Exemple #1
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static void	init(STEPPER_MOTOR* stepper){
	POLOLU_A4983* motor = (POLOLU_A4983*)stepper;

	// Make pins into outputs with initial values
	pin_make_output(motor->direction, FALSE);// clockwise
	pin_make_output(motor->enable, TRUE);	// disconnected
	pin_make_output(motor->pulse, FALSE);

	pin_make_output(motor->reset, FALSE);	// start reset the device
	pin_make_output(motor->reset, TRUE);	// end reset the device - will now respond to pulses

}
Exemple #2
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void speechInit(const IOPin* pin){
	pin_make_output(pin,FALSE);
	// Activate non-inverted PWM on the hardware pin
	TCCR1A |= (BV( COM1B0) << 1);
	

}
Exemple #3
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// Now create any global variables such as motors, servos, sensors etc
// This routine is called once only and allows you to do set up the hardware
// Dont use any 'clock' functions here - use 'delay' functions instead
void appInitHardware(void){
	a2dSetPrescaler(ADC_PRESCALE_DIV128);

	cyrf6936_Initialise_hard();


	// Initialise SPI bus as master. (RF modules connected to hardware SPI)
    spiBusInit(&bus, TRUE);
	spiDeviceSelect(&cyrf_0, TRUE);
	spiDeviceSelect(&cyrf_0, FALSE);
	spiDeviceSelect(&cyrf_1, TRUE);
	spiDeviceSelect(&cyrf_1, FALSE);

	// set I/O pins for RF module(s).
	pin_make_input(D4, FALSE);		// set PACTL pin to input. (module on connector J1)
	pin_make_input(D5, FALSE);		// set PACTLn pin to input. (module on connector J1)
	pin_make_input(D6, FALSE);		// set PACTL pin to input. (module on connector J2)
	pin_make_input(D7, FALSE);		// set PACTLn pin to input. (module on connector J2)

#ifdef RF_MODULE_ARTAFLEX
	//
	pin_make_output(D4, FALSE);			// set RXPA pin to output. (module on connector J1)
	pin_make_output(D5, FALSE);			// set TXPA pin to output. (module on connector J1)
	pin_make_output(D6, FALSE);			// set RXPA pin to output. (module on connector J2)
	pin_make_output(D7, FALSE);			// set TXPA pin to output. (module on connector J2)
#endif

	pin_make_input(E7, TRUE);		// set UNIGEN RF module IRQ pin to input. (module on connector J1)
	pin_make_input(E6, TRUE);		// set UNIGEN RF module IRQ pin to input. (module on connector J2)
	pin_make_output(G3, FALSE);			// set UNIGEN RF module RST pin to output. (both modules)
	//pin_low(G3);					// don't reset yet.

	// set I/O pins for status LEDs
	pin_make_output(C0, TRUE);			// set LED pin for output
	pin_make_output(C1, TRUE);			// set LED pin for output
	pin_make_output(C2, FALSE);			// set LED pin for output
	//pin_high(C0);					// LED off
	//pin_high(C1);					// LED off
	//pin_low(C2);					// LED on


	// Set UART1 to 19200 baud
    uartInit(UART1, 38400);
    // Tell rprintf to output to UART1
    rprintfInit(&uart1SendByte);


    // Initialise the servo controller using Hardware PWM
    servoPWMInit(&bank1);


    // Initialise WatchDog Timer
    wdt_enable( WDTO_500MS );

}
Exemple #4
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//------------- Private methods - dont call directly -----
static void __spiSWInit(SPI_ABSTRACT_BUS* _spi, boolean master){
	SPI_SW* spi = (SPI_SW*)_spi;

    if(master){
    	pin_make_output(spi->MOSI, TRUE); 	// make MOSI an output and set high
    	pin_make_input(spi->MISO,TRUE);  	// make MISO an input with a pullup

    }else{
    	pin_make_input(spi->SCLK,FALSE);  	// make clock an input with no pullup
    	pin_make_input(spi->MOSI,FALSE);  	// make MOSI an input with no pullup
    	pin_make_output(spi->MISO,TRUE); 	// make MISO an output
    }

    __spiSWSetClock(_spi,_spi->clock);
    __spiSWSetDataOrder(_spi,_spi->order);
    __spiSWSetMode(_spi,_spi->mode);

}
Exemple #5
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static void setConnected(__ACTUATOR *actuator, boolean connected){
	MOTOR* motor = (MOTOR*)actuator;
	const TimerCompare* channel = compareFromIOPin(motor->pwm);

	// Turn on/off the pin to start/stop sending PWM
	// reverts to default output logic level of low
	compareSetOutputMode(channel, (connected) ? CHANNEL_MODE_NON_INVERTING : CHANNEL_MODE_DISCONNECT);
	pin_make_output(motor->direction1,FALSE);
}
Exemple #6
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// Set up PWM on the given pin
boolean pwmInitDeciHertz(const IOPin* pin, uint32_t deciHertz, PERCENTAGE duty, uint32_t* actualDeciHertz){
	boolean rtn = FALSE;
	const TimerCompare* channel = compareFromIOPin(pin);

	if(channel==null){
		setError(PWM_PIN_NOT_AVAILABLE);
	}else{
		// The pin is valid
		// The pin is valid and available
		TIMER_MODE mode;
		uint16_t icr;
		uint16_t prescaler;
		uint32_t actual;

		const Timer* timer = compareGetTimer(channel);

		// Find the best PWM setting
		boolean valid = timerCalcPwm(timer, deciHertz, 100, &mode, &icr, &prescaler, &actual);

		if(!valid){
			// There is no PWM setting that is valid
			setError( (timerIsInUse(timer)) ? PWM_TIMER_IN_USE : TIMER_HAS_NO_PWM );
		}else{
			// Lets set up the PWM
			timerSetMode(timer,mode);
			if(modeIsICR(mode)){
				// Set the ICR
				PORT icrPort = pgm_read_word(&timer->pgm_icr);
				_SFR_MEM16(icrPort)=icr;
			}

			// Mark the channel as in use
//			compareAttach(channel,&nullTimerCompareCallback,0,null);

			// Turn the pin into an output, low
			pin_make_output(pin, FALSE);

			// Turn on the PWM pin output
			compareSetOutputMode(channel, CHANNEL_MODE_NON_INVERTING);

			// Turn on the timer
			timerSetPrescaler(timer,prescaler);

			// Set the initial duty cycle
			pwmSetDutyCycle(pin,duty);

			// Set the return value
			if(actualDeciHertz){
				*actualDeciHertz = actual;
			}

			rtn = TRUE;
		}
	}
	return rtn;
}
Exemple #7
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static void init(SEGLED* led){
	if(!led->initialised){
		for(uint8_t i=0; i<8;i++){
			const IOPin* pin = led->segment[i];
			pin_make_output(pin,FALSE);
		}
		led->initialised=TRUE;

	}
}
Exemple #8
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// Pass the list of motors, the list should be in PROGMEM space to save Flash RAM
// The specified Timer must implement timer compare interrupts and, if so, it will
// use the timer compare channel A (if there is more than one)
void motorL293Init(MOTOR_DRIVER* driver, uint32_t freq){
	// Make sure each servo is set as an output
	for(int i= driver->num_motors-1;i>=0;i--){
		MOTOR* motor = (MOTOR*)pgm_read_word(&driver->motors[i]);

		// Connect motor to driver
		motor->actuator.sclass = &c_l293;

		// Make sure the motor pins are set as output pins
		pin_make_output(motor->pwm, FALSE);
		pin_make_output(motor->direction1, FALSE);
		pin_make_output(motor->direction2, FALSE);

		// Start off braking
		act_setSpeed(motor,DRIVE_SPEED_BRAKE);

		// Indicate the motor is connected
		act_setConnected(motor,TRUE);
	}
}
Exemple #9
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static boolean initPWM(const IOPin* pin, uint32_t deciHertz){
	const TimerCompare* channel = compareFromIOPin(pin);

	if(channel==null){
		setError(PWM_PIN_NOT_AVAILABLE);
		return FALSE;
	}
	if(compareIsInUse(channel)){
		setError(PWM_PIN_IN_USE);
		return FALSE;
	}

	TIMER_MODE mode;
	uint16_t icr;
	uint16_t prescaler;

	const Timer* timer = compareGetTimer(channel);

	// Find the best PWM setting for 10kHz, with 128 steps
	boolean valid = timerCalcPwm(timer, deciHertz, 128, &mode, &icr, &prescaler);

	if(!valid){
		// There is no PWM setting that is valid
		setError( (timerIsInUse(timer)) ? PWM_TIMER_IN_USE : TIMER_HAS_NO_PWM );
	}else{
		// Lets set up the PWM
		if(!timerIsInUse(timer)){
			timerSetMode(timer,mode);
			if(modeIsICR(mode)){
				// Set the ICR
				PORT icrPort = pgm_read_word(&timer->pgm_icr);
				_SFR_MEM16(icrPort)=icr;
			}
		}

		// Make it an output pin and set high for brake
		pin_make_output(pin,TRUE);

		// Use inverting PWM
		compareSetOutputMode(channel,CHANNEL_MODE_INVERTING);

		// Mark the channels as in use
		compareAttach(channel,&nullTimerCompareCallback,0,null);

		// Do this last as it then turns on the timer
		timerSetPrescaler(timer,prescaler);
	}
	return valid;
}
// Read all the values and store into the device
static void __srf04_read(SENSOR* sensor){
	TICK_COUNT duration;

	Devantech_SRF04* device = (Devantech_SRF04*)sensor;

	// initialise the pins
	pin_make_output(device->out,FALSE);		// Set low
	pin_make_input(device->in,FALSE);

	// 10us high trigger pulse
	pin_pulseOut(device->out,10,TRUE);

	// Measure the inbound pulse
	duration = pin_pulseIn(device->in,TRUE);

	device->distance.cm = fraction32(duration, srf04_frac);
}
Exemple #11
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// Call back - for when the speed has been set
static void setSpeed(__ACTUATOR *actuator, DRIVE_SPEED speed){
	MOTOR* motor = (MOTOR*)actuator;
	const TimerCompare* channel = compareFromIOPin(motor->pwm);
	const Timer* timer = compareGetTimer(channel);
	uint16_t top = timerGetTOP(timer);

	// New compare threshold
	uint16_t delay=0;

	if( speed > 0 ){
		delay = interpolateU(speed, 0, DRIVE_SPEED_MAX, 0 , top);

		if(motor->direction2==null){
			// one wire so delay = top - delay
			delay = top - delay;
		}

		// Set direction1 high, direction2 low (if there is one)
		pin_make_output(motor->direction1,TRUE);
		pin_make_output(motor->direction2,FALSE);
	}else if(speed < 0){
		delay = interpolateU(speed, 0, DRIVE_SPEED_MIN,  0 , top);

		// Set direction1 low, direction2 high (if there is one)
		pin_make_output(motor->direction1,FALSE);
		pin_make_output(motor->direction2,TRUE);
	}else{
		// brake
		if(motor->direction2){
			// There are two direction pins - so set both to same value
			pin_make_output(motor->direction1,FALSE);
			pin_make_output(motor->direction2,FALSE);
			delay = top; // full speed brake
		}else{
			// Only has one direction pin
			// Set direction1 low
			pin_make_output(motor->direction1,FALSE);
			// PWM delay = 0 so pwm = low
			// ie both low = brake
		}
	}

	// Change the duty cycle
	compareSetThreshold(channel,delay);
}
Exemple #12
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// Call back - for when the speed has been set
static void setSpeed(__ACTUATOR *actuator, DRIVE_SPEED speed){
	MOTOR* motor = (MOTOR*)actuator;
	const TimerCompare* channel = compareFromIOPin(motor->pwm);
	const Timer* timer = compareGetTimer(channel);
	uint16_t top = timerGetTOP(timer);

	// New compare threshold
	uint16_t delay=0;

	if( speed > 0 ){
		delay = interpolateU(speed, 0, DRIVE_SPEED_MAX, 0 , top);

		// Set direction1 high, direction2 low
		pin_make_output(motor->direction1,TRUE);
		pin_make_output(motor->direction2,FALSE);
	}else if(speed < 0){
		delay = interpolateU(speed, 0, DRIVE_SPEED_MIN,  0 , top);

		// Set direction1 low, direction2 high low
		pin_make_output(motor->direction1,FALSE);
		pin_make_output(motor->direction2,TRUE);
	}else{
		// brake

		if(motor->direction2){
			// There are two direction pins - so set both to same value
			pin_make_output(motor->direction1,FALSE);
			pin_make_output(motor->direction2,FALSE);
		}else{
			// Only has one direction pin
			// Set direction1 to an input with no pullup ie disconnect
			pin_make_input(motor->direction1,FALSE);
		}
	}

	// Change the duty cycle
	compareSetThreshold(channel,delay);
}
Exemple #13
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// Make all databus pins into outputs
static void databus_output(const HD44780* device){
	for(uint8_t i=0; i<8; i++){
		pin_make_output(device->data[i],TRUE);
	}
}
Exemple #14
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// Make the data line low
static void sda_low(const I2C_SOFTWARE_BUS* i2c){
	pin_make_output(i2c->sda,FALSE);
}
Exemple #15
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static void __spiSWSetMode(SPI_ABSTRACT_BUS* _spi,SPI_MODE mode){
	SPI_SW* spi = (SPI_SW*)_spi;
	// Set the clock to its initial state
	pin_make_output(spi->SCLK, (mode == SPI_MODE_2 || mode == SPI_MODE_3));
}