/******************************************************************************
Function Name : ADC0__Config (from Inga Harris' Nucleus ADC0_ Validation)
Engineer : r54940
Date : 04/08/08
Parameters :
Returns : NONE
Notes : Configures ADC0_
******************************************************************************/
void ADC_Config(ADC_MemMapPtr adcmap, uint8_t CONFIG1, uint8_t CONFIG2, uint16_t COMPARE1, uint16_t COMPARE2, uint8_t STATUS2, uint8_t STATUS3, uint8_t STATUS1A, uint8_t STATUS1B, uint32_t PGA )
{
ADC_CFG1_REG(adcmap) = CONFIG1;
ADC_CFG2_REG(adcmap) = CONFIG2;
ADC_CV1_REG(adcmap) = COMPARE1;
ADC_CV2_REG(adcmap) = COMPARE2;
ADC_SC2_REG(adcmap) = STATUS2;
ADC_SC3_REG(adcmap) = STATUS3;
ADC_SC1_REG(adcmap,A) = STATUS1A;
ADC_SC1_REG(adcmap,B) = STATUS1B;
ADC_PGA_REG(adcmap) = PGA;
}
void ADC_Config_Alt(ADC_MemMapPtr adcmap, tADC_ConfigPtr ADC_CfgPtr)
{
ADC_CFG1_REG(adcmap) = ADC_CfgPtr->CONFIG1;
ADC_CFG2_REG(adcmap) = ADC_CfgPtr->CONFIG2;
ADC_CV1_REG(adcmap) = ADC_CfgPtr->COMPARE1;
ADC_CV2_REG(adcmap) = ADC_CfgPtr->COMPARE2;
ADC_SC2_REG(adcmap) = ADC_CfgPtr->STATUS2;
ADC_SC3_REG(adcmap) = ADC_CfgPtr->STATUS3;
//ADC_PGA_REG(adcmap) = ADC_CfgPtr->PGA; pbd
ADC_SC1_REG(adcmap,A)= ADC_CfgPtr->STATUS1A;
ADC_SC1_REG(adcmap,B)= ADC_CfgPtr->STATUS1B;
}
void Io_Adc_Autoscan(void)
{
Io_Adc_Data -> current_cnv_channel = 0;
Io_Int_DisableInterrupts();
/*Read the configuration from the configuration structure of the current channel*/
ADC_CFG2_REG(ADC0) = ADC_CFG2_DEFAULT | Io_Adc_ConfigPtr->adc_config_channel[Io_Adc_Data->current_cnv_channel].adc_channel_config2;
ADC_CFG1_REG(ADC0) = ADC_CFG1_DEFAULT | Io_Adc_ConfigPtr->adc_config_channel[Io_Adc_Data->current_cnv_channel].adc_channel_config1;
/*If software trigger is selected, conversion begins after SC1A is written */
ADC_SC1_REG(ADC0,S1A) = IO_ADC_SC1_INTERRUPT_ENABLE_MASK | IO_ADC_SC1_SE_CONVERSION | Io_Adc_ConfigPtr->adc_config_channel[Io_Adc_Data->current_cnv_channel].adc_channel_ID;
Io_Adc_Data->conversion_ongoing = 1;
/* Re-enable interrupts */
Io_Int_EnableInterrupts();
}
void Io_Adc_Isr(void)
{
uint16 result;
Io_Adc_Data->conversion_ongoing = 0;
Io_Int_DisableInterrupts();
/* Store the value of the last conversion */
result = ADC_R_REG(ADC0,S1A);
/* Conversion value is written in the specific adc_channel_value */
Io_Adc_Data->adc_ch_data[Io_Adc_Data->current_cnv_channel].adc_channel_value = result;
Io_Adc_Data->adc_ch_data[Io_Adc_Data->current_cnv_channel].valid = VALID;
/* Increment the channel */
Io_Adc_Data->current_cnv_channel++;
/* Check if current channel is not the last one */
if (Io_Adc_Data->current_cnv_channel<Io_Adc_ConfigPtr->adc_number_of_channels)
{
/*Read the configuration from the configuration structure of the current channel*/
ADC_CFG2_REG(ADC0) = ADC_CFG2_DEFAULT | Io_Adc_ConfigPtr->adc_config_channel[Io_Adc_Data->current_cnv_channel].adc_channel_config2;
ADC_CFG1_REG(ADC0) = ADC_CFG1_DEFAULT | Io_Adc_ConfigPtr->adc_config_channel[Io_Adc_Data->current_cnv_channel].adc_channel_config1;
/* Restart the conversion for next channel */
ADC_SC1_REG(ADC0,S1A) = IO_ADC_SC1_INTERRUPT_ENABLE_MASK | IO_ADC_SC1_SE_CONVERSION | Io_Adc_ConfigPtr->adc_config_channel[Io_Adc_Data->current_cnv_channel].adc_channel_ID;;
/* Conversion ongoing is set */
Io_Adc_Data->conversion_ongoing = 1;
}
/* Re-enable interrupts */
Io_Int_EnableInterrupts();
}
int adc_init() {
adc_pixelIndex = 0;
// disable ADC irq - not ready yet
disable_irq(ADC_IRQ_NUM);
// turn on clock to ADC0
SIM_SCGC6 |= (SIM_SCGC6_ADC0_MASK);
// to setup SW trigger on FTM2
SIM_SOPT7 = SIM_SOPT7_ADC0TRGSEL(10);
// to calibrate the ADC module
unsigned short cal_var;
cal_var = 0x0000;
// add the plus-side calibration results
cal_var += ADC_CLP0_REG(ADC0_BASE_PTR);
cal_var += ADC_CLP1_REG(ADC0_BASE_PTR);
cal_var += ADC_CLP2_REG(ADC0_BASE_PTR);
cal_var += ADC_CLP3_REG(ADC0_BASE_PTR);
cal_var += ADC_CLP4_REG(ADC0_BASE_PTR);
cal_var += ADC_CLPS_REG(ADC0_BASE_PTR);
cal_var /= 2;
cal_var |= 0x8000;
// store value in plus-side gain calibration register (PG)
ADC_PG_REG(ADC0_BASE_PTR) = ADC_PG_PG(cal_var);
cal_var = 0x0000;
// add the minus-side calibration results
cal_var += ADC_CLM0_REG(ADC0_BASE_PTR);
cal_var += ADC_CLM1_REG(ADC0_BASE_PTR);
cal_var += ADC_CLM2_REG(ADC0_BASE_PTR);
cal_var += ADC_CLM3_REG(ADC0_BASE_PTR);
cal_var += ADC_CLM4_REG(ADC0_BASE_PTR);
cal_var += ADC_CLMS_REG(ADC0_BASE_PTR);
cal_var /= 2;
cal_var |= 0x8000;
// store value in minus-side gain calibration register (MG)
ADC_MG_REG(ADC0_BASE_PTR) = ADC_MG_MG(cal_var);
ADC_SC3_REG(ADC0_BASE_PTR) &= ~ADC_SC3_CAL_MASK;
// to set the configuration register 1 (CFG1) to select the mode of
// operation, clock source, clock divide, and configuration for low
// power or long sample time
ADC_CFG1_REG(ADC0_BASE_PTR) = ADLPC_NORMAL
| ADC_CFG1_ADIV(ADIV_1)
| ADLSMP_SHORT
| ADC_CFG1_MODE(MODE_8)
| ADC_CFG1_ADICLK(ADICLK_BUS);
// to set the configuration register 2 (CFG2) to select the special
// high-speed configuration for very high speed conversions and
// select the long sample time duration during long sample mode
ADC_CFG2_REG(ADC0_BASE_PTR) = MUXSEL_ADCA
| ADACKEN_DISABLED
| ADHSC_HISPEED
| ADC_CFG2_ADLSTS(ADLSTS_2);
// to configure the status and control register 2 (SC2)
ADC_SC2_REG(ADC0_BASE_PTR) = ADTRG_SW
| ACFE_DISABLED
| ACFGT_GREATER
| ACREN_DISABLED
| DMAEN_DISABLED
| ADC_SC2_REFSEL(REFSEL_EXT);
// to configure the status and control register 3 (SC3)
// enable hw averaging, 16 samples taken
ADC_SC3_REG(ADC0_BASE_PTR) = CAL_OFF
| ADCO_SINGLE
| AVGE_ENABLED
| ADC_SC3_AVGS(AVGS_16);
// to configure the status and control register 1 (SC1)
// enable the interrupt, single-ended conversion, on AD18
ADC_SC1_REG(ADC0_BASE_PTR, A)= AIEN_ON
| DIFF_SINGLE
| ADC_SC1_ADCH(18);
// to configure the PGA register
ADC_PGA_REG(ADC0_BASE_PTR) = PGAEN_DISABLED
| PGACHP_NOCHOP
| PGALP_NORMAL
| ADC_PGA_PGAG(PGAG_64);
// enable ADC irq
enable_irq(ADC_IRQ_NUM);
return ADC_RET_SUCCESS;
}
//============================================================================
//函数名称:hw_ad_once
//函数返回:16位无符号的AD值
//参数说明:MoudelNumber:模块号
// Channel:通道号
// accuracy:精度
//功能概要:采集一次一路模拟量的AD值
//============================================================================
uint16 hw_adc_once(int MoudelNumber,int Channel,uint8 accuracy)//采集某路模拟量的AD值
{
uint16 result = 0;
uint8 ADCCfg1Mode = 0;
ADC_MemMapPtr ADCMoudel;//保存ADC模块地址指针
switch(accuracy)
{
case 8:
ADCCfg1Mode = 0x00;
break;
case 12:
ADCCfg1Mode = 0x01;
break;
case 10:
ADCCfg1Mode = 0x02;
break;
case 16:
ADCCfg1Mode = 0x03;
break;
default:
ADCCfg1Mode = 0x00;
}
if(MoudelNumber==0)//选择ADC模块0
{
ADCMoudel = ADC0_BASE_PTR;
}
else //选择ADC模块1
{
ADCMoudel = ADC1_BASE_PTR;
}
//配置正常电源模式,总线时钟,总线时钟4分频,长采样时间使能,设置精度
ADC_CFG1_REG(ADCMoudel) = ADLPC_NORMAL
| ADC_CFG1_ADIV(ADIV_4)
| ADLSMP_LONG
| ADC_CFG1_MODE(ADCCfg1Mode)
| ADC_CFG1_ADICLK(ADICLK_BUS);
//配置禁止异步时钟使能输出,ADxxat通道选择,高速配置,长采样时间
ADC_CFG2_REG(ADCMoudel) = MUXSEL_ADCA
| ADACKEN_DISABLED
| ADHSC_HISPEED
| ADC_CFG2_ADLSTS(ADLSTS_20) ;
//设置通道号
ADC_SC1_REG(ADCMoudel,A) = AIEN_ON | DIFF_SINGLE | ADC_SC1_ADCH(Channel);
//等待转换完成
while (( ADC_SC1_REG(ADCMoudel,A) & ADC_SC1_COCO_MASK ) != ADC_SC1_COCO_MASK)
{
}
//读取转化结果
result = ADC_R_REG(ADCMoudel,A);
//清ADC转换完成标志
ADC_SC1_REG(ADCMoudel,A) &= ~ADC_SC1_COCO_MASK;
return result;
}
int adcc_init(int adc_num)
{
//PORT_MemMapPtr pctl = NULL;
//uint8_t gpio_port;
/* led pin init */
if(!lwgpio_init(&pm2p5_ledgpio, PM2P5_LED_PWREN, LWGPIO_DIR_OUTPUT, LWGPIO_VALUE_NOCHANGE)) {
printf("Initializing GPIO with associated pins failed.\n");
_time_delay (200L);
_task_block();
}
lwgpio_set_functionality(&pm2p5_ledgpio, PM2P5_LED_MUX_GPIO);
//lwgpio_set_value(&pm2p5_ledgpio, LWGPIO_VALUE_LOW);
lwgpio_set_value(&pm2p5_ledgpio, LWGPIO_VALUE_HIGH);
if(adc_num == 0) {
/* SIM_SCGC6: ADC0=1 */
adc_ptr = ADC0_BASE_PTR;
SIM_SCGC6 |= SIM_SCGC6_ADC0_MASK;
}
else {
adc_ptr = ADC1_BASE_PTR;
SIM_SCGC6 |= SIM_SCGC6_ADC1_MASK;
}
#ifdef ADC_HW_TRIGER
SIM_SCGC6 |= SIM_SCGC6_PIT_MASK; /* enable PIT */
SIM_SOPT7 |= SIM_SOPT7_ADC1ALTTRGEN_MASK;
SIM_SOPT7 |= (SIM_SOPT7_ADC1PRETRGSEL_MASK); /* Pre Trigger B */
SIM_SOPT7 &= ~(SIM_SOPT7_ADC1TRGSEL_MASK);
SIM_SOPT7 |= SIM_SOPT7_ADC1TRGSEL(7); /* PIT trigger 3 */
PIT_MCR_REG(PIT_BASE_PTR) = 0;
#endif
// pin mux config : spec P216 ADC0_DP0/ADC1_DP3 is default
/* set pin's multiplexer to analog
gpio_port = ADC_SIG_PORTB | 4;
pctl = (PORT_MemMapPtr) PORTB_BASE_PTR;
pctl->PCR[gpio_port & 0x1F] &= ~PORT_PCR_MUX_MASK;
*/
// Initialize ADC0/1 =================================================================================
//averages (4 h/w) // bus 60M /8/2 = 3.75M ADC clock
ADC_CFG1_REG(adc_ptr) = ADLPC_NORMAL | ADC_CFG1_ADIV(ADIV_8) /*| ADLSMP_LONG*/ | ADC_CFG1_MODE(MODE_16)
| ADC_CFG1_ADICLK(/*ADICLK_BUS_2*/ADICLK_BUS);
// do calibration
if(adc_calibrate(adc_ptr))
printf("adc-%x calibrate failed\n",(int)adc_ptr);
/* channel A/B selected */
#ifdef ADC_HW_TRIGER
ADC_CFG2_REG(adc_ptr) = MUXSEL_ADCB | ADACKEN_ENABLED | ADHSC_HISPEED | ADC_CFG2_ADLSTS(ADLSTS_20);
#else
ADC_CFG2_REG(adc_ptr) = MUXSEL_ADCA /*| ADACKEN_ENABLED */| ADHSC_HISPEED | ADC_CFG2_ADLSTS(ADLSTS_20);
#endif
//ADC_CV1_REG(adc_ptr) = 0x0;
//ADC_CV2_REG(adc_ptr) = 0x0;
//ADC_SC1_REG(adc_ptr,0) = AIEN_ON | DIFF_SINGLE | ADC_SC1_ADCH(ADC_INPUT_CH); /* SC1 A */
//ADC_SC1_REG(adc_ptr,1) = AIEN_ON | DIFF_SINGLE | ADC_SC1_ADCH(ADC_INPUT_CH); /* SC1 B */
#ifdef ADC_HW_TRIGER
ADC_SC2_REG(adc_ptr) = ADTRG_HW /*ADTRG_SW*/ | ACFE_DISABLED | ACFGT_GREATER | ACREN_DISABLED
| DMAEN_DISABLED /* DMAEN_ENABLED*/| ADC_SC2_REFSEL(REFSEL_EXT);
#else
ADC_SC2_REG(adc_ptr) = ADTRG_SW /*| ACFE_DISABLED | ACFGT_GREATER | ACREN_DISABLED
| DMAEN_DISABLED*/ | ADC_SC2_REFSEL(REFSEL_EXT);
#endif
ADC_SC3_REG(adc_ptr) = /*ADC_SC3_CALF_MASK |*/ CAL_OFF | ADCO_SINGLE /*| AVGE_ENABLED | ADC_SC3_AVGS(AVGS_4)*/; /* averages 4 h/w */
}
