示例#1
0
//Case 4: User Interface
void main_fsm_case_4(void)
{
	//Alive LED
	alive_led();
	
	//UI RGB LED:
	
	if(safety_delay > SAFETY_DELAY)
	{
		//status_error_codes(safety_cop.status1, safety_cop.status2, &eL0, &eL1, &eL2); 
	}
	else
	{
		safety_delay++;
	}
	
	//Display temperature status on RGB	
	overtemp_error(&eL1, &eL2);					//Comment this line if safety code is problematic
	rgb_led_ui(eL0, eL1, eL2, new_cmd_led);		//ToDo add more error codes
	if(new_cmd_led)
	{
		new_cmd_led = 0;
	}
}
示例#2
0
int main(void)
{
	//Local variables:
	uint8 i = 0;
	unsigned char result = 0;
	uint8 toggle_wdclk = 0;	
	uint8 cmd_ready_485_1 = 0, cmd_ready_usb = 0;
	static uint8 new_cmd_led = 0;
	uint16 safety_delay = 0;
	uint8 i2c_time_share = 0;
	
	//Power on delay with LEDs
	power_on();	     

	//Initialize all the peripherals
	init_peripherals();
	
	//Start with an empty buffer
	flexsea_clear_slave_read_buffer();
	
	//=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-
	//Blocking Test code - enable one and only one for special 
	//debugging. Normal code WILL NOT EXECUTE when this is enabled!
	//=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=
	//strain_test_blocking();
	//safety_cop_comm_test_blocking();
	//imu_test_code_blocking();
	//motor_fixed_pwm_test_code_blocking(141);
	//wdclk_test_blocking();
	//timing_test_blocking();
	//test_current_tracking_blocking();
	//test_pwm_pulse_blocking();
	//test_uart_dma_xmit();
	//motor_cancel_damping_test_code_blocking();
	//csea_knee_up_down_test_demo();
	//motor_stepper_test_blocking_1(80);
	//=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=
	//Non-Blocking Test code
	//=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=
	#ifdef USE_SPI_COMMUT
		
	motor_stepper_test_init(0);
	//Note: deadtime is 55, small PWM values won't make it move.
	//Starting at 0, GUI will change that when it wants.
	
	#endif	//USE_SPI_COMMUT	
	//=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=	
	
	//Special code for the ExoBoots:
	#ifdef PROJECT_EXOCUTE
	init_exo();
	#endif

	//Main loop
	while(1)
	{
		if(t1_new_value == 1)
		{
			//If the time share slot changed we run the timing FSM. Refer to
			//timing.xlsx for more details. 't1_new_value' updates at 10kHz,
			//each slot at 1kHz.
			
			t1_new_value = 0;
			
			//Timing FSM:
			switch(t1_time_share)
			{
				//Case 0: I2C
				case 0:
					i2c_time_share++;
					i2c_time_share %= 4;
				
					#ifdef USE_I2C_INT
				
					//Subdivided in 4 slots.
					switch(i2c_time_share)
					{
						//Case 0.0: Accelerometer
						case 0:
						
							#ifdef USE_IMU							
							get_accel_xyz();
							i2c_last_request = I2C_RQ_ACCEL;
							#endif 	//USE_IMU
						
							break;
						
						//Case 0.1: Gyroscope
						case 1:
							
							#ifdef USE_IMU							
							get_gyro_xyz();		
							i2c_last_request = I2C_RQ_GYRO;
							#endif 	//USE_IMU
							
							break;
						
						//Case 0.2: Safety-Cop
						case 2:
							
							safety_cop_get_status();
							i2c_last_request = I2C_RQ_SAFETY;
							break;
						
						//Case 0.3: Free
						case 3:
							//I2C RGB LED
							
							//minm_test_code();
							update_minm_rgb();		//ToDo: That's EXT_I2C, not INT
							
							break;
						
						default:
							break;
					}
					
					#endif //USE_I2C_INT
					
					#ifdef USE_SPI_COMMUT
						
					angle = as5047_read_single(AS5047_REG_ANGLEUNC);
					
					#endif	//USE_SPI_COMMUT
				
					break;
				
				//Case 1:	
				case 1:
					break;
				
				//Case 2:	
				case 2:
					break;
				
				//Case 3: Strain Gauge DelSig ADC, SAR ADC
				case 3:
					
					//Start a new conversion
					ADC_DelSig_1_StartConvert();
					
					//Filter the previous results
					strain_filter_dma();					
					
					break;
				
				//Case 4: User Interface	
				case 4:
					
					//Alive LED
					alive_led();
					
					//UI RGB LED:
					
					if(safety_delay > SAFETY_DELAY)
					{
						//status_error_codes(safety_cop.status1, safety_cop.status2, &eL0, &eL1, &eL2); 
					}
					else
					{
						safety_delay++;
					}
					
					//Display temperature status on RGB	
					overtemp_error(&eL1, &eL2);					//Comment this line if safety code is problematic
					rgb_led_ui(eL0, eL1, eL2, new_cmd_led);		//ToDo add more error codes
					if(new_cmd_led)
					{
						new_cmd_led = 0;
					}
					
					break;
				
				//Case 5: Quadrature encoder & Position setpoint
				case 5:
					
					#ifdef USE_QEI1
				
					//Refresh encoder readings
					encoder_read();
						
					#endif	//USE_QEI1		
					
					#ifdef USE_TRAPEZ	
				
					if((ctrl.active_ctrl == CTRL_POSITION) || (ctrl.active_ctrl == CTRL_IMPEDANCE))
					{	
						//Trapezoidal trajectories (can be used for both Position & Impedance)				
						ctrl.position.setp = trapez_get_pos(steps);	//New setpoint
						ctrl.impedance.setpoint_val = trapez_get_pos(steps);	//New setpoint
					}
					
					#endif	//USE_TRAPEZ	
			
					break;
				
				//Case 6: P & Z controllers, 0 PWM	
				case 6:
					
					#ifdef USE_TRAPEZ	
					
					if(ctrl.active_ctrl == CTRL_POSITION)
					{
						motor_position_pid(ctrl.position.setp, ctrl.position.pos);
					}
					else if(ctrl.active_ctrl == CTRL_IMPEDANCE)
					{
						//Impedance controller
						motor_impedance_encoder(ctrl.impedance.setpoint_val, ctrl.impedance.actual_val);
					}
					
					#endif	//USE_TRAPEZ
					
					//If no controller is used the PWM should be 0:
					if(ctrl.active_ctrl == CTRL_NONE)
					{
						motor_open_speed_1(0);
					}
					
					break;
				
				case 7:
					
					#ifdef USE_SPI_COMMUT
						
					//Stepper test code:
					motor_stepper_test_runtime(10);
					
					#endif	//USE_SPI_COMMUT					
					
					break;
				
				//Case 8: SAR ADC filtering
				case 8:

					filter_sar_adc();
					
					break;
				
				//Case 9: User functions	
				case 9:
					
					//ExoBoot code - 1kHz
					#ifdef PROJECT_EXOCUTE
						
					exo_fsm();	
						
					#endif
					
					break;
				
				default:
					break;
			}
			
			//The code below is executed every 100us, after the previous slot. 
			//Keep it short!
			
			//BEGIN - 10kHz Refresh
			
			//RS-485 Byte Input
			#ifdef USE_RS485			
		
			//get_uart_data();	//Now done via DMA
			
			if(data_ready_485_1)
			{
				data_ready_485_1 = 0;
				//Got new data in, try to decode
				cmd_ready_485_1 = unpack_payload_485_1();
			}
				
			#endif	//USE_RS485
			
			//USB Byte Input
			#ifdef USE_USB			
		
			get_usb_data();
			
			if(data_ready_usb)
			{
				data_ready_usb = 0;
				//Got new data in, try to decode
				cmd_ready_usb = unpack_payload_usb();
				
				eL1 = 1;
			}

			#endif	//USE_USB
			
			//FlexSEA Network Communication
			#ifdef USE_COMM
				
			//Valid communication from RS-485 #1?
			if(cmd_ready_485_1 != 0)
			{
				cmd_ready_485_1 = 0;
				
				//Cheap trick to get first line	//ToDo: support more than 1
				for(i = 0; i < PAYLOAD_BUF_LEN; i++)
				{
					tmp_rx_command_485_1[i] = rx_command_485_1[0][i];
				}
				
				//payload_parse_str() calls the functions (if valid)
				result = payload_parse_str(tmp_rx_command_485_1);
				
				//LED:
				if(result == PARSE_SUCCESSFUL)
				{
					//Green LED only if the ID matched and the command was known
					new_cmd_led = 1;
				}
			}

			//Valid communication from USB?
			if(cmd_ready_usb != 0)
			{
				cmd_ready_usb = 0;
				
				//Cheap trick to get first line	//ToDo: support more than 1
				for(i = 0; i < PAYLOAD_BUF_LEN; i++)
				{
					tmp_rx_command_usb[i] = rx_command_usb[0][i];
				}
				
				//payload_parse_str() calls the functions (if valid)
				result = payload_parse_str(tmp_rx_command_usb);
				
				//LED:
				if(result == PARSE_SUCCESSFUL)
				{
					//Green LED only if the ID matched and the command was known
					new_cmd_led = 1;
				}
			}

			
			#endif	//USE_COMM	
			
			//END - 10kHz Refresh
		}
		else
		{
			//Asynchronous code goes here.
			
			//WatchDog Clock (Safety-CoP)
			toggle_wdclk ^= 1;
			WDCLK_Write(toggle_wdclk);
		}
	}
}