Ejemplos de ADC_BurstCmd en C++ (Cpp)

Lenguaje de programación: C++ (Cpp)

Método / Función: ADC_BurstCmd

Ejemplos en hotexamples.com: 2

C++ (Cpp) ADC_BurstCmd - 2 ejemplos encontrados. Estos son los ejemplos en C++ (Cpp) del mundo real mejor valorados de ADC_BurstCmd extraídos de proyectos de código abierto. Puedes valorar ejemplos para ayudarnos a mejorar la calidad de los ejemplos.

Ejemplo n.º 1

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Archivo: Adc_Burst.c Proyecto: satyanarayangullapalli/arm_lpc_1788_sdk

/*********************************************************************//**
 * @brief		c_entry: Main ADC program body
 * @param[in]	None
 * @return 		None
 **********************************************************************/
void c_entry(void)
{
	volatile uint32_t tmp;
#if !__DMA_USED__
	uint32_t adc_value;
#endif
    uint8_t  quit;
	EXTI_InitTypeDef EXTICfg;
#if __DMA_USED__
    GPDMA_Channel_CFG_Type GPDMACfg;
#endif
	
	GPIO_Init();
	
	/* Initialize debug via UART0
	* – 115200bps
	* – 8 data bit
	* – No parity
	* – 1 stop bit
	* – No flow control
	*/
	debug_frmwrk_init();

	// print welcome screen
	print_menu();

	/*
	* Init ADC pin connect
	* AD0.2 on P0.25
	*/
	PINSEL_ConfigPin(BRD_ADC_PREPARED_CH_PORT, BRD_ADC_PREPARED_CH_PIN, BRD_ADC_PREPARED_CH_FUNC_NO);
	PINSEL_SetAnalogPinMode(BRD_ADC_PREPARED_CH_PORT,BRD_ADC_PREPARED_CH_PIN,ENABLE);

#ifdef LPC177x_8x_ADC_BURST_MULTI
	/*
	* Init ADC pin connect
	* AD0.3 on P0.26
	*/
	PINSEL_ConfigPin(0, 26, 1);
    PINSEL_SetAnalogPinMode(0,26,ENABLE);

#endif

	/* Configuration for ADC:
	*  select: ADC channel 2
	*  		ADC channel 3
	*  ADC conversion rate = 400KHz
	*/
	ADC_Init(LPC_ADC, 400000);
	ADC_ChannelCmd(LPC_ADC,BRD_ADC_PREPARED_CHANNEL,ENABLE);

#ifdef LPC177x_8x_ADC_BURST_MULTI
    ADC_ChannelCmd(LPC_ADC,_ADC_CHANNEL_n,ENABLE);
#endif

#ifdef LPC177x_8x_ADC_INJECT_TEST
	//Config P2.10 as EINT0
	PINSEL_ConfigPin(2,10,1);
	EXTI_Init();

	EXTICfg.EXTI_Line = EXTI_EINT0;
	/* edge sensitive */
	EXTICfg.EXTI_Mode = EXTI_MODE_EDGE_SENSITIVE;
	EXTICfg.EXTI_polarity = EXTI_POLARITY_LOW_ACTIVE_OR_FALLING_EDGE;

	EXTI_Config(&EXTICfg);
	GPIO_SetDir(LED_PORT,LED_PIN,1);
	GPIO_SetValue(LED_PORT,LED_PIN);

	NVIC_EnableIRQ(EINT0_IRQn);
#endif

#if __DMA_USED__
     /* Initialize GPDMA controller */
	GPDMA_Init();

	// Setup GPDMA channel --------------------------------
	// channel 0
	GPDMACfg.ChannelNum = 0;
	// Source memory - unused
	GPDMACfg.SrcMemAddr = 0;
	// Destination memory
	GPDMACfg.DstMemAddr = (uint32_t)s_buf;
	// Transfer size
	GPDMACfg.TransferSize = DMA_SIZE;
	// Transfer width - unused
	GPDMACfg.TransferWidth = 0;
	// Transfer type
	GPDMACfg.TransferType = GPDMA_TRANSFERTYPE_P2M;
	// Source connection
	GPDMACfg.SrcConn = GPDMA_CONN_ADC;
	// Destination connection - unused
	GPDMACfg.DstConn = 0;
	// Linker List Item - unused
	GPDMACfg.DMALLI = 0;
	
	/* Enable GPDMA interrupt */
	NVIC_EnableIRQ(DMA_IRQn);

    while(1)
    {
		 for(tmp = 0; tmp < 0x1000; tmp++);
        /* Reset terminal counter */
	    Channel0_TC = 0;
	    /* Reset Error counter */
	    Channel0_Err = 0;
        for(tmp = 0; tmp < DMA_SIZE; tmp++)
        {
            s_buf[tmp] = 0;
        }
         //Start burst conversion
        ADC_BurstCmd(LPC_ADC,ENABLE);

        GPDMA_Setup(&GPDMACfg);
        // Enable GPDMA channel 1
        GPDMA_ChannelCmd(0, ENABLE);
         /* Wait for GPDMA processing complete */
    	while ((Channel0_TC == 0));
        GPDMA_ChannelCmd(0, DISABLE);
        
         for(tmp = 0; tmp < DMA_SIZE; tmp++)
          {
                if(s_buf[tmp] & ADC_GDR_DONE_FLAG)
                {
                    _DBG("ADC value on channel "); _DBD(ADC_GDR_CH(s_buf[tmp])); _DBG(": ");
                    _DBD32(ADC_GDR_RESULT(s_buf[tmp]));_DBG_("");
                }
          }
          if(_DG_NONBLOCK(&quit) &&
			(quit == 'Q' || quit == 'q'))
			break;
    }
#else
	//Start burst conversion
	ADC_BurstCmd(LPC_ADC,ENABLE);

	while(1)
	{
		adc_value =  ADC_ChannelGetData(LPC_ADC,BRD_ADC_PREPARED_CHANNEL);
		_DBG("ADC value on channel "); _DBD(BRD_ADC_PREPARED_CHANNEL); _DBG(": ");
		_DBD32(adc_value);
		_DBG_("");

#ifdef LPC177x_8x_ADC_BURST_MULTI
		adc_value =  ADC_ChannelGetData(LPC_ADC,_ADC_CHANNEL_n);
		_DBG("ADC value on channel 3: ");
		_DBD32(adc_value);
		_DBG_("");
#endif
		// Wait for a while
		for(tmp = 0; tmp < 1500000; tmp++);

		if(_DG_NONBLOCK(&quit) &&
			(quit == 'Q' || quit == 'q'))
			break;
	}
#endif /*__DMA_USED__*/

    _DBG_("Demo termination!!!");
	ADC_DeInit(LPC_ADC);
	
	GPIO_Deinit();
	
}

Ejemplo n.º 2

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Archivo: adc_burst_test.c Proyecto: readermank/kico_si5

/*********************************************************************//**
 * @brief		c_entry: Main ADC program body
 * @param[in]	None
 * @return 		int
 **********************************************************************/
int c_entry(void)
{
	PINSEL_CFG_Type PinCfg;
#ifdef MCB_LPC_1768_ADC_BURST_MULTI
	PINSEL_CFG_Type PinCfg1;
#endif
	uint32_t tmp;
	uint32_t adc_value;
	/* Initialize debug via UART0
	 * – 115200bps
	 * – 8 data bit
	 * – No parity
	 * – 1 stop bit
	 * – No flow control
	 */
	debug_frmwrk_init();

	// print welcome screen
	print_menu();

	/* Because the potentiometer on different boards (MCB & IAR) connect
	 * with different ADC channel, so we have to configure correct ADC channel
	 * on each board respectively.
	 * If you want to check other ADC channels, you have to wire this ADC pin directly
	 * to potentiometer pin (please see schematic doc for more reference)
	 */
#ifdef MCB_LPC_1768
	/*
	 * Init ADC pin connect
	 * AD0.2 on P0.25
	 */
	PinCfg.Funcnum = 1;
	PinCfg.OpenDrain = 0;
	PinCfg.Pinmode = 0;
	PinCfg.Pinnum = 25;
	PinCfg.Portnum = 0;
	PINSEL_ConfigPin(&PinCfg);
#ifdef MCB_LPC_1768_ADC_BURST_MULTI
	/*
	 * Init ADC pin connect
	 * AD0.3 on P0.26
	 */
	PinCfg1.Funcnum = 1;
	PinCfg1.OpenDrain = 0;
	PinCfg1.Pinmode = 0;
	PinCfg1.Pinnum = 26;
	PinCfg1.Portnum = 0;
	PINSEL_ConfigPin(&PinCfg1);
#endif
#elif defined (IAR_LPC_1768)
	/* select P1.31 as AD0.5 */
	PinCfg.Funcnum = 3;
	PinCfg.OpenDrain = 0;
	PinCfg.Pinmode = 0;
	PinCfg.Pinnum = 31;
	PinCfg.Portnum = 1;
	PINSEL_ConfigPin(&PinCfg);
#endif


	/* Configuration for ADC:
	 *  select: ADC channel 2 (if using MCB1700 board)
	 *  		ADC channel 5 (if using IAR-LPC1768 board)
	 *  ADC conversion rate = 200KHz
	 */
	ADC_Init(LPC_ADC, 200000);
	ADC_ChannelCmd(LPC_ADC,_ADC_CHANNEL,ENABLE);
#ifdef MCB_LPC_1768_ADC_BURST_MULTI
	ADC_ChannelCmd(LPC_ADC,_ADC_CHANNEL_3,ENABLE);
#endif

#ifdef MCB_LPC17XX_ADC_INJECT_TEST
	FIO_ByteSetDir(1, 3, POLL_LED, 1);
	FIO_ByteClearValue(1, 3, POLL_LED);
	// Enable GPIO interrupt P2.10
	GPIO_IntCmd(2,(1<<10),1);
	NVIC_EnableIRQ(EINT3_IRQn);
#endif

	//Start burst conversion
	ADC_BurstCmd(LPC_ADC,ENABLE);
	while(1)
	{
#ifdef MCB_LPC_1768
		adc_value =  ADC_ChannelGetData(LPC_ADC,ADC_CHANNEL_2);
		_DBG("ADC value on channel 2: ");
#elif defined (IAR_LPC_1768)
		adc_value =  ADC_ChannelGetData(LPC_ADC,ADC_CHANNEL_5);
		_DBG("ADC value on channel 5: ");
#endif
		_DBD32(adc_value);
		_DBG_("");
#ifdef MCB_LPC_1768_ADC_BURST_MULTI
		adc_value =  ADC_ChannelGetData(LPC_ADC,ADC_CHANNEL_3);
		_DBG("ADC value on channel 3: ");
		_DBD32(adc_value);
		_DBG_("");
#endif
		// Wait for a while
		for(tmp = 0; tmp < 1500000; tmp++);
	}
	ADC_DeInit(LPC_ADC);
	return (0);
}