/**
 * \brief ADCIFB ISR Routine
 */
ISR(ADCIFB_interrupt_handler, AVR32_ADCIFB_IRQ_GROUP, ADC_INTERRUPT_PRIORITY)
{
	/* Get the ADC output */
	adc_output = adcifb_get_last_data(adcifb);
	/* Clear the ADCIFB interrupt */
	adcifb_clear_compare_gt_interrupt_flag(adcifb);
	adcifb->ISR;
} /* End of ISR routine */
Beispiel #2
0
/** \brief Main function - init and loop to display ADC values */
int main(void)
{
	/* GPIO pin/ADC-function map. */
	const gpio_map_t ADCIFB_GPIO_MAP = {
		{EXAMPLE_ADCIFB_PIN, EXAMPLE_ADCIFB_FUNCTION}
	};
	
	/* ADCIFB Configuration */
	adcifb_opt_t adcifb_opt = {
		/* Resolution mode */
		.resolution = AVR32_ADCIFB_ACR_RES_12BIT,

		/* Channels Sample & Hold Time in [0,15] */
		.shtim  = 15,
		.ratio_clkadcifb_clkadc =
				(sysclk_get_pba_hz() / EXAMPLE_TARGET_CLK_ADC_FREQ_HZ),

		/*
		 * Startup time in [0,127], where
		 * Tstartup = startup * 8 * Tclk_adc (assuming Tstartup ~ 15us max)
		 */
		.startup = 3,
		
		/* ADCIFB Sleep Mode disabled */
		.sleep_mode_enable = false
	};
	
	uint32_t adc_data;

	/* Initialize the system clocks */
	sysclk_init();

	/* Init debug serial line */
	init_dbg_rs232(sysclk_get_pba_hz());

	/* Assign and enable GPIO pins to the ADC function. */
	gpio_enable_module(ADCIFB_GPIO_MAP,
			sizeof(ADCIFB_GPIO_MAP) / sizeof(ADCIFB_GPIO_MAP[0]));

	/* Enable and configure the ADCIFB module */
	if (adcifb_configure(&AVR32_ADCIFB, &adcifb_opt) != PASS) {
		/* Config error. */
		while (true) {
			gpio_tgl_gpio_pin(LED0_GPIO);
			
			delay_ms(100);
		}
	}

	/* Configure the trigger mode */
	/* "No trigger, only software trigger can start conversions". */
	if (adcifb_configure_trigger(&AVR32_ADCIFB, AVR32_ADCIFB_TRGMOD_NT, 0)
			!= PASS) {
		/* Config error. */
		while (true) {
			gpio_tgl_gpio_pin(LED1_GPIO);
			
			delay_ms(100);
		}
	}

	/* Enable the ADCIFB channel the battery is connected to. */
	adcifb_channels_enable(&AVR32_ADCIFB, EXAMPLE_ADCIFB_CHANNEL_MASK);

	while (true) {
		while (adcifb_is_ready(&AVR32_ADCIFB) != true) {
			/* Wait until the ADC is ready to perform a conversion. */
		}

		/* Start an ADCIFB conversion sequence. */
		adcifb_start_conversion_sequence(&AVR32_ADCIFB);

		while (adcifb_is_drdy(&AVR32_ADCIFB) != true) {
			/* Wait until the converted data is available. */
		}

		/* Get the last converted data. */
		adc_data = adcifb_get_last_data(&AVR32_ADCIFB);

		/* Display the current voltage of the battery. */
		print_dbg("\x1B[2J\x1B[H\r\nADCIFB Example\r\nHEX Value for "
				EXAMPLE_ADCIFB_CHANNEL_NAME " : 0x");
		print_dbg_hex(adc_data & AVR32_ADCIFB_LCDR_LDATA_MASK);
		print_dbg("\r\n");
		
		delay_ms(500);

		/*
		 * Note1: there is a resistor bridge between the battery and the
		 * ADC pad on the AT32UC3L-EK. The data converted is thus half
		 * of
		 * the battery voltage.
		 */

		/*
		 * Note2: if the battery is not in place, the conversion is out
		 * of
		 * spec because the ADC input is then higher than ADVREF.
		 */
	}
}
Beispiel #3
0
/**
 * \brief Initialize ADC driver to read the board temperature sensor.
 *
 * Initializes the board's ADC driver module and configures the ADC channel
 * connected to the onboard NTC temperature sensor ready for conversions.
 */
static void init_adc(void)
{
	// Assign and enable GPIO pin to the ADC function.
	gpio_enable_module_pin(ADC_TEMPERATURE_PIN, ADC_TEMPERATURE_FUNCTION);

	const adcifb_opt_t adcifb_opt = {
		.resolution             = AVR32_ADCIFB_ACR_RES_12BIT,
		.shtim                  = 15,
		.ratio_clkadcifb_clkadc = 2,
		.startup                = 3,
		.sleep_mode_enable      = false
	};

	// Enable and configure the ADCIFB module
	sysclk_enable_peripheral_clock(&AVR32_ADCIFB);
	adcifb_configure(&AVR32_ADCIFB, &adcifb_opt);

	// Configure the trigger (No trigger, only software trigger)
	adcifb_configure_trigger(&AVR32_ADCIFB, AVR32_ADCIFB_TRGMOD_NT, 0);

	// Enable the ADCIFB channel to NTC temperature sensor
	adcifb_channels_enable(&AVR32_ADCIFB, ADC_TEMPERATURE_CHANNEL);
}

/**
 * \brief Initializes the USART.
 *
 * Initializes the board USART ready for serial data to be transmitted and
 * received.
 */
static void init_usart(void)
{
	const usart_options_t usart_options = {
		.baudrate     = 57600,
		.charlength   = 8,
		.paritytype   = USART_NO_PARITY,
		.stopbits     = USART_1_STOPBIT,
		.channelmode  = USART_NORMAL_CHMODE
	};

	// Initialize USART in RS232 mode with the requested settings.
	sysclk_enable_peripheral_clock(USART);
	usart_init_rs232(USART, &usart_options, sysclk_get_pba_hz());
}

/**
 * \brief Initializes the PWM subsystem ready to generate the RGB LED PWM
 * waves.
 *
 * Initializes the on-chip PWM module and configures the RGB LED PWM outputs so
 * the the brightness of the three individual channels can be adjusted.
 */
static void init_pwm(void)
{
	// GPIO pin/function map for the RGB LEDs.
	gpio_enable_module_pin(LED_RED_PWMA,   LED_PWMA_FUNCTION);
	gpio_enable_module_pin(LED_GREEN_PWMA, LED_PWMA_FUNCTION);
	gpio_enable_module_pin(LED_BLUE_PWMA,  LED_PWMA_FUNCTION);

	const scif_gclk_opt_t genclk3_opt = {
		.clock_source = SCIF_GCCTRL_CPUCLOCK,
		.divider      = 8,
		.diven        = true,
	};

	// Start generic clock 3 for the PWM outputs.
	scif_start_gclk(AVR32_PM_GCLK_GCLK3, &genclk3_opt);

	// Enable RGB LED PWM.
	sysclk_enable_peripheral_clock(&AVR32_PWMA);
	pwma_config_enable(&AVR32_PWMA,EXAMPLE_PWMA_FREQUENCY,EXAMPLE_PWMA_GCLK_FREQUENCY,0); 
	pwma_set_channels_value(&AVR32_PWMA,PWM_CHANNEL_RED | PWM_CHANNEL_BLUE| PWM_CHANNEL_GREEN,255);

}

/**
 * \brief Application main loop.
 */
int main(void)
{
	board_init();
	sysclk_init();

	sysclk_enable_peripheral_clock(USART);

	// Initialize touch, ADC, USART and PWM
	init_adc();
	init_usart();
	init_pwm();
	init_touch();

	while (true) {
		uint32_t adc_data;

		// Read slider and button and update RGB led
		touch_handler();

		// Wait until the ADC is ready to perform a conversion.
		do { } while (!adcifb_is_ready(&AVR32_ADCIFB));

		// Start an ADCIFB conversion sequence.
		adcifb_start_conversion_sequence(&AVR32_ADCIFB);

		// Wait until the converted data is available.
		do { } while (!adcifb_is_drdy(&AVR32_ADCIFB));

		// Get the last converted data.
		adc_data = (adcifb_get_last_data(&AVR32_ADCIFB) & 0x3FF);

		// Write temperature data to USART
		do { } while (!usart_tx_empty(USART));
		usart_write_char(USART, (adc_data >> 8));
		do { } while (!usart_tx_empty(USART));
		usart_write_char(USART, (adc_data & 0xFF));
	}
}