/*lint -save -e970 Disable MISRA rule (6.3) checking. */
int main(void)
/*lint -restore Enable MISRA rule (6.3) checking. */
{
/* Write your local variable definition here */
uint32_t currentCounter = 0;
/*** Processor Expert internal initialization. DON'T REMOVE THIS CODE!!! ***/
PE_low_level_init();
/*** End of Processor Expert internal initialization. ***/
hw_average_config.hwAverageCountMode = kAdc16HwAverageCountOf32; //enable hardware average.
ADC16_DRV_ConfigHwAverage(FSL_ADCONV1,&hw_average_config);
ADC16_DRV_GetAutoCalibrationParam(FSL_ADCONV1,&calibration_param);
calibrateParams();
//ADC16_DRV_Init(FSL_ADCONV1, &adConv1_InitConfig0);
LPTMR_DRV_SetTimerPeriodUs(FSL_LPTMR1,1000000); // Set lptmr period
printf("\r\nLPTMR is running!!\r\n");
LPTMR_DRV_Start(FSL_LPTMR1);
/* Write your code here */
/* For example: for(;;) { } */
while(1)
{
if(currentCounter != lptmrCounter)
{
currentCounter = lptmrCounter;
printf("\r\nLPTMR interrupt No.%d \r\n",currentCounter);
GPIO_DRV_TogglePinOutput(LEDRGB_GREEN);
}
}
/*** Don't write any code pass this line, or it will be deleted during code generation. ***/
/*** RTOS startup code. Macro PEX_RTOS_START is defined by the RTOS component. DON'T MODIFY THIS CODE!!! ***/
#ifdef PEX_RTOS_START
PEX_RTOS_START(); /* Startup of the selected RTOS. Macro is defined by the RTOS component. */
#endif
/*** End of RTOS startup code. ***/
/*** Processor Expert end of main routine. DON'T MODIFY THIS CODE!!! ***/
for(;;){}
/*** Processor Expert end of main routine. DON'T WRITE CODE BELOW!!! ***/
} /*** End of main routine. DO NOT MODIFY THIS TEXT!!! ***/
/*!
* @brief Initialize the ADCx for HW trigger.
*
* @param instance The ADC instance number
*/
static int32_t init_adc(uint32_t instance)
{
adc16_converter_config_t adcUserConfig;
adc16_chn_config_t adcChnConfig;
#if FSL_FEATURE_ADC16_HAS_CALIBRATION
// Initialization ADC for calibration purposes
adc16_calibration_param_t adcCalibrationParam;
adc16_chn_config_t adcCalibrationChnConfig;
const adc16_hw_average_config_t adcAverageConfig = {
.hwAverageEnable = true,
.hwAverageCountMode = kAdc16HwAverageCountOf32
};
ADC16_DRV_StructInitUserConfigDefault(&adcUserConfig);
#if BOARD_ADC_USE_ALT_VREF
adcUserConfig.refVoltSrc = kAdc16RefVoltSrcOfValt;
#endif
ADC16_DRV_Init(instance, &adcUserConfig);
ADC16_DRV_ConfigHwAverage(instance, &adcAverageConfig);
adcChnConfig.chnIdx = kAdc16Chn31;
#if FSL_FEATURE_ADC16_HAS_DIFF_MODE
adcCalibrationChnConfig.diffConvEnable = false;
#endif /* FSL_FEATURE_ADC16_HAS_DIFF_MODE */
adcCalibrationChnConfig.convCompletedIntEnable = false;
// Configure channel0
ADC16_DRV_ConfigConvChn(instance, 0U, &adcCalibrationChnConfig);
// Configure channel1, which is used in PDB trigger case
ADC16_DRV_ConfigConvChn(instance, 1U, &adcCalibrationChnConfig);
// Auto calibration.
ADC16_DRV_GetAutoCalibrationParam(instance, &adcCalibrationParam);
ADC16_DRV_SetCalibrationParam(instance, &adcCalibrationParam);
#endif
// Initialization ADC for
// 12bit resolution, interrrupt mode, hw trigger enabled.
// normal convert speed, VREFH/L as reference,
// disable continuouse convert mode.
ADC16_DRV_StructInitUserConfigDefault(&adcUserConfig);
adcUserConfig.hwTriggerEnable = true;
adcUserConfig.continuousConvEnable = false;
#if BOARD_ADC_USE_ALT_VREF
adcUserConfig.refVoltSrc = kAdc16RefVoltSrcOfValt;
#endif
ADC16_DRV_Init(instance, &adcUserConfig);
// Install Callback function into ISR
ADC_TEST_InstallCallback(instance, 0U, adc_chn0_isr_callback);
ADC_TEST_InstallCallback(instance, 1U, adc_chn1_isr_callback);
adcChnConfig.chnIdx = (adc16_chn_t)ADC_INPUT_CHAN;
#if FSL_FEATURE_ADC16_HAS_DIFF_MODE
adcChnConfig.diffConvEnable = false;
#endif /* FSL_FEATURE_ADC16_HAS_DIFF_MODE */
adcChnConfig.convCompletedIntEnable = true;
// Configure channel0
ADC16_DRV_ConfigConvChn(instance, 0U, &adcChnConfig);
// Configure channel1, which is used in PDB trigger case
ADC16_DRV_ConfigConvChn(instance, 1U, &adcChnConfig);
return 0;
}
/*!
* @brief Reset the sparse matrix
*/
void sparse_reset(void)
{
memset(gChartHead, 0, sizeof(gChartHead));
memset(gChartNodes, 0, sizeof(gChartNodes));
gFreeNode = 0;
}
/*!
* @brief calibrate param for adc.
*/
void adc16CalibrateParams(void)
{
#if FSL_FEATURE_ADC16_HAS_CALIBRATION
adc16_calibration_param_t adcCalibraitionParam;
#endif
adc16_converter_config_t adcUserConfig;
#if FSL_FEATURE_ADC16_HAS_HW_AVERAGE
adc16_hw_average_config_t hwAverageConfig;
#endif
adc16_chn_config_t adcChnConfig;
pmc_bandgap_buffer_config_t pmcBandgapConfig = {
.enable = true,
#if FSL_FEATURE_PMC_HAS_BGEN
.enableInLowPower = false,
#endif
#if FSL_FEATURE_PMC_HAS_BGBDS
.drive = kPmcBandgapBufferDriveLow,
#endif
};
uint32_t bandgapValue = 0; /*! ADC value of BANDGAP */
uint32_t vdd = 0; /*! VDD in mV */
// Enable BANDGAP reference voltage
PMC_HAL_BandgapBufferConfig(PMC_BASE_PTR, &pmcBandgapConfig);
// Initialization ADC for
// 16bit resolution, interrupt mode, hw trigger disabled.
// normal convert speed, VREFH/L as reference,
// disable continuous convert mode.
ADC16_DRV_StructInitUserConfigDefault(&adcUserConfig);
adcUserConfig.resolution = kAdc16ResolutionBitOf16;
adcUserConfig.continuousConvEnable = false;
adcUserConfig.clkSrc = kAdc16ClkSrcOfAsynClk;
#if BOARD_ADC_USE_ALT_VREF
adcUserConfig.refVoltSrc = kAdc16RefVoltSrcOfValt;
#endif
ADC16_DRV_Init(HWADC_INSTANCE, &adcUserConfig);
#if FSL_FEATURE_ADC16_HAS_HW_AVERAGE
hwAverageConfig.hwAverageEnable = true;
hwAverageConfig.hwAverageCountMode = kAdc16HwAverageCountOf32;
ADC16_DRV_ConfigHwAverage(HWADC_INSTANCE, &hwAverageConfig);
#endif // FSL_FEATURE_ADC16_HAS_HW_AVERAGE
#if FSL_FEATURE_ADC16_HAS_CALIBRATION
// Auto calibration
ADC16_DRV_GetAutoCalibrationParam(HWADC_INSTANCE, &adcCalibraitionParam);
ADC16_DRV_SetCalibrationParam(HWADC_INSTANCE, &adcCalibraitionParam);
#endif
adcChnConfig.chnIdx = ADC16_BANDGAP_CHN;
#if FSL_FEATURE_ADC16_HAS_DIFF_MODE
adcChnConfig.diffConvEnable = false;
#endif
adcChnConfig.convCompletedIntEnable = false;
ADC16_DRV_ConfigConvChn(HWADC_INSTANCE, CHANNEL_0, &adcChnConfig);
// Wait for the conversion to be done
ADC16_DRV_WaitConvDone(HWADC_INSTANCE, CHANNEL_0);
// Get current ADC BANDGAP value
bandgapValue = ADC16_DRV_GetConvValueSigned(HWADC_INSTANCE, CHANNEL_0);
// ADC stop conversion
ADC16_DRV_PauseConv(HWADC_INSTANCE, CHANNEL_0);
// Get VDD value measured in mV: VDD = (ADCR_VDD x V_BG) / ADCR_BG
vdd = ADCR_VDD * V_BG / bandgapValue;
// Calibrate ADCR_TEMP25: ADCR_TEMP25 = ADCR_VDD x V_TEMP25 / VDD
sAdcrTemp25 = ADCR_VDD * V_TEMP25 / vdd;
// ADCR_100M = ADCR_VDD x M x 100 / VDD
sAdcr100m = (ADCR_VDD * M) / (vdd * 10);
#if FSL_FEATURE_ADC16_HAS_HW_AVERAGE
hwAverageConfig.hwAverageEnable = false;
ADC16_DRV_ConfigHwAverage(HWADC_INSTANCE, &hwAverageConfig);
#endif // FSL_FEATURE_ADC16_HAS_HW_AVERAGE
// Disable BANDGAP reference voltage
pmcBandgapConfig.enable = false;
PMC_HAL_BandgapBufferConfig(PMC_BASE_PTR, &pmcBandgapConfig);
}
/*!
* @brief Getting current temperature value.
* @return Current temperature.
*/
int32_t adc16GetCurrentTempValue(void)
{
int32_t currentTemperature = 0;
currentTemperature = (int32_t)(STANDARD_TEMP - ((int32_t)sAdcValue - (int32_t)sAdcrTemp25) * 100 / (int32_t)sAdcr100m);
return currentTemperature;
}
/*
** ###################################################################
**
** This file was created by Processor Expert 10.5 [05.21]
** for the Freescale Kinetis series of microcontrollers.
**
** ###################################################################
*/
void calibrateParams(void)
{
adc16_chn_config_t adcChnConfig;
#if FSL_FEATURE_ADC16_HAS_HW_AVERAGE
adc16_hw_average_config_t userHwAverageConfig;
#endif
pmc_bandgap_buffer_config_t pmcBandgapConfig = {
.enable = true,
#if FSL_FEATURE_PMC_HAS_BGEN
.enableInLowPower = false,
#endif
#if FSL_FEATURE_PMC_HAS_BGBDS
.drive = kPmcBandgapBufferDriveLow,
#endif
};
uint32_t bandgapValue = 0; // ADC value of BANDGAP
uint32_t vdd = 0; // VDD in mV
#if FSL_FEATURE_ADC16_HAS_CALIBRATION
// Auto calibration
adc16_calibration_param_t adcCalibraitionParam;
ADC16_DRV_GetAutoCalibrationParam(ADC16_INSTANCE, &adcCalibraitionParam);
ADC16_DRV_SetCalibrationParam(ADC16_INSTANCE, &adcCalibraitionParam);
#endif // FSL_FEATURE_ADC16_HAS_CALIBRATION.
// Enable BANDGAP reference voltage
PMC_HAL_BandgapBufferConfig(PMC_BASE_PTR, &pmcBandgapConfig);
#if FSL_FEATURE_ADC16_HAS_HW_AVERAGE
// Use hardware average to increase stability of the measurement.
userHwAverageConfig.hwAverageEnable = true;
userHwAverageConfig.hwAverageCountMode = kAdc16HwAverageCountOf32;
ADC16_DRV_ConfigHwAverage(ADC16_INSTANCE, &userHwAverageConfig);
#endif // FSL_FEATURE_ADC16_HAS_HW_AVERAGE
// Configure the conversion channel
// differential and interrupt mode disable.
adcChnConfig.chnIdx = (adc16_chn_t)ADC16_BANDGAP_CHN;
#if FSL_FEATURE_ADC16_HAS_DIFF_MODE
adcChnConfig.diffConvEnable = false;
#endif
adcChnConfig.convCompletedIntEnable = false;
ADC16_DRV_ConfigConvChn(ADC16_INSTANCE, ADC16_CHN_GROUP, &adcChnConfig);
// Wait for the conversion to be done
ADC16_DRV_WaitConvDone(ADC16_INSTANCE, ADC16_CHN_GROUP);
// Get current ADC BANDGAP value and format it.
bandgapValue = ADC16_DRV_GetConvValueSigned(ADC16_INSTANCE, ADC16_CHN_GROUP);
// Calculates bandgapValue in 16bit resolution
// from 12bit resolution to calibrate.
#if (FSL_FEATURE_ADC16_MAX_RESOLUTION < 16)
bandgapValue = bandgapValue << 4;
#endif
// ADC stop conversion
ADC16_DRV_PauseConv(ADC16_INSTANCE, ADC16_CHN_GROUP);
// Get VDD value measured in mV
// VDD = (ADCR_VDD x V_BG) / ADCR_BG
vdd = ADCR_VDD * V_BG / bandgapValue;
// Calibrate ADCR_TEMP25
// ADCR_TEMP25 = ADCR_VDD x V_TEMP25 / VDD
adcrTemp25 = ADCR_VDD * V_TEMP25 / vdd;
// Calculate conversion value of 100mV.
// ADCR_100M = ADCR_VDD x 100 / VDD
adcr100m = ADCR_VDD*100/ vdd;
// Disable BANDGAP reference voltage
pmcBandgapConfig.enable = false;
PMC_HAL_BandgapBufferConfig(PMC_BASE_PTR, &pmcBandgapConfig);
}
/*!
* @brief Gets current temperature of chip.
*
* This function gets convertion value, converted temperature and print them to terminal.
*/
void ADC16_Measure(void)
{
adc16_chn_config_t chnConfig;
// Configure the conversion channel
// differential and interrupt mode disable.
chnConfig.chnIdx = (adc16_chn_t)ADC16_TEMPERATURE_CHN;
#if FSL_FEATURE_ADC16_HAS_DIFF_MODE
chnConfig.diffConvEnable = false;
#endif
chnConfig.convCompletedIntEnable = false;
// Software trigger the conversion.
ADC16_DRV_ConfigConvChn(ADC16_INSTANCE, ADC16_CHN_GROUP, &chnConfig);
//ADC16_DRV_ConfigConvChn(FSL_ADCONV1, 0U, &adConv1_ChnConfig0);
// Wait for the conversion to be done.
ADC16_DRV_WaitConvDone(ADC16_INSTANCE, ADC16_CHN_GROUP);
// Fetch the conversion value.
adcValue = ADC16_DRV_GetConvValueSigned(ADC16_INSTANCE, ADC16_CHN_GROUP);
// Show the current temperature value.
PRINTF("\r\n ADC converted value: %ld\t", adcValue );
// Calculates adcValue in 16bit resolution
// from 12bit resolution in order to convert to temperature.
#if (FSL_FEATURE_ADC16_MAX_RESOLUTION < 16)
adcValue = adcValue << 4;
#endif
PRINTF("\r\n Temperature %ld\r\n", get_current_temperature(adcValue));
// Pause the conversion.
ADC16_DRV_PauseConv(ADC16_INSTANCE, ADC16_CHN_GROUP);
}
/*!
* @brief Initialize the ADCx for HW trigger.
*
* @param instance The ADC instance number
*/
int32_t init_adc(uint32_t instance)
{
#if FSL_FEATURE_ADC16_HAS_CALIBRATION
adc16_calibration_param_t adcCalibraitionParam;
#endif
adc16_converter_config_t adcUserConfig;
adc16_chn_config_t adcChnConfig;
adc16_hw_average_config_t adchwaverageConfig;
//ADC16_DRV_StructInitUserConfigDefault(&adcUserConfig);
/* Special configuration for highest accuracy. */
adcUserConfig.lowPowerEnable = false;
adcUserConfig.clkDividerMode = kAdc16ClkDividerOf1;
adcUserConfig.longSampleTimeEnable = false;
//yanglliang
adcUserConfig.resolution = kAdc16ResolutionBitOfSingleEndAs16;
//adcUserConfig.resolution = kAdc16ResolutionBitOfSingleEndAs12;
adcUserConfig.clkSrc = kAdc16ClkSrcOfBusClk; //kAdc16ClkSrcOfAsynClk;
adcUserConfig.asyncClkEnable = true;
adcUserConfig.highSpeedEnable = true;
adcUserConfig.longSampleCycleMode = kAdc16LongSampleCycleOf24;
adcUserConfig.hwTriggerEnable = false;
adcUserConfig.refVoltSrc = kAdc16RefVoltSrcOfVref;
adcUserConfig.continuousConvEnable = false;
#if ( defined(FRDM_KL43Z) /* CPU_MKL43Z256VLH4 */ \
|| defined(TWR_KL43Z48M) /* CPU_MKL43Z256VLH4 */ \
|| defined(FRDM_KL27Z) /* CPU_MKL27Z64VLH4 */ \
)
adcUserConfig.refVoltSrc = kAdc16RefVoltSrcOfValt;
#endif
ADC16_DRV_Init(instance, &adcUserConfig);
#if FSL_FEATURE_ADC16_HAS_CALIBRATION
// Auto calibraion.
ADC16_DRV_GetAutoCalibrationParam(instance, &adcCalibraitionParam);
ADC16_DRV_SetCalibrationParam(instance, &adcCalibraitionParam);
#endif
// Initialization ADC for
// 12bit resolution, interrrupt mode, hw trigger enabled.
// normal convert speed, VREFH/L as reference,
// disable continuouse convert mode.
//ADC16_DRV_StructInitUserConfigDefault(&adcUserConfig);
adcUserConfig.hwTriggerEnable = true;
adcUserConfig.continuousConvEnable = false;
#if ( defined(FRDM_KL43Z) /* CPU_MKL43Z256VLH4 */ \
|| defined(TWR_KL43Z48M) /* CPU_MKL43Z256VLH4 */ \
|| defined(FRDM_KL27Z) /* CPU_MKL27Z64VLH4 */ \
)
adcUserConfig.refVoltSrc = kAdc16RefVoltSrcOfValt;
#endif
ADC16_DRV_Init(instance, &adcUserConfig);
// Install Callback function into ISR
ADC_TEST_InstallCallback(instance, 0U, adc_chn0_isr_callback);
//ADC_TEST_InstallCallback(instance, 1U, adc_chn1_isr_callback);
adcChnConfig.chnIdx = (adc16_chn_t)ADC_AI1;
#if FSL_FEATURE_ADC16_HAS_DIFF_MODE
adcChnConfig.diffConvEnable = false;
#endif /* FSL_FEATURE_ADC16_HAS_DIFF_MODE */
adcChnConfig.convCompletedIntEnable = true;
ADC0_CFG2 |= ADC_CFG2_MUXSEL_MASK;
// Configure channel0
ADC16_DRV_ConfigConvChn(instance, 0U, &adcChnConfig);
adchwaverageConfig.hwAverageEnable=false;
//yangliang for hardware average
adchwaverageConfig.hwAverageCountMode=kAdc16HwAverageCountOf4;
//adchwaverageConfig.hwAverageCountMode=kAdc16HwAverageCountOf16;
ADC16_DRV_ConfigHwAverage(0, & adchwaverageConfig); //Set Hardware Average numbers
// Configure channel1, which is used in PDB trigger case
//ADC16_DRV_ConfigConvChn(instance, 1U, &adcChnConfig);
return 0;
}
