#include "Copter.h" #if MODE_TURTLE_ENABLED == ENABLED #define CRASH_FLIP_EXPO 35.0f #define CRASH_FLIP_STICK_MINF 0.15f #define power3(x) ((x) * (x) * (x)) bool ModeTurtle::init(bool ignore_checks) { // do not enter the mode when already armed or when flying if (motors->armed() || SRV_Channels::get_dshot_esc_type() == 0) { return false; } // perform minimal arming checks if (!copter.mavlink_motor_control_check(*gcs().chan(0), true, "Turtle Mode")) { return false; } // do not enter the mode if sticks are not centered if (!is_zero(channel_pitch->norm_input_dz()) || !is_zero(channel_roll->norm_input_dz()) || !is_zero(channel_yaw->norm_input_dz())) { return false; } // reverse the motors hal.rcout->disable_channel_mask_updates(); change_motor_direction(true); // disable throttle and gps failsafe g.failsafe_throttle = FS_THR_DISABLED; g.failsafe_gcs = FS_GCS_DISABLED; g.fs_ekf_action = 0; // arm motors->armed(true); hal.util->set_soft_armed(true); return true; } bool ModeTurtle::allows_arming(AP_Arming::Method method) const { return true; } void ModeTurtle::exit() { // disarm motors->armed(false); hal.util->set_soft_armed(false); // un-reverse the motors change_motor_direction(false); hal.rcout->enable_channel_mask_updates(); // re-enable failsafes g.failsafe_throttle.load(); g.failsafe_gcs.load(); g.fs_ekf_action.load(); } void ModeTurtle::change_motor_direction(bool reverse) { AP_HAL::RCOutput::BLHeliDshotCommand direction = reverse ? AP_HAL::RCOutput::DSHOT_REVERSE : AP_HAL::RCOutput::DSHOT_NORMAL; AP_HAL::RCOutput::BLHeliDshotCommand inverse_direction = reverse ? AP_HAL::RCOutput::DSHOT_NORMAL : AP_HAL::RCOutput::DSHOT_REVERSE; if (!hal.rcout->get_reversed_mask()) { hal.rcout->send_dshot_command(direction, AP_HAL::RCOutput::ALL_CHANNELS, 0, 10, true); } else { for (uint8_t i = 0; i < AP_MOTORS_MAX_NUM_MOTORS; ++i) { if (!motors->is_motor_enabled(i)) { continue; } if ((hal.rcout->get_reversed_mask() & (1U << i)) == 0) { hal.rcout->send_dshot_command(direction, i, 0, 10, true); } else { hal.rcout->send_dshot_command(inverse_direction, i, 0, 10, true); } } } } void ModeTurtle::run() { const float flip_power_factor = 1.0f - CRASH_FLIP_EXPO / 100.0f; const bool norc = copter.failsafe.radio || !copter.ap.rc_receiver_present; const float stick_deflection_pitch = norc ? 0.0f : channel_pitch->norm_input_dz(); const float stick_deflection_roll = norc ? 0.0f : channel_roll->norm_input_dz(); const float stick_deflection_yaw = norc ? 0.0f : channel_yaw->norm_input_dz(); const float stick_deflection_pitch_abs = fabsf(stick_deflection_pitch); const float stick_deflection_roll_abs = fabsf(stick_deflection_roll); const float stick_deflection_yaw_abs = fabsf(stick_deflection_yaw); const float stick_deflection_pitch_expo = flip_power_factor * stick_deflection_pitch_abs + power3(stick_deflection_pitch_abs) * (1 - flip_power_factor); const float stick_deflection_roll_expo = flip_power_factor * stick_deflection_roll_abs + power3(stick_deflection_roll_abs) * (1 - flip_power_factor); const float stick_deflection_yaw_expo = flip_power_factor * stick_deflection_yaw_abs + power3(stick_deflection_yaw_abs) * (1 - flip_power_factor); float sign_pitch = stick_deflection_pitch < 0 ? -1 : 1; float sign_roll = stick_deflection_roll < 0 ? 1 : -1; float stick_deflection_length = sqrtf(sq(stick_deflection_pitch_abs) + sq(stick_deflection_roll_abs)); float stick_deflection_expo_length = sqrtf(sq(stick_deflection_pitch_expo) + sq(stick_deflection_roll_expo)); if (stick_deflection_yaw_abs > MAX(stick_deflection_pitch_abs, stick_deflection_roll_abs)) { // If yaw is the dominant, disable pitch and roll stick_deflection_length = stick_deflection_yaw_abs; stick_deflection_expo_length = stick_deflection_yaw_expo; sign_roll = 0; sign_pitch = 0; } const float cos_phi = (stick_deflection_length > 0) ? (stick_deflection_pitch_abs + stick_deflection_roll_abs) / (sqrtf(2.0f) * stick_deflection_length) : 0; const float cos_threshold = sqrtf(3.0f) / 2.0f; // cos(PI/6.0f) if (cos_phi < cos_threshold) { // Enforce either roll or pitch exclusively, if not on diagonal if (stick_deflection_roll_abs > stick_deflection_pitch_abs) { sign_pitch = 0; } else { sign_roll = 0; } } // Apply a reasonable amount of stick deadband const float crash_flip_stick_min_expo = flip_power_factor * CRASH_FLIP_STICK_MINF + power3(CRASH_FLIP_STICK_MINF) * (1 - flip_power_factor); const float flip_stick_range = 1.0f - crash_flip_stick_min_expo; const float flip_power = MAX(0.0f, stick_deflection_expo_length - crash_flip_stick_min_expo) / flip_stick_range; // at this point we have a power value in the range 0..1 // notmalise the roll and pitch input to match the motors Vector2f input{sign_roll, sign_pitch}; motors_input = input.normalized() * 0.5; // we bypass spin min and friends in the deadzone because we only want spin up when the sticks are moved motors_output = !is_zero(flip_power) ? motors->thrust_to_actuator(flip_power) : 0.0f; } // actually write values to the motors void ModeTurtle::output_to_motors() { for (uint8_t i = 0; i < AP_MOTORS_MAX_NUM_MOTORS; ++i) { if (!motors->is_motor_enabled(i)) { continue; } const Vector2f output{motors->get_roll_factor(i), motors->get_pitch_factor(i)}; // if output aligns with input then use this motor if ((motors_input - output).length() > 0.5) { motors->rc_write(i, motors->get_pwm_output_min()); continue; } int16_t pwm = motors->get_pwm_output_min() + (motors->get_pwm_output_max() - motors->get_pwm_output_min()) * motors_output; motors->rc_write(i, pwm); } } #endif