void turn_direction(float direction)
{
	int end_turn;
		
		if (direction < PI)     // turn clockwise
		{
			e_set_steps_left(0);
			e_set_speed_left(TURN_SPEED);  // motor speed in steps/s
			e_set_speed_right(-TURN_SPEED);  // motor speed in steps/s
			
			// calculate how many steps the robot needs to turn
			end_turn = (int)(STEPS_FOR_2PI*(direction/(2*PI)));   
			while(e_get_steps_left() < end_turn){
				flick_led();
		}   // turn until done 
		}
		else 					// turn counterclockwise
		{
			e_set_steps_right(0);
			e_set_speed_left(-TURN_SPEED);  // motor speed in steps/s
			e_set_speed_right(TURN_SPEED);  // motor speed in steps/s
			
			// calculate how many steps the robot needs to turn
			end_turn = (int)(STEPS_FOR_2PI*((2*PI-direction)/(2*PI)));
			while(e_get_steps_right() < end_turn){
				flick_led();
			}   // turn until done
		}

		// stop motors
		e_set_speed_left(0);  // motor speed in steps/s
		e_set_speed_right(0);  // motor speed in steps/s
}
Esempio n. 2
0
void send_steps()
{
  int steps_right,steps_left;

  steps_right = e_get_steps_right();
  steps_left = e_get_steps_left();
  e_set_steps_right(0);
  e_set_steps_left(0);

  ve_send_int(steps_right);
  ve_send_int(steps_left);
}
Esempio n. 3
0
int run_asercom(void) {
	static char c1,c2,wait_cam=0;
	static int	i,j,n,speedr,speedl,positionr,positionl,LED_nbr,LED_action,accx,accy,accz,sound;
	static int cam_mode,cam_width,cam_heigth,cam_zoom,cam_size,cam_x1,cam_y1;
	static char first=0;
	char *ptr;
	static int mod, reg, val;
#ifdef IR_RECEIVER
	char ir_move = 0,ir_address= 0, ir_last_move = 0;
#endif
	static TypeAccSpheric accelero;
	//static TypeAccRaw accelero_raw;
	int use_bt=0;
	//e_init_port();    // configure port pins
	//e_start_agendas_processing();
	e_init_motors();
	//e_init_uart1();   // initialize UART to 115200 Kbaud
	//e_init_ad_scan();

	selector = getselector(); //SELECTOR0 + 2*SELECTOR1 + 4*SELECTOR2 + 8*SELECTOR3;
	if(selector==10) {
		use_bt=0;
	} else {
		use_bt=1;
	}

#ifdef FLOOR_SENSORS
	if(use_bt) {	// the I2C must remain disabled when using the gumstix extension
		e_i2cp_init();
	}
#endif

#ifdef IR_RECEIVER
	e_init_remote_control();
#endif
	if(RCONbits.POR) {	// reset if power on (some problem for few robots)
		RCONbits.POR=0;
		RESET();
	}
	/*read HW version from the eeprom (last word)*/
	static int HWversion=0xFFFF;
	ReadEE(0x7F,0xFFFE,&HWversion, 1);

	/*Cam default parameter*/
	cam_mode=RGB_565_MODE;
	cam_width=40; // DEFAULT_WIDTH;
	cam_heigth=40; // DEFAULT_HEIGHT;
	cam_zoom=8;
	cam_size=cam_width*cam_heigth*2;

	if(use_bt) {
		e_poxxxx_init_cam();
		//e_po6030k_set_sketch_mode(E_PO6030K_SKETCH_COLOR);
		e_poxxxx_config_cam((ARRAY_WIDTH -cam_width*cam_zoom)/2,(ARRAY_HEIGHT-cam_heigth*cam_zoom)/2,cam_width*cam_zoom,cam_heigth*cam_zoom,cam_zoom,cam_zoom,cam_mode);
		e_poxxxx_set_mirror(1,1);
		e_poxxxx_write_cam_registers();
	}
	
	e_acc_calibr();
	
	if(use_bt) {
	uart1_send_static_text("\f\a"
			"WELCOME to the SerCom protocol on e-Puck\r\n"
			"the EPFL education robot type \"H\" for help\r\n");
	} else {
	uart2_send_static_text("\f\a"
			"WELCOME to the SerCom protocol on e-Puck\r\n"
			"the EPFL education robot type \"H\" for help\r\n");
	}


	while(1) {
		if(use_bt) {
			while (e_getchar_uart1(&c)==0)
			#ifdef IR_RECEIVER
					{
						ir_move = e_get_data();
						ir_address = e_get_address();
						if (((ir_address ==  0)||(ir_address ==  8))&&(ir_move!=ir_last_move)){
							switch(ir_move) {
								case 1:
									speedr = SPEED_IR;
									speedl = SPEED_IR/2;
									break;
								case 2:
									speedr = SPEED_IR;
									speedl = SPEED_IR;
									break;
								case 3:
									speedr = SPEED_IR/2;
									speedl = SPEED_IR;
									break;
								case 4:
									speedr = SPEED_IR;
									speedl = -SPEED_IR;
									break;
								case 5:
									speedr = 0;
									speedl = 0;
									break;
								case 6:
									speedr = -SPEED_IR;
									speedl = SPEED_IR;
									break;
								case 7:
									speedr = -SPEED_IR;
									speedl = -SPEED_IR/2;
									break;
								case 8:
									speedr = -SPEED_IR;
									speedl = -SPEED_IR;
									break;
								case 9:
									speedr = -SPEED_IR/2;
									speedl = -SPEED_IR;
									break;
								case 0:
									if(first==0){
										e_init_sound();
										first=1;
									}
									e_play_sound(11028,8016);
									break;
								default:
									speedr = speedl = 0;
							}
							ir_last_move = ir_move;
							e_set_speed_left(speedl);
							e_set_speed_right(speedr);
							}
					}
			#else 
					;
			#endif
		} else {
			while (e_getchar_uart2(&c)==0)
			#ifdef IR_RECEIVER
					{
						ir_move = e_get_data();
						ir_address = e_get_address();
						if (((ir_address ==  0)||(ir_address ==  8))&&(ir_move!=ir_last_move)){
							switch(ir_move) {
								case 1:
									speedr = SPEED_IR;
									speedl = SPEED_IR/2;
									break;
								case 2:
									speedr = SPEED_IR;
									speedl = SPEED_IR;
									break;
								case 3:
									speedr = SPEED_IR/2;
									speedl = SPEED_IR;
									break;
								case 4:
									speedr = SPEED_IR;
									speedl = -SPEED_IR;
									break;
								case 5:
									speedr = 0;
									speedl = 0;
									break;
								case 6:
									speedr = -SPEED_IR;
									speedl = SPEED_IR;
									break;
								case 7:
									speedr = -SPEED_IR;
									speedl = -SPEED_IR/2;
									break;
								case 8:
									speedr = -SPEED_IR;
									speedl = -SPEED_IR;
									break;
								case 9:
									speedr = -SPEED_IR/2;
									speedl = -SPEED_IR;
									break;
								case 0:
									if(first==0){
										e_init_sound();
										first=1;
									}
									e_play_sound(11028,8016);
									break;
								default:
									speedr = speedl = 0;
							}
							ir_last_move = ir_move;
							e_set_speed_left(speedl);
							e_set_speed_right(speedr);
							}
					}
			#else 
					;
			#endif
		}

		if (c<0) { // binary mode (big endian)
			i=0;
			do {
				switch(-c) { 
        		case 'a': // Read acceleration sensors in a non
                  // filtered way, some as ASCII
          			accx = e_get_acc_filtered(0, 1); 
          			accy = e_get_acc_filtered(1, 1); 
          			accz = e_get_acc_filtered(2, 1); 
				
				//accx = e_get_acc(0);	//too much noisy
				//accy = e_get_acc(1);
				//accz = e_get_acc(2);

				buffer[i++] = accx & 0xff;
          			buffer[i++] = accx >> 8;
          			buffer[i++] = accy & 0xff;
          			buffer[i++] = accy >> 8;
          			buffer[i++] = accz & 0xff;
          			buffer[i++] = accz >> 8;
				
				/*
          			accelero_raw=e_read_acc_xyz();
				ptr=(char *)&accelero_raw.acc_x;
				buffer[i++]=(*ptr);
				ptr++;
				buffer[i++]=(*ptr);
				ptr++;

				ptr=(char *)&accelero_raw.acc_y;
				buffer[i++]=(*ptr);
				ptr++;
				buffer[i++]=(*ptr);
				ptr++;

				ptr=(char *)&accelero_raw.acc_z;
				buffer[i++]=(*ptr);
				ptr++;
				buffer[i++]=(*ptr);
				ptr++;
				*/
          			break;
				case 'A': // read acceleration sensors
					accelero=e_read_acc_spheric();
					ptr=(char *)&accelero.acceleration;
					buffer[i++]=(*ptr);
					ptr++;
					buffer[i++]=(*ptr);
					ptr++;
					buffer[i++]=(*ptr);
					ptr++;
					buffer[i++]=(*ptr);
				
					ptr=(char *)&accelero.orientation;
					buffer[i++]=(*ptr);
					ptr++;
					buffer[i++]=(*ptr);
					ptr++;
					buffer[i++]=(*ptr);
					ptr++;
					buffer[i++]=(*ptr);
		
					ptr=(char *)&accelero.inclination;
					buffer[i++]=(*ptr);
					ptr++;
					buffer[i++]=(*ptr);
					ptr++;
					buffer[i++]=(*ptr);
					ptr++;
					buffer[i++]=(*ptr);
				
					break;
				case 'b': // battery ok?
					buffer[i++] = BATT_LOW;
					break;
				case 'D': // set motor speed
					if(use_bt) {
						while (e_getchar_uart1(&c1)==0);
						while (e_getchar_uart1(&c2)==0);
					} else {
						while (e_getchar_uart2(&c1)==0);
						while (e_getchar_uart2(&c2)==0);
					}
					speedl=(unsigned char)c1+((unsigned int)c2<<8);
					if(use_bt) {
						while (e_getchar_uart1(&c1)==0);
						while (e_getchar_uart1(&c2)==0);
					} else {
						while (e_getchar_uart2(&c1)==0);
						while (e_getchar_uart2(&c2)==0);					
					}
					speedr=(unsigned char)c1+((unsigned  int)c2<<8);
					e_set_speed_left(speedl);
					e_set_speed_right(speedr);
					break;
        		case 'E': // get motor speed
          			buffer[i++] = speedl & 0xff;
          			buffer[i++] = speedl >> 8;
          			buffer[i++] = speedr & 0xff;
          			buffer[i++] = speedr >> 8;
          			break;
				case 'I': // get camera image
					if(use_bt) {
						e_poxxxx_launch_capture(&buffer[i+3]);
						wait_cam=1;
						buffer[i++]=(char)cam_mode&0xff;//send image parameter
						buffer[i++]=(char)cam_width&0xff;
						buffer[i++]=(char)cam_heigth&0xff;
						i+=cam_size;
					}
					break;
				case 'L': // set LED
					if(use_bt) {
						while (e_getchar_uart1(&c1)==0);
						while (e_getchar_uart1(&c2)==0);
					} else {
						while (e_getchar_uart2(&c1)==0);
						while (e_getchar_uart2(&c2)==0);
					}
					switch(c1) {
						case 8:
							if(use_bt) {
								e_set_body_led(c2);
							}
							break;
						case 9:
							if(use_bt) {
								e_set_front_led(c2);
							}
							break;
						default:
							e_set_led(c1,c2);
							break;
					}
					break;
				case 'M': // optional floor sensors
#ifdef FLOOR_SENSORS
					if(use_bt) {
	          			e_i2cp_init();
	          			e_i2cp_enable();
	          			e_i2cp_read(0xC0, 0);
	          			for(j = 0; j < 6; j++) {
	            			if (j % 2 == 0) buffer[i++] = e_i2cp_read(0xC0, j + 1);
	            			else            buffer[i++] = e_i2cp_read(0xC0, j - 1);
	          			}
#ifdef CLIFF_SENSORS
          				for(j=13; j<17; j++) {
            				if (j % 2 == 0) buffer[i++] = e_i2cp_read(0xC0, j - 1);
            				else            buffer[i++] = e_i2cp_read(0xC0, j + 1);	          				
	          			}
#endif
	          			e_i2cp_disable();
					}
#else
					for(j=0;j<6;j++) buffer[i++]=0;
#endif
					break;
				case 'N': // read proximity sensors
					if(use_bt) {
						for(j=0;j<8;j++) {
							n=e_get_calibrated_prox(j);	// or ? n=e_get_prox(j);
							buffer[i++]=n&0xff;
							buffer[i++]=n>>8;
						}
					} else {
						for(j=0;j<10;j++) {
							n=e_get_calibrated_prox(j);	// or ? n=e_get_prox(j);
							buffer[i++]=n&0xff;
							buffer[i++]=n>>8;
						}
					}
					break;
				case 'O': // read light sensors
					if(use_bt) {
						for(j=0;j<8;j++) {
	
							n=e_get_ambient_light(j);
							buffer[i++]=n&0xff;
							buffer[i++]=n>>8;
						}
					} else {
						for(j=0;j<10;j++) {
							n=e_get_ambient_light(j);
							buffer[i++]=n&0xff;
							buffer[i++]=n>>8;
						}
					}
					break;
				case 'Q': // read encoders
                    n=e_get_steps_left();
					buffer[i++]=n&0xff;
					buffer[i++]=n>>8;
                    n=e_get_steps_right();
					buffer[i++]=n&0xff;
					buffer[i++]=n>>8;
					break;
        		case 'u': // get last micro volumes
          			n = e_get_micro_volume(0);
          			buffer[i++] = n & 0xff;
          			buffer[i++] = n >> 8;

          			n = e_get_micro_volume(1);
          			buffer[i++] = n & 0xff;
          			buffer[i++] = n >> 8;

          			n = e_get_micro_volume(2);
          			buffer[i++] = n & 0xff;
          			buffer[i++] = n >> 8;
          			break;
				case 'U': // get micro buffer
					ptr=(char *)e_mic_scan;
					if(use_bt) {
						e_send_uart1_char(ptr,600);//send sound buffer
					} else {
						e_send_uart2_char(ptr,600);//send sound buffer
					}
					n=e_last_mic_scan_id;//send last scan
					buffer[i++]=n&0xff;
					break;
				default: // silently ignored
					break;
				}
				if(use_bt) {
					while (e_getchar_uart1(&c)==0); // get next command
				} else {
					while (e_getchar_uart2(&c)==0); // get next command
				}
			} while(c);