C++ (Cpp) shutter_control Beispiele

Beispiel #1

Datei: communication.c Projekt: zhao0079/imu_autopilot

//@{
void handle_mavlink_message(mavlink_channel_t chan,
		mavlink_message_t* msg)
{
	uint8_t buf[MAVLINK_MAX_PACKET_LEN];
	uint32_t len;
	switch (chan)
	{
	case MAVLINK_COMM_0:
	{
		if (msg->msgid != MAVLINK_MSG_ID_VISION_POSITION_ESTIMATE)
		{
			// Copy to COMM 1
			len = mavlink_msg_to_send_buffer(buf, msg);
			for (int i = 0; i < len; i++)
			{
				uart1_transmit(buf[i]);
			}
		}
	}
	break;
	case MAVLINK_COMM_1:
	{
		if (msg->msgid != MAVLINK_MSG_ID_VISION_POSITION_ESTIMATE && msg->msgid != MAVLINK_MSG_ID_VICON_POSITION_ESTIMATE)
		{
			// Copy to COMM 0
			len = mavlink_msg_to_send_buffer(buf, msg);
			for (int i = 0; i < len; i++)
			{
				uart0_transmit(buf[i]);
			}
			break;
		}
	}
	default:
		break;
	}


	switch (msg->msgid)
	{
	case MAVLINK_MSG_ID_SET_MODE:
	{
		mavlink_set_mode_t mode;
		mavlink_msg_set_mode_decode(msg, &mode);
		// Check if this system should change the mode
		if (mode.target == (uint8_t)global_data.param[PARAM_SYSTEM_ID])
		{
			sys_set_mode(mode.mode);

			// Emit current mode
			mavlink_msg_sys_status_send(MAVLINK_COMM_0, global_data.state.mav_mode, global_data.state.nav_mode,
					global_data.state.status, global_data.cpu_usage, global_data.battery_voltage,
					global_data.motor_block, communication_get_uart_drop_rate());
			mavlink_msg_sys_status_send(MAVLINK_COMM_1, global_data.state.mav_mode, global_data.state.nav_mode,
					global_data.state.status, global_data.cpu_usage, global_data.battery_voltage,
					global_data.motor_block, communication_get_uart_drop_rate());

		}
	}
	break;
	case MAVLINK_MSG_ID_ACTION:
	{
		execute_action(mavlink_msg_action_get_action(msg));

		//Forwart actions from Xbee to Onboard Computer and vice versa
		if (chan == MAVLINK_COMM_1)
		{
			mavlink_send_uart(MAVLINK_COMM_0, msg);
		}
		else if (chan == MAVLINK_COMM_0)
		{
			mavlink_send_uart(MAVLINK_COMM_1, msg);
		}
	}
	break;
	case MAVLINK_MSG_ID_SYSTEM_TIME:
	{
		if (!sys_time_clock_get_unix_offset())
		{
			int64_t offset = ((int64_t) mavlink_msg_system_time_get_time_usec(
					msg)) - (int64_t) sys_time_clock_get_time_usec();
			sys_time_clock_set_unix_offset(offset);

			debug_message_buffer("UNIX offset updated");
		}
		else
		{

			//			debug_message_buffer("UNIX offset REFUSED");
		}
	}
	break;
	case MAVLINK_MSG_ID_REQUEST_DATA_STREAM:
	{
		mavlink_request_data_stream_t stream;
		mavlink_msg_request_data_stream_decode(msg, &stream);
		switch (stream.req_stream_id)
		{
		case 0: // UNIMPLEMENTED
			break;
		case 1: // RAW SENSOR DATA
			global_data.param[PARAM_SEND_SLOT_RAW_IMU] = stream.start_stop;
			break;
		case 2: // EXTENDED SYSTEM STATUS
			global_data.param[PARAM_SEND_SLOT_ATTITUDE] = stream.start_stop;
			break;
		case 3: // REMOTE CONTROL CHANNELS
			global_data.param[PARAM_SEND_SLOT_REMOTE_CONTROL] = stream.start_stop;
			break;
		case 4: // RAW CONTROLLER
			//global_data.param[PARAM_SEND_SLOT_DEBUG_5] = stream.start_stop;
			//global_data.param[PARAM_SEND_SLOT_DEBUG_3] = stream.start_stop;
			global_data.param[PARAM_SEND_SLOT_CONTROLLER_OUTPUT] = stream.start_stop;
			break;
		case 5: // SENSOR FUSION

			//LOST IN GROUDNCONTROL
			//			global_data.param[PARAM_SEND_SLOT_DEBUG_5] = stream.start_stop;
			break;
		case 6: // POSITION
			global_data.param[PARAM_SEND_SLOT_DEBUG_5] = stream.start_stop;
			break;
		case 7: // EXTRA1
			global_data.param[PARAM_SEND_SLOT_DEBUG_2] = stream.start_stop;
			break;
		case 8: // EXTRA2
			global_data.param[PARAM_SEND_SLOT_DEBUG_4] = stream.start_stop;
			break;
		case 9: // EXTRA3
			global_data.param[PARAM_SEND_SLOT_DEBUG_6] = stream.start_stop;
			break;
		default:
			// Do nothing
			break;
		}
	}
	break;
	case MAVLINK_MSG_ID_PARAM_REQUEST_READ:
	{
		mavlink_param_request_read_t set;
		mavlink_msg_param_request_read_decode(msg, &set);

		// Check if this message is for this system
		if ((uint8_t) set.target_system
				== (uint8_t) global_data.param[PARAM_SYSTEM_ID]
				                               && (uint8_t) set.target_component
				                               == (uint8_t) global_data.param[PARAM_COMPONENT_ID])
		{
			char* key = (char*) set.param_id;

			if (set.param_id[0] == '\0')
			{
				// Choose parameter based on index
				if (set.param_index < ONBOARD_PARAM_COUNT)
				{
					// Report back value
					mavlink_msg_param_value_send(chan,
							(int8_t*) global_data.param_name[set.param_index],
							global_data.param[set.param_index], ONBOARD_PARAM_COUNT, set.param_index);
				}
			}
			else
			{
				for (int i = 0; i < ONBOARD_PARAM_COUNT; i++)
				{
					bool match = true;
					for (int j = 0; j < ONBOARD_PARAM_NAME_LENGTH; j++)
					{
						// Compare
						if (((char) (global_data.param_name[i][j]))
								!= (char) (key[j]))
						{
							match = false;
						}

						// End matching if null termination is reached
						if (((char) global_data.param_name[i][j]) == '\0')
						{
							break;
						}
					}

					// Check if matched
					if (match)
					{
						// Report back value
						mavlink_msg_param_value_send(chan,
								(int8_t*) global_data.param_name[i],
								global_data.param[i], ONBOARD_PARAM_COUNT, m_parameter_i);
					}
				}
			}
		}
	}
	break;
	case MAVLINK_MSG_ID_PARAM_REQUEST_LIST:
	{
		// Start sending parameters
		m_parameter_i = 0;
	}
	break;
	case MAVLINK_MSG_ID_PARAM_SET:
	{
		mavlink_param_set_t set;
		mavlink_msg_param_set_decode(msg, &set);

		// Check if this message is for this system
		if ((uint8_t) set.target_system
				== (uint8_t) global_data.param[PARAM_SYSTEM_ID]
				                               && (uint8_t) set.target_component
				                               == (uint8_t) global_data.param[PARAM_COMPONENT_ID])
		{
			char* key = (char*) set.param_id;

			for (int i = 0; i < ONBOARD_PARAM_COUNT; i++)
			{
				bool match = true;
				for (int j = 0; j < ONBOARD_PARAM_NAME_LENGTH; j++)
				{
					// Compare
					if (((char) (global_data.param_name[i][j]))
							!= (char) (key[j]))
					{
						match = false;
					}

					// End matching if null termination is reached
					if (((char) global_data.param_name[i][j]) == '\0')
					{
						break;
					}
				}

				// Check if matched
				if (match)
				{
					// Only write and emit changes if there is actually a difference
					// AND only write if new value is NOT "not-a-number"
					// AND is NOT infy
					if (global_data.param[i] != set.param_value
							&& !isnan(set.param_value)
							&& !isinf(set.param_value))
					{
						global_data.param[i] = set.param_value;
						// Report back new value
						mavlink_msg_param_value_send(MAVLINK_COMM_0,
								(int8_t*) global_data.param_name[i],
								global_data.param[i], ONBOARD_PARAM_COUNT, m_parameter_i);
						mavlink_msg_param_value_send(MAVLINK_COMM_1,
								(int8_t*) global_data.param_name[i],
								global_data.param[i], ONBOARD_PARAM_COUNT, m_parameter_i);

						debug_message_buffer_sprintf("Parameter received param id=%i",i);
					}
				}
			}
		}
	}
	break;
	case MAVLINK_MSG_ID_POSITION_CONTROL_SETPOINT_SET:
	{
		mavlink_position_control_setpoint_set_t pos;
		mavlink_msg_position_control_setpoint_set_decode(msg, &pos);
		if (global_data.param[PARAM_POSITIONSETPOINT_ACCEPT] == 1)
		{
			//			global_data.position_setpoint.x = pos.x;
			//			global_data.position_setpoint.y = pos.y;
			//			global_data.position_setpoint.z = pos.z;
			debug_message_buffer("Position setpoint updated. OLD?\n");
		}
		else
		{
			debug_message_buffer(
					"Position setpoint recieved but not updated. OLD?\n");
		}

		// Send back a message confirming the new position
		mavlink_msg_position_control_setpoint_send(MAVLINK_COMM_0, pos.id,
				pos.x, pos.y, pos.z, pos.yaw);
		mavlink_msg_position_control_setpoint_send(MAVLINK_COMM_1, pos.id,
				pos.x, pos.y, pos.z, pos.yaw);
	}
	break;
	case MAVLINK_MSG_ID_POSITION_CONTROL_OFFSET_SET:
	{
		mavlink_position_control_offset_set_t set;
		mavlink_msg_position_control_offset_set_decode(msg, &set);
		//global_data.attitude_setpoint_pos_body_offset.z = set.yaw;

		//Ball Tracking
		if (global_data.param[PARAM_POSITIONSETPOINT_ACCEPT] == 1 && global_data.param[PARAM_POSITION_YAW_TRACKING]==1)
		{
			global_data.param[PARAM_POSITION_SETPOINT_YAW]
			                  = global_data.attitude.z + set.yaw;

			mavlink_msg_debug_send(global_data.param[PARAM_SEND_DEBUGCHAN], 92, set.yaw);
		}
	}
	break;
	case MAVLINK_MSG_ID_SET_CAM_SHUTTER:
	{
		// Decode the desired shutter
		mavlink_set_cam_shutter_t cam;
		mavlink_msg_set_cam_shutter_decode(msg, &cam);
		shutter_set(cam.interval, cam.exposure);
		debug_message_buffer_sprintf("set_cam_shutter. interval %i",
				cam.interval);

	}
	break;
	case MAVLINK_MSG_ID_IMAGE_TRIGGER_CONTROL:
	{
		uint8_t enable = mavlink_msg_image_trigger_control_get_enable(msg);
		shutter_control(enable);
		if (enable)
		{
			debug_message_buffer("CAM: Enabling hardware trigger");
		}
		else
		{
			debug_message_buffer("CAM: Disabling hardware trigger");
		}
	}
	break;
	case MAVLINK_MSG_ID_VISION_POSITION_ESTIMATE:
	{
		mavlink_vision_position_estimate_t pos;
		mavlink_msg_vision_position_estimate_decode(msg, &pos);

		vision_buffer_handle_data(&pos);
		// Update validity time is done in vision buffer

	}
	break;
	case MAVLINK_MSG_ID_VICON_POSITION_ESTIMATE:
	{
		mavlink_vicon_position_estimate_t pos;
		mavlink_msg_vicon_position_estimate_decode(msg, &pos);

		global_data.vicon_data.x = pos.x;
		global_data.vicon_data.y = pos.y;
		global_data.vicon_data.z = pos.z;
		global_data.state.vicon_new_data=1;
		// Update validity time
		global_data.vicon_last_valid = sys_time_clock_get_time_usec();
		global_data.state.vicon_ok=1;

//		//Set data from Vicon into vision filter
//		global_data.vision_data.ang.x = pos.roll;
//		global_data.vision_data.ang.y = pos.pitch;
//		global_data.vision_data.ang.z = pos.yaw;
//
//		global_data.vision_data.pos.x = pos.x;
//		global_data.vision_data.pos.y = pos.y;
//		global_data.vision_data.pos.z = pos.z;
//
//		global_data.vision_data.new_data = 1;

		if (!global_data.state.vision_ok)
		{
			//Correct YAW
			global_data.attitude.z = pos.yaw;
			//If yaw goes to infy (no idea why) set it to setpoint, next time will be better
			if (global_data.attitude.z > 18.8495559 || global_data.attitude.z
					< -18.8495559)
			{
				global_data.attitude.z = global_data.yaw_pos_setpoint;
				debug_message_buffer(
						"vicon CRITICAL FAULT yaw was bigger than 6 PI! prevented crash");
			}
		}


		//send the vicon message to UART0 with new timestamp
		mavlink_msg_vicon_position_estimate_send(MAVLINK_COMM_0, global_data.vicon_last_valid, pos.x, pos.y, pos.z, pos.roll, pos.pitch, pos.yaw);

	}
	break;
	case MAVLINK_MSG_ID_PING:
	{
		mavlink_ping_t ping;
		mavlink_msg_ping_decode(msg, &ping);
		if (ping.target_system == 0 && ping.target_component == 0)
		{
			// Respond to ping
			uint64_t r_timestamp = sys_time_clock_get_unix_time();
			mavlink_msg_ping_send(chan, ping.seq, msg->sysid, msg->compid, r_timestamp);
		}
	}
	break;
	case MAVLINK_MSG_ID_LOCAL_POSITION_SETPOINT_SET:
	{
		mavlink_local_position_setpoint_set_t sp;
		mavlink_msg_local_position_setpoint_set_decode(msg, &sp);
		if (sp.target_system == global_data.param[PARAM_SYSTEM_ID])
		{
			if (global_data.param[PARAM_POSITIONSETPOINT_ACCEPT] == 1)
			{
				if (sp.x >= global_data.position_setpoint_min.x && sp.y
						>= global_data.position_setpoint_min.y && sp.z
						>= global_data.position_setpoint_min.z && sp.x
						<= global_data.position_setpoint_max.x && sp.y
						<= global_data.position_setpoint_max.y && sp.z
						<= global_data.position_setpoint_max.z)
				{
					debug_message_buffer("Setpoint accepted and set.");
					global_data.param[PARAM_POSITION_SETPOINT_X] = sp.x;
					global_data.param[PARAM_POSITION_SETPOINT_Y] = sp.y;
					global_data.param[PARAM_POSITION_SETPOINT_Z] = sp.z;

					if (global_data.param[PARAM_POSITION_YAW_TRACKING] == 0)
					{
						// Only update yaw if we are not tracking ball.
						global_data.param[PARAM_POSITION_SETPOINT_YAW] = sp.yaw;
					}

					//check if we want to start or land
					if (global_data.state.status == MAV_STATE_ACTIVE
							|| global_data.state.status == MAV_STATE_CRITICAL)
					{
						if (sp.z > -0.1)
						{
							if (!(global_data.state.fly == FLY_GROUNDED
									|| global_data.state.fly == FLY_SINKING
									|| global_data.state.fly
											== FLY_WAIT_LANDING
									|| global_data.state.fly == FLY_LANDING
									|| global_data.state.fly == FLY_RAMP_DOWN))
							{
								//if setpoint is lower that ground iate landing
								global_data.state.fly = FLY_SINKING;
								global_data.param[PARAM_POSITION_SETPOINT_Z]
										= -0.2;//with lowpass
								debug_message_buffer(
										"Sinking for LANDING. (z-sp lower than 10cm)");
							}
							else if (!(global_data.state.fly == FLY_GROUNDED))
							{
								global_data.param[PARAM_POSITION_SETPOINT_Z]
										= -0.2;//with lowpass
							}
						}
						else if (global_data.state.fly == FLY_GROUNDED && sp.z
								< -0.50)
						{
							//start if we were grounded and get a sp over 0.5m
							global_data.state.fly = FLY_WAIT_MOTORS;
							debug_message_buffer(
									"STARTING wait motors. (z-sp higher than 50cm)");
							//set point changed with lowpass, after 5s it will be ok.
						}
					}

					//SINK TO 0.7m if we are critical or emergency
					if (global_data.state.status == MAV_STATE_EMERGENCY
							|| global_data.state.status == MAV_STATE_CRITICAL)
					{
						global_data.param[PARAM_POSITION_SETPOINT_Z] = -0.7;//with lowpass
					}
				}
				else
				{
					debug_message_buffer("Setpoint refused. Out of range.");
				}
			}
			else
			{
				debug_message_buffer("Setpoint refused. Param setpoint accept=0.");
			}
		}
	}
	break;
	default:
		break;
	}
}

Beispiel #2

Datei: mainloop_quadrotor.c Projekt: 976717326/imu_autopilot

/**
* @brief Initialize the whole system
*
* All functions that need to be called before the first mainloop iteration
* should be placed here.
*/
void main_init_generic(void)
{

	// Reset to safe values
	global_data_reset();

	// Load default eeprom parameters as fallback
	global_data_reset_param_defaults();

	// LOWLEVEL INIT, ONLY VERY BASIC SYSTEM FUNCTIONS
	hw_init();
	enableIRQ();
	led_init();
	led_on(LED_GREEN);
	buzzer_init();
	sys_time_init();
	sys_time_periodic_init();
	sys_time_clock_init();
	ppm_init();
	pwm_init();

	// Lowlevel periphel support init
	adc_init();
	// FIXME SDCARD
//	MMC_IO_Init();
	spi_init();
	i2c_init();

	// Sensor init
	sensors_init();
	debug_message_buffer("Sensor initialized");

	// Shutter init
	shutter_init();
	shutter_control(0);

	// Debug output init
	debug_message_init();
	debug_message_buffer("Text message buffer initialized");

	// MEDIUM LEVEL INIT, INITIALIZE I2C, EEPROM, WAIT FOR MOTOR CONTROLLERS
	// Try to reach the EEPROM
	eeprom_check_start();

	// WAIT FOR 2 SECONDS FOR THE USER TO NOT TOUCH THE UNIT
	while (sys_time_clock_get_time_usec() < 2000000)
	{
	}

	// Do the auto-gyro calibration for 1 second
	// Get current temperature
	led_on(LED_RED);
	gyro_init();

//	uint8_t timeout = 3;
//	// Check for SD card
//	while (sys_time_clock_get_time_usec() < 2000000)
//	{
//		while (GetDriveInformation() != F_OK && timeout--)
//		  {
//		   debug_message_buffer("MMC/SD-Card not found ! retrying..");
//		  }
//	}
//
//	if (GetDriveInformation() == F_OK)
//	{
//		debug_message_buffer("MMC/SD-Card SUCCESS: FOUND");
//	}
//	else
//	{
//		debug_message_buffer("MMC/SD-Card FAILURE: NOT FOUND");
//	}
	//FIXME redo init because of SD driver decreasing speed
	//spi_init();
	led_off(LED_RED);

	// Stop trying to reach the EEPROM - if it has not been found by now, assume
	// there is no EEPROM mounted
	if (eeprom_check_ok())
	{
		param_read_all();
		debug_message_buffer("EEPROM detected - reading parameters from EEPROM");

		for (int i = 0; i < ONBOARD_PARAM_COUNT * 2 + 20; i++)
		{
			param_handler();
			//sleep 1 ms
			sys_time_wait(1000);
		}
	}
	else
	{
		debug_message_buffer("NO EEPROM - reading onboard parameters from FLASH");
	}

	// Set mavlink system
	mavlink_system.compid = MAV_COMP_ID_IMU;
	mavlink_system.sysid = global_data.param[PARAM_SYSTEM_ID];

	//Magnet sensor
	hmc5843_init();
	acc_init();

	// Comm parameter init
	mavlink_system.sysid = global_data.param[PARAM_SYSTEM_ID]; // System ID, 1-255
	mavlink_system.compid = global_data.param[PARAM_COMPONENT_ID]; // Component/Subsystem ID, 1-255

	// Comm init has to be
	// AFTER PARAM INIT
	comm_init(MAVLINK_COMM_0);
	comm_init(MAVLINK_COMM_1);

	// UART initialized, now initialize COMM peripherals
	communication_init();
	gps_init();

	us_run_init();

	servos_init();

	//position_kalman3_init();

	// Calibration starts (this can take a few seconds)
	//	led_on(LED_GREEN);
	//	led_on(LED_RED);

	// Read out first time battery
	global_data.battery_voltage = battery_get_value();

	global_data.state.mav_mode = MAV_MODE_PREFLIGHT;
	global_data.state.status = MAV_STATE_CALIBRATING;

	send_system_state();

	float_vect3 init_state_accel;
	init_state_accel.x = 0.0f;
	init_state_accel.y = 0.0f;
	init_state_accel.z = -1000.0f;
	float_vect3 init_state_magnet;
	init_state_magnet.x = 1.0f;
	init_state_magnet.y = 0.0f;
	init_state_magnet.z = 0.0f;


	//auto_calibration();


	attitude_observer_init(init_state_accel, init_state_magnet);

	debug_message_buffer("Attitude Filter initialized");
	led_on(LED_RED);

	send_system_state();

	debug_message_buffer("System is initialized");

	// Calibration stopped
	led_off(LED_RED);

	global_data.state.mav_mode = MAV_MODE_FLAG_MANUAL_INPUT_ENABLED;
	global_data.state.status = MAV_STATE_STANDBY;

	send_system_state();

	debug_message_buffer("Checking if remote control is switched on:");
	// Initialize remote control status
	remote_control();
	remote_control();
	if (radio_control_status() == RADIO_CONTROL_ON && global_data.state.remote_ok)
	{
		global_data.state.mav_mode = MAV_MODE_FLAG_MANUAL_INPUT_ENABLED | MAV_MODE_FLAG_TEST_ENABLED;
		debug_message_buffer("RESULT: remote control switched ON");
		debug_message_buffer("Now in MAV_MODE_TEST2 position hold tobi_laurens");
		led_on(LED_GREEN);
	}
	else
	{
		global_data.state.mav_mode = MAV_MODE_FLAG_MANUAL_INPUT_ENABLED;
		debug_message_buffer("RESULT: remote control switched OFF");
		led_off(LED_GREEN);
	}
}