); APM_RC.OutputCh(CH_2, g.rc_3.radio_in); APM_RC.OutputCh(CH_3, g.rc_3.radio_in); if(g.frame_type != TRI_FRAME) APM_RC.OutputCh(CH_4, g.rc_3.radio_in); }else{ APM_RC.OutputCh(CH_1, motor_out[CH_1]); APM_RC.OutputCh(CH_2, motor_out[CH_2]); APM_RC.OutputCh(CH_3, motor_out[CH_3]); APM_RC.OutputCh(CH_4, motor_out[CH_4]); } if(Serial.available() > 0){ return (0); } } } static int8_t setup_accel(uint8_t argc, const Menu::arg *argv) { //Serial.printf_P(PSTR("\nHold ArduCopter completely still and level.\n")); imu.init_accel(); print_accel_offsets(); report_imu(); return(0); } static int8_t setup_pid(uint8_t argc, const Menu::arg *argv) { if (!strcmp_P(argv[1].str, PSTR("default"))) { default_gains(); }else if (!strcmp_P(argv[1].str, PSTR("stabilize"))) { g.pid_stabilize_roll.kP(argv[2].f); g.pid_stabilize_pitch.kP(argv[2].f); g.stabilize_dampener.set_and_save(argv[3].f); g.pid_stabilize_roll.save_gains(); g.pid_stabilize_pitch.save_gains(); }else if (!strcmp_P(argv[1].str, PSTR("yaw"))) { g.pid_yaw.kP(argv[2].f); g.pid_yaw.save_gains(); g.hold_yaw_dampener.set_and_save(argv[3].f); }else if (!strcmp_P(argv[1].str, PSTR("nav"))) { g.pid_nav_lat.kP(argv[2].f); g.pid_nav_lat.kI(argv[3].f); g.pid_nav_lat.imax(argv[4].i); g.pid_nav_lon.kP(argv[2].f); g.pid_nav_lon.kI(argv[3].f); g.pid_nav_lon.imax(argv[4].i); g.pid_nav_lon.save_gains(); g.pid_nav_lat.save_gains(); }else if (!strcmp_P(argv[1].str, PSTR("baro"))) { g.pid_baro_throttle.kP(argv[2].f); g.pid_baro_throttle.kI(argv[3].f); g.pid_baro_throttle.kD(0); g.pid_baro_throttle.imax(argv[4].i); g.pid_baro_throttle.save_gains(); }else if (!strcmp_P(argv[1].str, PSTR("sonar"))) { g.pid_sonar_throttle.kP(argv[2].f); g.pid_sonar_throttle.kI(argv[3].f); g.pid_sonar_throttle.kD(argv[4].f); g.pid_sonar_throttle.imax(argv[5].i); g.pid_sonar_throttle.save_gains(); }else{ default_gains(); } report_gains(); } static int8_t setup_flightmodes(uint8_t argc, const Menu::arg *argv) { byte switchPosition, oldSwitchPosition, mode; Serial.printf_P(PSTR("\nMove RC toggle switch to each position to edit, move aileron stick to select modes.")); print_hit_enter(); trim_radio(); while(1){ delay(20); read_radio(); switchPosition = readSwitch(); // look for control switch change if (oldSwitchPosition != switchPosition){ mode = g.flight_modes[switchPosition]; mode = constrain(mode, 0, NUM_MODES-1); // update the user print_switch(switchPosition, mode); // Remember switch position oldSwitchPosition = switchPosition; } // look for stick input if (radio_input_switch() == true){ mode++; if(mode >= NUM_MODES) mode = 0; // save new mode g.flight_modes[switchPosition] = mode; // print new mode print_switch(switchPosition, mode); } // escape hatch if(Serial.available() > 0){ g.flight_modes.save(); print_done(); report_flight_modes(); return (0); } } } static int8_t setup_declination(uint8_t argc, const Menu::arg *argv) { compass.set_declination(radians(argv[1].f)); report_compass(); } static int8_t setup_erase(uint8_t argc, const Menu::arg *argv) { zero_eeprom(); return 0; } static int8_t setup_compass(uint8_t argc, const Menu::arg *argv) { if (!strcmp_P(argv[1].str, PSTR("on"))) { g.compass_enabled = true; init_compass(); } else if (!strcmp_P(argv[1].str, PSTR("off"))) { g.compass_enabled = false; }else{ Serial.printf_P(PSTR("\nOptions:[on,off]\n")); report_compass(); return 0; } g.compass_enabled.save(); report_compass(); return 0; } static int8_t setup_frame(uint8_t argc, const Menu::arg *argv) { if (!strcmp_P(argv[1].str, PSTR("+"))) { g.frame_type = PLUS_FRAME; } else if (!strcmp_P(argv[1].str, PSTR("x"))) { g.frame_type = X_FRAME; } else if (!strcmp_P(argv[1].str, PSTR("tri"))) { g.frame_type = TRI_FRAME; } else if (!strcmp_P(argv[1].str, PSTR("hexa"))) { g.frame_type = HEXA_FRAME; } else if (!strcmp_P(argv[1].str, PSTR("y6"))) { g.frame_type = Y6_FRAME; }else{ Serial.printf_P(PSTR("\nOptions:[+, x, tri, hexa, y6]\n")); report_frame(); return 0; } g.frame_type.save(); report_frame(); return 0; } static int8_t setup_current(uint8_t argc, const Menu::arg *argv) { if (!strcmp_P(argv[1].str, PSTR("on"))) { g.current_enabled.set_and_save(true); } else if (!strcmp_P(argv[1].str, PSTR("off"))) { g.current_enabled.set_and_save(false); } else if(argv[1].i > 10){ g.milliamp_hours.set_and_save(argv[1].i); }else{ Serial.printf_P(PSTR("\nOptions:[on, off, mAh]\n")); report_current(); return 0; } report_current(); return 0; } static int8_t setup_sonar(uint8_t argc, const Menu::arg *argv) { if (!strcmp_P(argv[1].str, PSTR("on"))) { g.sonar_enabled.set_and_save(true); } else if (!strcmp_P(argv[1].str, PSTR("off"))) { g.sonar_enabled.set_and_save(false); }else{ Serial.printf_P(PSTR("\nOptions:[on, off]\n")); report_sonar(); return 0; } report_sonar(); return 0; } /*static int8_t setup_mag_offset(uint8_t argc, const Menu::arg *argv) { Serial.printf_P(PSTR("\nRotate/Pitch/Roll your ArduCopter until the offset variables stop changing.\n")); print_hit_enter(); Serial.printf_P(PSTR("Starting in 3 secs.\n")); delay(3000); compass.init(); // Initialization compass.set_orientation(MAG_ORIENTATION); // set compass's orientation on aircraft //compass.set_offsets(0, 0, 0); // set offsets to account for surrounding interference //int counter = 0; float _min[3], _max[3], _offset[3]; while(1){ static float min[3], _max[3], offset[3]; if (millis() - fast_loopTimer > 100) { delta_ms_fast_loop = millis() - fast_loopTimer; fast_loopTimer = millis(); G_Dt = (float)delta_ms_fast_loop / 1000.f; compass.read(); compass.calculate(0, 0); // roll = 0, pitch = 0 for this example // capture min if(compass.mag_x < _min[0]) _min[0] = compass.mag_x; if(compass.mag_y < _min[1]) _min[1] = compass.mag_y; if(compass.mag_z < _min[2]) _min[2] = compass.mag_z; // capture max if(compass.mag_x > _max[0]) _max[0] = compass.mag_x; if(compass.mag_y > _max[1]) _max[1] = compass.mag_y; if(compass.mag_z > _max[2]) _max[2] = compass.mag_z; // calculate offsets offset[0] = -(_max[0] + _min[0]) / 2; offset[1] = -(_max[1] + _min[1]) / 2; offset[2] = -(_max[2] + _min[2]) / 2; // display all to user Serial.printf_P(PSTR("Heading: ")); Serial.print(ToDeg(compass.heading)); Serial.print(" \t("); Serial.print(compass.mag_x); Serial.print(","); Serial.print(compass.mag_y); Serial.print(","); Serial.print(compass.mag_z); Serial.print(")\t offsets("); Serial.print(offset[0]); Serial.print(","); Serial.print(offset[1]); Serial.print(","); Serial.print(offset[2]); Serial.println(")"); if(Serial.available() > 0){ //mag_offset_x = offset[0]; //mag_offset_y = offset[1]; //mag_offset_z = offset[2]; //setup_mag_offset(); // set offsets to account for surrounding interference //compass.set_offsets(mag_offset_x, mag_offset_y, mag_offset_z); report_compass(); break; } } } } */ /***************************************************************************/ // CLI defaults /***************************************************************************/ void default_waypoint_info() { g.waypoint_radius = 4; //TODO: Replace this quick fix with a real way to define wp_radius g.loiter_radius = 30; //TODO: Replace this quick fix with a real way to define loiter_radius save_EEPROM_waypoint_info(); } void default_nav() { // nav control g.crosstrack_gain = XTRACK_GAIN * 100; g.crosstrack_entry_angle = XTRACK_ENTRY_ANGLE * 100; g.pitch_max = PITCH_MAX * 100; save_EEPROM_nav(); } void default_alt_hold() { g.RTL_altitude.set_and_save(-1); } void default_frame() { g.frame_type.set_and_save(PLUS_FRAME); } void default_current() { g.milliamp_hours = 2000; g.current_enabled.set(false); save_EEPROM_current(); } void default_flight_modes() { g.flight_modes[0] = FLIGHT_MODE_1; g.flight_modes[1] = FLIGHT_MODE_2; g.flight_modes[2] = FLIGHT_MODE_3; g.flight_modes[3] = FLIGHT_MODE_4; g.flight_modes[4] = FLIGHT_MODE_5; g.flight_modes[5] = FLIGHT_MODE_6; g.flight_modes.save(); } void default_throttle() { g.throttle_min = 0; g.throttle_max = 1000; g.throttle_cruise = 100; g.throttle_fs_enabled = THROTTLE_FAILSAFE; g.throttle_fs_action = THROTTLE_FAILSAFE_ACTION; g.throttle_fs_value = THROTTLE_FS_VALUE; save_EEPROM_throttle(); } void default_log_bitmask() { // convenience macro for testing LOG_* and setting LOGBIT_* #define LOGBIT(_s) (MASK_LOG_##_s ? MASK_LOG_##_s : 0) g.log_bitmask = LOGBIT(ATTITUDE_FAST) | LOGBIT(ATTITUDE_MED) | LOGBIT(GPS) | LOGBIT(PM) | LOGBIT(CTUN) | LOGBIT(NTUN) | LOGBIT(MODE) | LOGBIT(RAW) | LOGBIT(CMD) | LOGBIT(CUR); #undef LOGBIT g.log_bitmask.save(); } void default_gains() { // acro, angular rate g.pid_acro_rate_roll.kP(ACRO_RATE_ROLL_P); g.pid_acro_rate_roll.kI(ACRO_RATE_ROLL_I); g.pid_acro_rate_roll.kD(0); g.pid_acro_rate_roll.imax(ACRO_RATE_ROLL_IMAX * 100); g.pid_acro_rate_pitch.kP(ACRO_RATE_PITCH_P); g.pid_acro_rate_pitch.kI(ACRO_RATE_PITCH_I); g.pid_acro_rate_pitch.kD(0); g.pid_acro_rate_pitch.imax(ACRO_RATE_PITCH_IMAX * 100); g.pid_acro_rate_yaw.kP(ACRO_RATE_YAW_P); g.pid_acro_rate_yaw.kI(ACRO_RATE_YAW_I); g.pid_acro_rate_yaw.kD(0); g.pid_acro_rate_yaw.imax(ACRO_RATE_YAW_IMAX * 100); // stabilize, angle error g.pid_stabilize_roll.kP(STABILIZE_ROLL_P); g.pid_stabilize_roll.kI(STABILIZE_ROLL_I); g.pid_stabilize_roll.kD(0); g.pid_stabilize_roll.imax(STABILIZE_ROLL_IMAX * 100); g.pid_stabilize_pitch.kP(STABILIZE_PITCH_P); g.pid_stabilize_pitch.kI(STABILIZE_PITCH_I); g.pid_stabilize_pitch.kD(0); g.pid_stabilize_pitch.imax(STABILIZE_PITCH_IMAX * 100); // YAW hold g.pid_yaw.kP(YAW_P); g.pid_yaw.kI(YAW_I); g.pid_yaw.kD(0); g.pid_yaw.imax(YAW_IMAX * 100); // custom dampeners // roll pitch g.stabilize_dampener = STABILIZE_ROLL_D; //yaw g.hold_yaw_dampener = YAW_D; // navigation g.pid_nav_lat.kP(NAV_P); g.pid_nav_lat.kI(NAV_I); g.pid_nav_lat.kD(NAV_D); g.pid_nav_lat.imax(NAV_IMAX); g.pid_nav_lon.kP(NAV_P); g.pid_nav_lon.kI(NAV_I); g.pid_nav_lon.kD(NAV_D); g.pid_nav_lon.imax(NAV_IMAX); g.pid_baro_throttle.kP(THROTTLE_BARO_P); g.pid_baro_throttle.kI(THROTTLE_BARO_I); g.pid_baro_throttle.kD(THROTTLE_BARO_D); g.pid_baro_throttle.imax(THROTTLE_BARO_IMAX); g.pid_sonar_throttle.kP(THROTTLE_SONAR_P); g.pid_sonar_throttle.kI(THROTTLE_SONAR_I); g.pid_sonar_throttle.kD(THROTTLE_SONAR_D); g.pid_sonar_throttle.imax(THROTTLE_SONAR_IMAX); save_EEPROM_PID(); } /***************************************************************************/ // CLI reports /***************************************************************************/ void report_wp(byte index = 255) { if(index == 255){ for(byte i = 0; i <= g.waypoint_total; i++){ struct Location temp = get_wp_with_index(i); print_wp(&temp, i); } }else{ struct Location temp = get_wp_with_index(index); print_wp(&temp, index); } } void print_wp(struct Location *cmd, byte index) { Serial.printf_P(PSTR("command #: %d id:%d p1:%d p2:%ld p3:%ld p4:%ld \n"), (int)index, (int)cmd->id, (int)cmd->p1, cmd->alt, cmd->lat, cmd->lng); } void report_current() { //read_EEPROM_current(); Serial.printf_P(PSTR("Current \n")); print_divider(); print_enabled(g.current_enabled.get()); Serial.printf_P(PSTR("mah: %d"),(int)g.milliamp_hours.get()); print_blanks(2); } void report_gps() { Serial.printf_P(PSTR("\nGPS\n")); print_divider(); print_enabled(GPS_enabled); print_blanks(2); } void report_sonar() { g.sonar_enabled.load(); Serial.printf_P(PSTR("Sonar\n")); print_divider(); print_enabled(g.sonar_enabled.get()); print_blanks(2); } void report_version() { Serial.printf_P(PSTR("FW Version %d\n"),(int)g.format_version.get()); print_divider(); print_blanks(2); } void report_frame() { Serial.printf_P(PSTR("Frame\n")); print_divider(); if(g.frame_type == X_FRAME) Serial.printf_P(PSTR("X ")); else if(g.frame_type == PLUS_FRAME) Serial.printf_P(PSTR("Plus ")); else if(g.frame_type == TRI_FRAME) Serial.printf_P(PSTR("TRI ")); else if(g.frame_type == HEXA_FRAME) Serial.printf_P(PSTR("HEXA ")); else if(g.frame_type == Y6_FRAME) Serial.printf_P(PSTR("Y6 ")); Serial.printf_P(PSTR("frame (%d)"), (int)g.frame_type); print_blanks(2); } void report_radio() { Serial.printf_P(PSTR("Radio\n")); print_divider(); // radio //read_EEPROM_radio(); print_radio_values(); print_blanks(2); } void report_gains() { Serial.printf_P(PSTR("Gains\n")); print_divider(); //read_EEPROM_PID(); // Acro Serial.printf_P(PSTR("Acro:\nroll:\n")); print_PID(&g.pid_acro_rate_roll); Serial.printf_P(PSTR("pitch:\n")); print_PID(&g.pid_acro_rate_pitch); Serial.printf_P(PSTR("yaw:\n")); print_PID(&g.pid_acro_rate_yaw); // Stabilize Serial.printf_P(PSTR("\nStabilize:\nroll:\n")); print_PID(&g.pid_stabilize_roll); Serial.printf_P(PSTR("pitch:\n")); print_PID(&g.pid_stabilize_pitch); Serial.printf_P(PSTR("yaw:\n")); print_PID(&g.pid_yaw); Serial.printf_P(PSTR("Stab D: %4.3f\n"), (float)g.stabilize_dampener); Serial.printf_P(PSTR("Yaw D: %4.3f\n\n"), (float)g.hold_yaw_dampener); // Nav Serial.printf_P(PSTR("Nav:\nlat:\n")); print_PID(&g.pid_nav_lat); Serial.printf_P(PSTR("long:\n")); print_PID(&g.pid_nav_lon); Serial.printf_P(PSTR("baro throttle:\n")); print_PID(&g.pid_baro_throttle); Serial.printf_P(PSTR("sonar throttle:\n")); print_PID(&g.pid_sonar_throttle); print_blanks(2); } void report_xtrack() { Serial.printf_P(PSTR("XTrack\n")); print_divider(); // radio //read_EEPROM_nav(); Serial.printf_P(PSTR("XTRACK: %4.2f\n" "XTRACK angle: %d\n" "PITCH_MAX: %ld"), (float)g.crosstrack_gain, (int)g.crosstrack_entry_angle, (long)g.pitch_max); print_blanks(2); } void report_throttle() { Serial.printf_P(PSTR("Throttle\n")); print_divider(); //read_EEPROM_throttle(); Serial.printf_P(PSTR("min: %d\n" "max: %d\n" "cruise: %d\n" "failsafe_enabled: %d\n" "failsafe_value: %d"), (int)g.throttle_min, (int)g.throttle_max, (int)g.throttle_cruise, (int)g.throttle_fs_enabled, (int)g.throttle_fs_value); print_blanks(2); } void report_imu() { Serial.printf_P(PSTR("IMU\n")); print_divider(); print_gyro_offsets(); print_accel_offsets(); print_blanks(2); } void report_compass() { Serial.printf_P(PSTR("Compass\n")); print_divider(); print_enabled(g.compass_enabled); // mag declination Serial.printf_P(PSTR("Mag Dec: %4.4f\n"), degrees(compass.get_declination())); Vector3f offsets = compass.get_offsets(); // mag offsets Serial.printf_P(PSTR("Mag offsets: %4.4f, %4.4f, %4.4f"), offsets.x, offsets.y, offsets.z); print_blanks(2); } void report_flight_modes() { Serial.printf_P(PSTR("Flight modes\n")); print_divider(); for(int i = 0; i < 6; i++ ){ print_switch(i, g.flight_modes[i]); } print_blanks(2); } /***************************************************************************/ // CLI utilities /***************************************************************************/ void print_PID(PID * pid) { Serial.printf_P(PSTR("P: %4.3f, I:%4.3f, D:%4.3f, IMAX:%ld\n"), pid->kP(), pid->kI(), pid->kD(), (long)pid->imax()); } void print_radio_values() { /*Serial.printf_P(PSTR( "CH1: %d | %d\n" "CH2: %d | %d\n" "CH3: %d | %d\n" "CH4: %d | %d\n" "CH5: %d | %d\n" "CH6: %d | %d\n" "CH7: %d | %d\n" "CH8: %d | %d\n"), g.rc_1.radio_min, g.rc_1.radio_max, g.rc_2.radio_min, g.rc_2.radio_max, g.rc_3.radio_min, g.rc_3.radio_max, g.rc_4.radio_min, g.rc_4.radio_max, g.rc_5.radio_min, g.rc_5.radio_max, g.rc_6.radio_min, g.rc_6.radio_max, g.rc_7.radio_min, g.rc_7.radio_max, g.rc_8.radio_min, g.rc_8.radio_max);*/ ///* Serial.printf_P(PSTR("CH1: %d | %d\n"), (int)g.rc_1.radio_min, (int)g.rc_1.radio_max); Serial.printf_P(PSTR("CH2: %d | %d\n"), (int)g.rc_2.radio_min, (int)g.rc_2.radio_max); Serial.printf_P(PSTR("CH3: %d | %d\n"), (int)g.rc_3.radio_min, (int)g.rc_3.radio_max); Serial.printf_P(PSTR("CH4: %d | %d\n"), (int)g.rc_4.radio_min, (int)g.rc_4.radio_max); Serial.printf_P(PSTR("CH5: %d | %d\n"), (int)g.rc_5.radio_min, (int)g.rc_5.radio_max); Serial.printf_P(PSTR("CH6: %d | %d\n"), (int)g.rc_6.radio_min, (int)g.rc_6.radio_max); Serial.printf_P(PSTR("CH7: %d | %d\n"), (int)g.rc_7.radio_min, (int)g.rc_7.radio_max); Serial.printf_P(PSTR("CH8: %d | %d\n"), (int)g.rc_8.radio_min, (int)g.rc_8.radio_max); //*/ } void print_switch(byte p, byte m) { Serial.printf_P(PSTR("Pos %d: "),p); Serial.println(flight_mode_strings[m]); } void print_done() { Serial.printf_P(PSTR("\nSaved Settings\n\n")); } void print_blanks(int num) { while(num > 0){ num--; Serial.println(""); } } void print_divider(void) { for (int i = 0; i < 40; i++) { Serial.print("-"); } Serial.println(""); } // read at 50Hz bool radio_input_switch(void) { static int8_t bouncer = 0; if (int16_t(g.rc_1.radio_in - g.rc_1.radio_trim) > 100) { bouncer = 10; } if (int16_t(g.rc_1.radio_in - g.rc_1.radio_trim) < -100) { bouncer = -10; } if (bouncer >0) { bouncer --; } if (bouncer <0) { bouncer ++; } if (bouncer == 1 || bouncer == -1) { return bouncer; }else{ return 0; } } void zero_eeprom(void) { byte b; Serial.printf_P(PSTR("\nErasing EEPROM\n")); for (int i = 0; i < EEPROM_MAX_ADDR; i++) { eeprom_write_byte((uint8_t *) i, b); } Serial.printf_P(PSTR("done\n")); } void print_enabled(boolean b) { if(b) Serial.printf_P(PSTR("en")); else Serial.printf_P(PSTR("dis")); Serial.printf_P(PSTR("abled\n")); } void print_accel_offsets(void) { Serial.printf_P(PSTR("Accel offsets: %4.2f, %4.2f, %4.2f\n"), (float)imu.ax(), (float)imu.ay(), (float)imu.az()); } void print_gyro_offsets(void) { Serial.printf_P(PSTR("Gyro offsets: %4.2f, %4.2f, %4.2f\n"), (float)imu.gx(), (float)imu.gy(), (float)imu.gz()); } /***************************************************************************/ // EEPROM convenience functions /***************************************************************************/ void read_EEPROM_waypoint_info(void) { g.waypoint_total.load(); g.waypoint_radius.load(); g.loiter_radius.load(); } void save_EEPROM_waypoint_info(void) { g.waypoint_total.save(); g.waypoint_radius.save(); g.loiter_radius.save(); } /********************************************************************************/ void read_EEPROM_nav(void) { g.crosstrack_gain.load(); g.crosstrack_entry_angle.load(); g.pitch_max.load(); } void save_EEPROM_nav(void) { g.crosstrack_gain.save(); g.crosstrack_entry_angle.save(); g.pitch_max.save(); } /********************************************************************************/ void read_EEPROM_PID(void) { g.pid_acro_rate_roll.load_gains(); g.pid_acro_rate_pitch.load_gains(); g.pid_acro_rate_yaw.load_gains(); g.pid_stabilize_roll.load_gains(); g.pid_stabilize_pitch.load_gains(); g.pid_yaw.load_gains(); g.pid_nav_lon.load_gains(); g.pid_nav_lat.load_gains(); g.pid_baro_throttle.load_gains(); g.pid_sonar_throttle.load_gains(); // roll pitch g.stabilize_dampener.load(); // yaw g.hold_yaw_dampener.load(); init_pids(); } void save_EEPROM_PID(void) { g.pid_acro_rate_roll.save_gains(); g.pid_acro_rate_pitch.save_gains(); g.pid_acro_rate_yaw.save_gains(); g.pid_stabilize_roll.save_gains(); g.pid_stabilize_pitch.save_gains(); g.pid_yaw.save_gains(); g.pid_nav_lon.save_gains(); g.pid_nav_lat.save_gains(); g.pid_baro_throttle.save_gains(); g.pid_sonar_throttle.save_gains(); // roll pitch g.stabilize_dampener.save(); // yaw g.hold_yaw_dampener.save(); } /********************************************************************************/ void save_EEPROM_current(void) { g.current_enabled.save(); g.milliamp_hours.save(); } void read_EEPROM_current(void) { g.current_enabled.load(); g.milliamp_hours.load(); } /********************************************************************************/ void read_EEPROM_radio(void) { g.rc_1.load_eeprom(); g.rc_2.load_eeprom(); g.rc_3.load_eeprom(); g.rc_4.load_eeprom(); g.rc_5.load_eeprom(); g.rc_6.load_eeprom(); g.rc_7.load_eeprom(); g.rc_8.load_eeprom(); } void save_EEPROM_radio(void) { g.rc_1.save_eeprom(); g.rc_2.save_eeprom(); g.rc_3.save_eeprom(); g.rc_4.save_eeprom(); g.rc_5.save_eeprom(); g.rc_6.save_eeprom(); g.rc_7.save_eeprom(); g.rc_8.save_eeprom(); } /********************************************************************************/ // configs are the basics void read_EEPROM_throttle(void) { g.throttle_min.load(); g.throttle_max.load(); g.throttle_cruise.load(); g.throttle_fs_enabled.load(); g.throttle_fs_action.load(); g.throttle_fs_value.load(); } void save_EEPROM_throttle(void) { g.throttle_min.load(); g.throttle_max.load(); g.throttle_cruise.save(); g.throttle_fs_enabled.load(); g.throttle_fs_action.load(); g.throttle_fs_value.load(); } /********************************************************************************/ /* float read_EE_float(int address) { union { byte bytes[4]; float value; } _floatOut; for (int i = 0; i < 4; i++) _floatOut.bytes[i] = eeprom_read_byte((uint8_t *) (address + i)); return _floatOut.value; } void write_EE_float(float value, int address) { union { byte bytes[4]; float value; } _floatIn; _floatIn.value = value; for (int i = 0; i < 4; i++) eeprom_write_byte((uint8_t *) (address + i), _floatIn.bytes[i]); } */ /********************************************************************************/ /* float read_EE_compressed_float(int address, byte places) { float scale = pow(10, places); int temp = eeprom_read_word((uint16_t *) address); return ((float)temp / scale); } void write_EE_compressed_float(float value, int address, byte places) { float scale = pow(10, places); int temp = value * scale; eeprom_write_word((uint16_t *) address, temp); } */