int AdcInit(void) { XSysMon_Config *ConfigPtr; int Status; ConfigPtr = XSysMon_LookupConfig(SYSMON_DEVICE_ID); if (ConfigPtr == NULL) { return XST_FAILURE; } XSysMon_CfgInitialize(SysMonInstPtr, ConfigPtr, ConfigPtr->BaseAddress); XSysMon_SetSequencerMode(SysMonInstPtr, XSM_SEQ_MODE_SAFE); XSysMon_SetAlarmEnables(SysMonInstPtr, 0x0); XSysMon_SetAvg(SysMonInstPtr, XSM_AVG_0_SAMPLES); Status = XSysMon_SetSeqInputMode(SysMonInstPtr, XSM_SEQ_CH_AUX00); if (Status != XST_SUCCESS) { return XST_FAILURE; } Status = XSysMon_SetSeqAcqTime(SysMonInstPtr, XSM_SEQ_CH_AUX00 | XSM_SEQ_CH_AUX06 | XSM_SEQ_CH_AUX07 | XSM_SEQ_CH_AUX14 | XSM_SEQ_CH_AUX15); if (Status != XST_SUCCESS) { return XST_FAILURE; } Status = XSysMon_SetSeqChEnables(SysMonInstPtr, XSM_SEQ_CH_AUX00 | XSM_SEQ_CH_AUX06 | XSM_SEQ_CH_AUX07 | XSM_SEQ_CH_AUX14 | XSM_SEQ_CH_AUX15); if (Status != XST_SUCCESS) { return XST_FAILURE; } XSysMon_SetAdcClkDivisor(SysMonInstPtr, 32); XSysMon_SetCalibEnables(SysMonInstPtr, XSM_CFR1_CAL_PS_GAIN_OFFSET_MASK | XSM_CFR1_CAL_ADC_GAIN_OFFSET_MASK); XSysMon_SetSequencerMode(SysMonInstPtr, XSM_SEQ_MODE_CONTINPASS); XSysMon_GetStatus(SysMonInstPtr); while ((XSysMon_GetStatus(SysMonInstPtr) & XSM_SR_EOS_MASK) != XSM_SR_EOS_MASK); return 0; }
/** * * This function runs a test on the System Monitor/ADC device using the * driver APIs. * * The function does the following tasks: * - Initiate the System Monitor/ADC device driver instance * - Run self-test on the device * - Reset the device * - Set up alarm for VCCINT * - Set up the configuration registers for single channel continuous mode * for VCCINT channel * - Setup interrupt system * - Enable interrupts * - Wait until the VCCINT alarm interrupt occurs * * @param IntcInstancePtr is a pointer to the Interrupt Controller * driver Instance. * @param SysMonInstPtr is a pointer to the XSysMon driver Instance. * @param SysMonDeviceId is the XPAR_<SYSMON_ADC_instance>_DEVICE_ID value * from xparameters.h. * @param SysMonIntrId is * XPAR_<INTC_instance>_<SYSMON_ADC_instance>_VEC_ID * value from xparameters.h * * @return * - XST_SUCCESS if the example has completed successfully. * - XST_FAILURE if the example has failed. * * @note This function may never return if no interrupt occurs. * ****************************************************************************/ int SysMonSingleChannelIntrExample(XIntc* IntcInstancePtr, XSysMon* SysMonInstPtr, u16 SysMonDeviceId, u16 SysMonIntrId) { int Status; XSysMon_Config *ConfigPtr; u16 VccintData; u32 IntrStatus; /* * Initialize the SysMon driver. */ ConfigPtr = XSysMon_LookupConfig(SysMonDeviceId); if (ConfigPtr == NULL) { return XST_FAILURE; } XSysMon_CfgInitialize(SysMonInstPtr, ConfigPtr, ConfigPtr->BaseAddress); /* * Self Test the System Monitor/ADC device. */ Status = XSysMon_SelfTest(SysMonInstPtr); if (Status != XST_SUCCESS) { return XST_FAILURE; } /* * Set the ADCCLK frequency equal to 1/32 of System clock for the System * Monitor/ADC in the Configuration Register 2. */ XSysMon_SetAdcClkDivisor(SysMonInstPtr, 32); /* * Set the sequencer in Single channel mode. */ XSysMon_SetSequencerMode(SysMonInstPtr, XSM_SEQ_MODE_SINGCHAN); /* * Set the configuration registers for single channel continuous mode * of operation for the VCCINT channel. */ Status= XSysMon_SetSingleChParams(SysMonInstPtr, XSM_CH_VCCINT, FALSE, FALSE, FALSE); if(Status != XST_SUCCESS) { return XST_FAILURE; } /* * Disable all the alarms in the Configuration Register 1. */ XSysMon_SetAlarmEnables(SysMonInstPtr, 0x0); /* * Set up Alarm threshold registers for the VCCINT * High limit and lower limit so that the alarm does not occur. */ XSysMon_SetAlarmThreshold(SysMonInstPtr, XSM_ATR_VCCINT_UPPER, 0xFFFF); XSysMon_SetAlarmThreshold(SysMonInstPtr, XSM_ATR_VCCINT_LOWER, 0x0); /* * Setup the interrupt system. */ Status = SysMonSetupInterruptSystem(IntcInstancePtr, SysMonInstPtr, SysMonIntrId); if (Status != XST_SUCCESS) { return XST_FAILURE; } /* * Clear any bits set in the Interrupt Status Register. */ IntrStatus = XSysMon_IntrGetStatus(SysMonInstPtr); XSysMon_IntrClear(SysMonInstPtr, IntrStatus); /* * Enable EOC interrupt and Alarm 1 interrupt for on-chip VCCINT. */ XSysMon_IntrEnable(SysMonInstPtr, XSM_IPIXR_EOC_MASK | XSM_IPIXR_VCCINT_MASK); /* * Enable global interrupt of System Monitor. */ XSysMon_IntrGlobalEnable(SysMonInstPtr); /* * Wait till the End of Conversion occurs. */ EocFlag = FALSE; /* Clear the EOC Flag */ while (EocFlag != TRUE); /* * Read the ADC converted Data from the data registers for VCCINT. */ VccintData = XSysMon_GetAdcData(SysMonInstPtr, XSM_CH_VCCINT); /* * Set up Alarm threshold registers for the VCCINT * High limit and lower limit so that the alarm occurs. */ XSysMon_SetAlarmThreshold(SysMonInstPtr, XSM_ATR_VCCINT_UPPER, VccintData - 0x007F); XSysMon_SetAlarmThreshold(SysMonInstPtr, XSM_ATR_VCCINT_LOWER, VccintData - 0x007F); VccintIntr = FALSE; /* Clear the flag */ /* * Enable Alarm 1 for VCCINT */ XSysMon_SetAlarmEnables(SysMonInstPtr, XSM_CFR1_ALM_VCCINT_MASK); /* * Wait until an Alarm 1 interrupt occurs. */ while (1) { if (VccintIntr == TRUE) { /* * Alarm 1 - VCCINT alarm interrupt has occurred. * The required processing should be put here. */ break; } } /* * Disable global interrupt of System Monitor. */ XSysMon_IntrGlobalDisable(SysMonInstPtr); return XST_SUCCESS; }
/** * * This function runs a test on the System Monitor/ADC device using the * driver APIs. * This function does the following tasks: * - Initiate the System Monitor device driver instance * - Run self-test on the device * - Setup alarms for on-chip temperature and VCCAUX * - Setup the sequence registers to continuously monitor on-chip * temperature and VCCAUX * - Setup configuration registers to start the sequence * - Read latest on-chip temperature and VCCAUX, as well as their maximum * and minimum values. Also check if alarm(s) are set * * @param SysMonDeviceId is the XPAR_<SYSMON_ADC_instance>_DEVICE_ID value * from xparameters.h. * @param Temp is an output parameter, it is a pointer through which the * current temperature value is returned to the main function. * * @return * - XST_SUCCESS if the example has completed successfully. * - XST_FAILURE if the example has failed. * * @note None * ****************************************************************************/ int SysMonPolledExample(u16 SysMonDeviceId, int *Temp) { int Status; volatile u32 Value; XSysMon_Config *ConfigPtr; u16 TempData; u16 VccauxData; XSysMon *SysMonInstPtr = &SysMonInst; /* * Initialize the SysMon driver. */ ConfigPtr = XSysMon_LookupConfig(SysMonDeviceId); if (ConfigPtr == NULL) { return XST_FAILURE; } XSysMon_CfgInitialize(SysMonInstPtr, ConfigPtr, ConfigPtr->BaseAddress); /* * Self Test the System Monitor/ADC device */ Status = XSysMon_SelfTest(SysMonInstPtr); if (Status != XST_SUCCESS) { return XST_FAILURE; } /* * Disable the Channel Sequencer before configuring the Sequence * registers. */ XSysMon_SetSequencerMode(SysMonInstPtr, XSM_SEQ_MODE_SAFE); /* * Setup the Averaging to be done for the channels in the * Configuration 0 register as 16 samples: */ XSysMon_SetAvg(SysMonInstPtr, XSM_AVG_16_SAMPLES); /* * Setup the Sequence register for 1st Auxiliary channel * Setting is: * - Add acquisition time by 6 ADCCLK cycles. * - Bipolar Mode * * Setup the Sequence register for 16th Auxiliary channel * Setting is: * - Add acquisition time by 6 ADCCLK cycles. * - Unipolar Mode */ Status = XSysMon_SetSeqInputMode(SysMonInstPtr, XSM_SEQ_CH_AUX00); if (Status != XST_SUCCESS) { return XST_FAILURE; } Status = XSysMon_SetSeqAcqTime(SysMonInstPtr, XSM_SEQ_CH_AUX15 | XSM_SEQ_CH_AUX00); if (Status != XST_SUCCESS) { return XST_FAILURE; } /* * Enable the averaging on the following channels in the Sequencer * registers: * - On-chip Temperature * - On-chip VCCAUX supply sensor * - 1st Auxiliary Channel * - 16th Auxiliary Channel */ Status = XSysMon_SetSeqAvgEnables(SysMonInstPtr, XSM_SEQ_CH_TEMP | XSM_SEQ_CH_VCCAUX | XSM_SEQ_CH_AUX00 | XSM_SEQ_CH_AUX15); if (Status != XST_SUCCESS) { return XST_FAILURE; } /* * Enable the following channels in the Sequencer registers: * - On-chip Temperature * - On-chip VCCAUX supply sensor * - 1st Auxiliary Channel * - 16th Auxiliary Channel */ Status = XSysMon_SetSeqChEnables(SysMonInstPtr, XSM_SEQ_CH_TEMP | XSM_SEQ_CH_VCCAUX | XSM_SEQ_CH_AUX00 | XSM_SEQ_CH_AUX15); if (Status != XST_SUCCESS) { return XST_FAILURE; } /* * Set the ADCCLK frequency equal to 1/32 of System clock for the System * Monitor/ADC in the Configuration Register 2. */ XSysMon_SetAdcClkDivisor(SysMonInstPtr, 32); /* * Enable the Channel Sequencer in continuous sequencer cycling mode. */ XSysMon_SetSequencerMode(SysMonInstPtr, XSM_SEQ_MODE_CONTINPASS); /* * Wait till the End of Sequence occurs */ XSysMon_GetStatus(SysMonInstPtr); /* Clear the old status */ while ((XSysMon_GetStatus(SysMonInstPtr) & XSM_SR_EOS_MASK) != XSM_SR_EOS_MASK); /* * Disable all the alarms in the Configuration Register 1 */ XSysMon_SetAlarmEnables(SysMonInstPtr, 0x0); /* * Read the ADC converted Data from the data registers for on-chip * temperature and on-chip VCCAUX */ TempData = XSysMon_GetAdcData(SysMonInstPtr, XSM_CH_TEMP); VccauxData = XSysMon_GetAdcData(SysMonInstPtr, XSM_CH_VCCAUX); /* * Convert the ADC data into temperature */ *Temp = XSysMon_RawToTemperature(TempData); /* * Set up Alarm threshold registers for * On-chip Temperature High limit * On-chip Temperature Low limit * VCCAUX High limit * VCCAUX Low limit */ XSysMon_SetAlarmThreshold(SysMonInstPtr, XSM_ATR_TEMP_UPPER, TempData - 0x007F); XSysMon_SetAlarmThreshold(SysMonInstPtr, XSM_ATR_TEMP_LOWER, TempData - 0x007F); XSysMon_SetAlarmThreshold(SysMonInstPtr, XSM_ATR_VCCAUX_UPPER, VccauxData - 0x007F); XSysMon_SetAlarmThreshold(SysMonInstPtr, XSM_ATR_VCCAUX_LOWER, VccauxData + 0x007F); /* * Enable Alarm 0 for on-chip temperature and Alarm 2 for on-chip * VCCAUX in the Configuration Register 1. */ XSysMon_SetAlarmEnables(SysMonInstPtr, (XSM_CFR1_ALM_VCCAUX_MASK | XSM_CFR1_ALM_TEMP_MASK)); /* * Enable the Channel Sequencer in continuous cycling mode. */ XSysMon_SetSequencerMode(SysMonInstPtr, XSM_SEQ_MODE_CONTINPASS); /* * Read the current value of on-chip Temperature. */ Value = XSysMon_GetAdcData(SysMonInstPtr, XSM_CH_TEMP); /* * Read the Maximum value of on-chip Temperature. */ Value = XSysMon_GetMinMaxMeasurement(SysMonInstPtr, XSM_MAX_TEMP); /* * Read the Minimum value of on-chip Temperature. */ Value = XSysMon_GetMinMaxMeasurement(SysMonInstPtr, XSM_MIN_TEMP); /* * Check if alarm for on-chip temperature is set. */ Value = XSysMon_GetAlarmOutputStatus(SysMonInstPtr) & XSM_AOR_TEMP_MASK; if (Value) { /* * Alarm for on-chip temperature is set. * The required processing should be put here. */ } /* * Read the current value of on-chip VCCAUX. */ Value = XSysMon_GetAdcData(SysMonInstPtr, XSM_CH_VCCAUX); /* * Read the Maximum value of on-chip VCCAUX. */ Value = XSysMon_GetMinMaxMeasurement(SysMonInstPtr, XSM_MAX_VCCAUX); /* * Read the Minimum value of on-chip VCCAUX. */ Value = XSysMon_GetMinMaxMeasurement(SysMonInstPtr, XSM_MIN_VCCAUX); /* * Check if alarm for on-chip VCCAUX is set. */ Value = XSysMon_GetAlarmOutputStatus(SysMonInstPtr) & XSM_AOR_VCCAUX_MASK; if (Value) { /* * Alarm for on-chip VCCAUX is set. * The required processing should be put here. */ } return XST_SUCCESS; }
/** * * This function runs a test on the System Monitor/ADC device using the * driver APIs. * * The function does the following tasks: * - Initiate the System Monitor/ADC device driver instance * - Run self-test on the device * - Reset the device * - Set up alarms for on-chip temperature and VCCAUX * - Set up sequence registers to continuously monitor on-chip temperature * and VCCAUX * - Setup interrupt system * - Enable interrupts * - Set up configuration registers to start the sequence * - Wait until temperature alarm interrupt or VCCAUX alarm interrupt * occurs * * @param IntcInstancePtr is a pointer to the Interrupt Controller * driver Instance. * @param SysMonInstPtr is a pointer to the XSysMon driver Instance. * @param SysMonDeviceId is the XPAR_<SYSMON_ADC_instance>_DEVICE_ID value * from xparameters.h. * @param SysMonIntrId is * XPAR_<INTC_instance>_<SYSMON_ADC_instance>_VEC_ID value from * xparameters.h * @param Temp is an output parameter, it is a pointer through which the * current temperature value is returned to the main function. * * @return * - XST_SUCCESS if the example has completed successfully. * - XST_FAILURE if the example has failed. * * @note This function may never return if no interrupt occurs. * ****************************************************************************/ int SysMonIntrExample(XIntc* IntcInstancePtr, XSysMon* SysMonInstPtr, u16 SysMonDeviceId, u16 SysMonIntrId, int *Temp) { int Status; XSysMon_Config *ConfigPtr; u16 TempData; u16 VccauxData; u32 IntrStatus; /* * Initialize the SysMon driver. */ ConfigPtr = XSysMon_LookupConfig(SysMonDeviceId); if (ConfigPtr == NULL) { return XST_FAILURE; } XSysMon_CfgInitialize(SysMonInstPtr, ConfigPtr, ConfigPtr->BaseAddress); /* * Self Test the System Monitor/ADC device. */ Status = XSysMon_SelfTest(SysMonInstPtr); if (Status != XST_SUCCESS) { return XST_FAILURE; } /* * Disable the Channel Sequencer before configuring the Sequence * registers. */ XSysMon_SetSequencerMode(SysMonInstPtr, XSM_SEQ_MODE_SAFE); /* * Setup the Averaging to be done for the channels in the * Configuration 0 register as 16 samples: */ XSysMon_SetAvg(SysMonInstPtr, XSM_AVG_16_SAMPLES); /* * Setup the Sequence register for 1st Auxiliary channel * Setting is: * - Add acquisition time by 6 ADCCLK cycles. * - Bipolar Mode * * Setup the Sequence register for 16th Auxiliary channel * Setting is: * - Add acquisition time by 6 ADCCLK cycles. * - Unipolar Mode */ Status = XSysMon_SetSeqInputMode(SysMonInstPtr, XSM_SEQ_CH_AUX00); if (Status != XST_SUCCESS) { return XST_FAILURE; } Status = XSysMon_SetSeqAcqTime(SysMonInstPtr, XSM_SEQ_CH_AUX15 | XSM_SEQ_CH_AUX00); if (Status != XST_SUCCESS) { return XST_FAILURE; } /* * Enable the averaging on the following channels in the Sequencer * registers: * - On-chip Temperature * - On-chip VCCAUX supply sensor * - 1st Auxiliary Channel * - 16th Auxiliary Channel */ Status = XSysMon_SetSeqAvgEnables(SysMonInstPtr, XSM_SEQ_CH_TEMP | XSM_SEQ_CH_VCCAUX | XSM_SEQ_CH_AUX00 | XSM_SEQ_CH_AUX15); if (Status != XST_SUCCESS) { return XST_FAILURE; } /* * Enable the following channels in the Sequencer registers: * - On-chip Temperature * - On-chip VCCAUX supply sensor * - 1st Auxiliary Channel * - 16th Auxiliary Channel */ Status = XSysMon_SetSeqChEnables(SysMonInstPtr, XSM_SEQ_CH_TEMP | XSM_SEQ_CH_VCCAUX | XSM_SEQ_CH_AUX00 | XSM_SEQ_CH_AUX15); if (Status != XST_SUCCESS) { return XST_FAILURE; } /* * Set the ADCCLK frequency equal to 1/32 of System clock for the System * Monitor/ADC in the Configuration Register 2. */ XSysMon_SetAdcClkDivisor(SysMonInstPtr, 32); /* * Enable the Channel Sequencer in continuous sequencer cycling mode. */ XSysMon_SetSequencerMode(SysMonInstPtr, XSM_SEQ_MODE_CONTINPASS); /* * Wait till the End of Sequence occurs */ XSysMon_GetStatus(SysMonInstPtr); /* Clear the old status */ while ((XSysMon_GetStatus(SysMonInstPtr) & XSM_SR_EOS_MASK) != XSM_SR_EOS_MASK); /* * Read the ADC converted Data from the data registers for on-chip * temperature and on-chip VCCAUX voltage. */ TempData = XSysMon_GetAdcData(SysMonInstPtr, XSM_CH_TEMP); VccauxData = XSysMon_GetAdcData(SysMonInstPtr, XSM_CH_VCCAUX); /* * Convert the ADC data into temperature */ *Temp = XSysMon_RawToTemperature(TempData); /* * Disable all the alarms in the Configuration Register 1. */ XSysMon_SetAlarmEnables(SysMonInstPtr, 0x0); /* * Set up Alarm threshold registers for the on-chip temperature and * VCCAUX High limit and lower limit so that the alarms DONOT occur. */ XSysMon_SetAlarmThreshold(SysMonInstPtr, XSM_ATR_TEMP_UPPER, 0xFFFF); XSysMon_SetAlarmThreshold(SysMonInstPtr, XSM_ATR_TEMP_LOWER, 0xFFFF); XSysMon_SetAlarmThreshold(SysMonInstPtr, XSM_ATR_VCCAUX_UPPER, 0xFFFF); XSysMon_SetAlarmThreshold(SysMonInstPtr, XSM_ATR_VCCAUX_LOWER, 0x0); /* * Setup the interrupt system. */ Status = SysMonSetupInterruptSystem(IntcInstancePtr, SysMonInstPtr, SysMonIntrId); if (Status != XST_SUCCESS) { return XST_FAILURE; } /* * Clear any bits set in the Interrupt Status Register. */ IntrStatus = XSysMon_IntrGetStatus(SysMonInstPtr); XSysMon_IntrClear(SysMonInstPtr, IntrStatus); /* * Enable Alarm 0 interrupt for on-chip temperature and Alarm 2 * interrupt for on-chip VCCAUX. */ XSysMon_IntrEnable(SysMonInstPtr, XSM_IPIXR_TEMP_MASK | XSM_IPIXR_VCCAUX_MASK); /* * Enable global interrupt of System Monitor. */ XSysMon_IntrGlobalEnable(SysMonInstPtr); /* * Set up Alarm threshold registers for * On-chip Temperature High limit * On-chip Temperature Low limit * VCCAUX High limit * VCCAUX Low limit */ XSysMon_SetAlarmThreshold(SysMonInstPtr, XSM_ATR_TEMP_UPPER, TempData - 0x007F); XSysMon_SetAlarmThreshold(SysMonInstPtr, XSM_ATR_TEMP_LOWER, TempData - 0x007F); XSysMon_SetAlarmThreshold(SysMonInstPtr, XSM_ATR_VCCAUX_UPPER, VccauxData - 0x007F); XSysMon_SetAlarmThreshold(SysMonInstPtr, XSM_ATR_VCCAUX_LOWER, VccauxData + 0x007F); /* * Enable Alarm 0 for on-chip temperature and Alarm 2 for on-chip * VCCAUX in the Configuration Register 1. */ XSysMon_SetAlarmEnables(SysMonInstPtr, (XSM_CFR1_ALM_VCCAUX_MASK | XSM_CFR1_ALM_TEMP_MASK)); /* * Wait until an Alarm 0 or Alarm 2 interrupt occurs. */ while (1) { if (TemperatureIntr == TRUE) { /* * Alarm 0 - Temperature alarm interrupt has occurred. * The required processing should be put here. */ break; } if (VccauxIntr == TRUE) { /* * Alarm 2 - VCCAUX alarm interrupt has occurred. * The required processing should be put here. */ break; } } /* * Disable global interrupt of System Monitor. */ XSysMon_IntrGlobalDisable(SysMonInstPtr); return XST_SUCCESS; }
int SysMonIntrExample(XIntc* IntcInstancePtr, XSysMon* SysMonInstPtr, u16 SysMonDeviceId, u16 SysMonIntrId, int *Temp) { int Status; XSysMon_Config *ConfigPtr; u32 TempData; u32 VccauxData; u32 VccintData; u32 IntrStatus; int i, j; unsigned int whole1, thousandths1; unsigned int whole2, thousandths2; unsigned int whole3, thousandths3; /* * Initialize the SysMon driver. */ //xil_printf("XSysMon intr example\r\n"); ConfigPtr = XSysMon_LookupConfig(SysMonDeviceId); if (ConfigPtr == NULL) { return XST_FAILURE; } //xil_printf("XSysMon_CfgInitialize\r\n"); XSysMon_CfgInitialize(SysMonInstPtr, ConfigPtr, ConfigPtr->BaseAddress); /* * Self Test the System Monitor/ADC device. */ //xil_printf("XSysMon_SelfTest\r\n"); Status = XSysMon_SelfTest(SysMonInstPtr); if (Status != XST_SUCCESS) { xil_printf("XSysMon_SelfTest failed\r\n"); return XST_FAILURE; } /* * Disable the Channel Sequencer before configuring the Sequence * registers. */ XSysMon_SetSequencerMode(SysMonInstPtr, XSM_SEQ_MODE_SINGCHAN); /* * Setup the Averaging to be done for the channels in the * Configuration 0 register as 16 samples: */ XSysMon_SetAvg(SysMonInstPtr, XSM_AVG_16_SAMPLES); #if 0 /* * Setup the Sequence register for 1st Auxiliary channel * Setting is: * - Add acquisition time by 6 ADCCLK cycles. * - Bipolar Mode * * Setup the Sequence register for 16th Auxiliary channel * Setting is: * - Add acquisition time by 6 ADCCLK cycles. * - Unipolar Mode */ Status = XSysMon_SetSeqInputMode(SysMonInstPtr, XSM_SEQ_CH_AUX00); if (Status != XST_SUCCESS) { return XST_FAILURE; } Status = XSysMon_SetSeqAcqTime(SysMonInstPtr, XSM_SEQ_CH_AUX15 | XSM_SEQ_CH_AUX00); if (Status != XST_SUCCESS) { return XST_FAILURE; } #endif /* * Enable the averaging on the following channels in the Sequencer * registers: * - On-chip Temperature * - On-chip VCCAUX supply sensor * - 1st Auxiliary Channel * - 16th Auxiliary Channel */ Status = XSysMon_SetSeqAvgEnables(SysMonInstPtr, XSM_SEQ_CH_TEMP | /* XSM_SEQ_CH_AUX00 | */ /* XSM_SEQ_CH_AUX15 | */ XSM_SEQ_CH_VCCINT | XSM_SEQ_CH_VCCAUX ); if (Status != XST_SUCCESS) { return XST_FAILURE; } /* * Enable the following channels in the Sequencer registers: * - On-chip Temperature * - On-chip VCCAUX supply sensor * - 1st Auxiliary Channel * - 16th Auxiliary Channel */ Status = XSysMon_SetSeqChEnables(SysMonInstPtr, XSM_SEQ_CH_TEMP | /* XSM_SEQ_CH_AUX00 | */ /* XSM_SEQ_CH_AUX15 | */ XSM_SEQ_CH_VCCINT | XSM_SEQ_CH_VCCAUX ); if (Status != XST_SUCCESS) { return XST_FAILURE; } /* * Set the ADCCLK frequency equal to 1/32 of System clock for the System * Monitor/ADC in the Configuration Register 2. */ XSysMon_SetAdcClkDivisor(SysMonInstPtr, 32); /* * Enable the Channel Sequencer in continuous sequencer cycling mode. */ XSysMon_SetSequencerMode(SysMonInstPtr, XSM_SEQ_MODE_CONTINPASS); /* * Disable all the alarms in the Configuration Register 1. */ XSysMon_SetAlarmEnables(SysMonInstPtr, 0x0); /* * Wait till the End of Sequence occurs */ XSysMon_GetStatus(SysMonInstPtr); /* Clear the old status */ i = 0; while(i < 10) { if((XSysMon_GetStatus(SysMonInstPtr) & XSM_SR_EOS_MASK) != XSM_SR_EOS_MASK) continue; /* * Read the ADC converted Data from the data registers for on-chip * temperature and on-chip VCCAUX voltage. */ TempData = XSysMon_GetAdcData(SysMonInstPtr, XSM_CH_TEMP); VccauxData = XSysMon_GetAdcData(SysMonInstPtr, XSM_CH_VCCAUX); VccintData = XSysMon_GetAdcData(SysMonInstPtr, XSM_CH_VCCINT); /* * Convert the ADC data into temperature */ *Temp = XSysMon_RawToTemperature(TempData); t = (float) XSysMon_RawToTemperature(TempData); vint = (float) XSysMon_RawToVoltage(VccintData); vaux = (float) XSysMon_RawToVoltage(VccauxData); whole1 = t; thousandths1 = (t - whole1) * 1000; whole2 = vint; thousandths2 = (vint - whole2) * 1000; whole3 = vaux; thousandths3 = (vaux - whole3) * 1000; //xil_printf("Temperature: 0x%x, Vccint: 0x%x Vccaux: 0x%x [Exit: press any key]\r\n", // TempData, VccintData, VccauxData); printf("Temperature: %d.%3dC, Vccint: %d.%3dV Vccaux: %d.%3dV\r\n", whole1, thousandths1, whole2, thousandths2, whole3, thousandths3); for(j=0; j<10000;j++); // some delay //if(!XUartNs550_IsReceiveData(STDIN_BASEADDRESS)) //{ // continue; //} //else //{ // XUartNs550_ReadReg(STDIN_BASEADDRESS, XUN_RBR_OFFSET); // return 0; //} i++; } #if 0 /* * Set up Alarm threshold registers for the on-chip temperature and * VCCAUX High limit and lower limit so that the alarms DONOT occur. */ XSysMon_SetAlarmThreshold(SysMonInstPtr, XSM_ATR_TEMP_UPPER, 0xFFFF); XSysMon_SetAlarmThreshold(SysMonInstPtr, XSM_ATR_TEMP_LOWER, 0xFFFF); XSysMon_SetAlarmThreshold(SysMonInstPtr, XSM_ATR_VCCAUX_UPPER, 0xFFFF); XSysMon_SetAlarmThreshold(SysMonInstPtr, XSM_ATR_VCCAUX_LOWER, 0x0); XSysMon_SetAlarmThreshold(SysMonInstPtr, XSM_ATR_VCCINT_UPPER, 0xFFFF); XSysMon_SetAlarmThreshold(SysMonInstPtr, XSM_ATR_VCCINT_LOWER, 0x0); /* * Setup the interrupt system. */ Status = SysMonSetupInterruptSystem(IntcInstancePtr, SysMonInstPtr, SysMonIntrId); if (Status != XST_SUCCESS) { return XST_FAILURE; } #endif /* * Clear any bits set in the Interrupt Status Register. */ IntrStatus = XSysMon_IntrGetStatus(SysMonInstPtr); XSysMon_IntrClear(SysMonInstPtr, IntrStatus); #if 0 /* * Enable Alarm 0 interrupt for on-chip temperature and Alarm 2 * interrupt for on-chip VCCAUX. */ XSysMon_IntrEnable(SysMonInstPtr, XSM_IPIXR_TEMP_MASK | XSM_IPIXR_VCCAUX_MASK); /* * Enable global interrupt of System Monitor. */ XSysMon_IntrGlobalEnable(SysMonInstPtr); /* * Set up Alarm threshold registers for * On-chip Temperature High limit * On-chip Temperature Low limit * VCCAUX High limit * VCCAUX Low limit */ XSysMon_SetAlarmThreshold(SysMonInstPtr, XSM_ATR_TEMP_UPPER, TempData - 0x007F); XSysMon_SetAlarmThreshold(SysMonInstPtr, XSM_ATR_TEMP_LOWER, TempData - 0x007F); XSysMon_SetAlarmThreshold(SysMonInstPtr, XSM_ATR_VCCAUX_UPPER, VccauxData - 0x007F); XSysMon_SetAlarmThreshold(SysMonInstPtr, XSM_ATR_VCCAUX_LOWER, VccauxData + 0x007F); /* * Enable Alarm 0 for on-chip temperature and Alarm 2 for on-chip * VCCAUX in the Configuration Register 1. */ XSysMon_SetAlarmEnables(SysMonInstPtr, (XSM_CFR1_ALM_VCCAUX_MASK | XSM_CFR1_ALM_TEMP_MASK)); /* * Wait until an Alarm 0 or Alarm 2 interrupt occurs. */ while (1) { if (TemperatureIntr == TRUE) { /* * Alarm 0 - Temperature alarm interrupt has occurred. * The required processing should be put here. */ break; } if (VccauxIntr == TRUE) { /* * Alarm 2 - VCCAUX alarm interrupt has occurred. * The required processing should be put here. */ break; } } #endif /* * Disable global interrupt of System Monitor. */ XSysMon_IntrGlobalDisable(SysMonInstPtr); return XST_SUCCESS; }
/** * * This function runs a test on the System Monitor/ADC device using the * driver APIs. * * The function does the following tasks: * - Initiate the System Monitor/ADC device driver instance * - Run self-test on the device * - Reset the device * - Set up alarms for on-chip temperature and VCCAUX * - Set up sequence registers to continuously monitor on-chip temperature * and VCCAUX * - Setup interrupt system * - Enable interrupts * - Set up configuration registers to start the sequence * - Wait until temperature alarm interrupt or VCCAUX alarm interrupt * occurs * * @param IntcInstancePtr is a pointer to the Interrupt Controller * driver Instance. * @param SysMonInstPtr is a pointer to the XSysMon driver Instance. * @param SysMonDeviceId is the XPAR_<SYSMON_ADC_instance>_DEVICE_ID value * from xparameters.h. * @param SysMonIntrId is * XPAR_<INTC_instance>_<SYSMON_ADC_instance>_VEC_ID value from * xparameters.h * @param Temp is an output parameter, it is a pointer through which the * current temperature value is returned to the main function. * * @return * - XST_SUCCESS if the example has completed successfully. * - XST_FAILURE if the example has failed. * * @note This function may never return if no interrupt occurs. * ****************************************************************************/ int SysMonIntrExample2(XSysMon* SysMonInstPtr, u16 SysMonDeviceId, u16 SysMonIntrId, char *adcData, int printable) { int Status; u32 TempData; u32 VccauxData; u32 VccintData; u32 IntrStatus; int j; unsigned int whole1, thousandths1; unsigned int whole2, thousandths2; unsigned int whole3, thousandths3; /* * Initialize the SysMon driver. */ if(sysmon_init==0) { //xil_printf("XSysMon intr example\r\n"); SysMonConfigPtr = XSysMon_LookupConfig(SysMonDeviceId); if (SysMonConfigPtr == NULL) { return XST_FAILURE; } //xil_printf("XSysMon_CfgInitialize\r\n"); XSysMon_CfgInitialize(SysMonInstPtr, SysMonConfigPtr, SysMonConfigPtr->BaseAddress); /* * Self Test the System Monitor/ADC device. */ //xil_printf("XSysMon_SelfTest\r\n"); Status = XSysMon_SelfTest(SysMonInstPtr); if (Status != XST_SUCCESS) { xil_printf("XSysMon_SelfTest failed\r\n"); return XST_FAILURE; } sysmon_init = 1; } /* * Disable the Channel Sequencer before configuring the Sequence * registers. */ XSysMon_SetSequencerMode(SysMonInstPtr, XSM_SEQ_MODE_SAFE); /* * Setup the Averaging to be done for the channels in the * Configuration 0 register as 16 samples: */ XSysMon_SetAvg(SysMonInstPtr, XSM_AVG_16_SAMPLES); /* * Enable the averaging on the following channels in the Sequencer * registers: * - On-chip Temperature * - On-chip VCCAUX supply sensor * - 1st Auxiliary Channel * - 16th Auxiliary Channel */ Status = XSysMon_SetSeqAvgEnables(SysMonInstPtr, XSM_SEQ_CH_TEMP | /* XSM_SEQ_CH_AUX00 | */ /* XSM_SEQ_CH_AUX15 | */ XSM_SEQ_CH_VCCINT | XSM_SEQ_CH_VCCAUX ); if (Status != XST_SUCCESS) { return XST_FAILURE; } /* * Enable the following channels in the Sequencer registers: * - On-chip Temperature * - On-chip VCCAUX supply sensor * - 1st Auxiliary Channel * - 16th Auxiliary Channel */ Status = XSysMon_SetSeqChEnables(SysMonInstPtr, XSM_SEQ_CH_TEMP | /* XSM_SEQ_CH_AUX00 | */ /* XSM_SEQ_CH_AUX15 | */ XSM_SEQ_CH_VCCINT | XSM_SEQ_CH_VCCAUX ); if (Status != XST_SUCCESS) { return XST_FAILURE; } /* * Set the ADCCLK frequency equal to 1/32 of System clock for the System * Monitor/ADC in the Configuration Register 2. */ XSysMon_SetAdcClkDivisor(SysMonInstPtr, 32); /* * Enable the Channel Sequencer in continuous sequencer cycling mode. */ XSysMon_SetSequencerMode(SysMonInstPtr, XSM_SEQ_MODE_CONTINPASS); /* * Disable all the alarms in the Configuration Register 1. */ XSysMon_SetAlarmEnables(SysMonInstPtr, 0x0); /* * Wait till the End of Sequence occurs */ XSysMon_GetStatus(SysMonInstPtr); /* Clear the old status */ do { if((XSysMon_GetStatus(SysMonInstPtr) & XSM_SR_EOS_MASK) == XSM_SR_EOS_MASK) break; } while(1); /* * Read the ADC converted Data from the data registers for on-chip * temperature and on-chip VCCAUX voltage. */ TempData = XSysMon_GetAdcData(SysMonInstPtr, XSM_CH_TEMP); VccauxData = XSysMon_GetAdcData(SysMonInstPtr, XSM_CH_VCCAUX); VccintData = XSysMon_GetAdcData(SysMonInstPtr, XSM_CH_VCCINT); /* * Convert the ADC data into temperature */ //*Temp = XSysMon_RawToTemperature(TempData); t = (float) XSysMon_RawToTemperature(TempData); vint = (float) XSysMon_RawToVoltage(VccintData); vaux = (float) XSysMon_RawToVoltage(VccauxData); whole1 = t; thousandths1 = (t - whole1) * 1000; whole2 = vint; thousandths2 = (vint - whole2) * 1000; whole3 = vaux; thousandths3 = (vaux - whole3) * 1000; //xil_printf("Temperature: 0x%x, Vccint: 0x%x Vccaux: 0x%x [Exit: press any key]\r\n", // TempData, VccintData, VccauxData); if(printable==1) { // send complete string with units sprintf(adcData, "Temperature:%d.%-3dC, Vccint:%d.%-3dV, Vccaux: %d.%-3dV", whole1, thousandths1, whole2, thousandths2, whole3, thousandths3); } else { // send ONLY the numbers (used for graph plot by the webserver sprintf(adcData, "%d.%-d, %d.%-d, %d.%-d", whole1, thousandths1, whole2, thousandths2, whole3, thousandths3); } //printf("Temperature: %d.%3dC, Vccint: %d.%3dV Vccaux: %d.%3dV\r\n", // whole1, thousandths1, whole2, thousandths2, whole3, thousandths3); for(j=0; j<10000;j++); // some delay //if(!XUartNs550_IsReceiveData(STDIN_BASEADDRESS)) //{ // continue; //} //else //{ // XUartNs550_ReadReg(STDIN_BASEADDRESS, XUN_RBR_OFFSET); // return 0; //} /* * Clear any bits set in the Interrupt Status Register. */ IntrStatus = XSysMon_IntrGetStatus(SysMonInstPtr); XSysMon_IntrClear(SysMonInstPtr, IntrStatus); /* * Disable global interrupt of System Monitor. */ XSysMon_IntrGlobalDisable(SysMonInstPtr); return XST_SUCCESS; }
/** * * This function runs a test on the System Monitor/ADC device using the * driver APIs. * This function does the following tasks: * - Initiate the System Monitor device driver instance * - Run self-test on the device * - Setup the sequence registers to continuously monitor on-chip * temperature, VCCINT and VCCAUX * - Setup configuration registers to start the sequence * - Read the latest on-chip temperature, VCCINT and VCCAUX * * @param SysMonDeviceId is the XPAR_<SYSMON_ADC_instance>_DEVICE_ID value * from xparameters.h. * * @return * - XST_SUCCESS if the example has completed successfully. * - XST_FAILURE if the example has failed. * * @note None * ****************************************************************************/ int SysMonPolledPrintfExample(u16 SysMonDeviceId) { int Status; XSysMon_Config *ConfigPtr; u32 TempRawData; u32 VccAuxRawData; u32 VccIntRawData; float TempData; float VccAuxData; float VccIntData; float MaxData; float MinData; XSysMon *SysMonInstPtr = &SysMonInst; printf("\r\nEntering the SysMon Polled Example. \r\n"); /* * Initialize the SysMon driver. */ ConfigPtr = XSysMon_LookupConfig(SysMonDeviceId); if (ConfigPtr == NULL) { return XST_FAILURE; } XSysMon_CfgInitialize(SysMonInstPtr, ConfigPtr, ConfigPtr->BaseAddress); /* * Self Test the System Monitor/ADC device */ Status = XSysMon_SelfTest(SysMonInstPtr); if (Status != XST_SUCCESS) { return XST_FAILURE; } /* * Disable the Channel Sequencer before configuring the Sequence * registers. */ XSysMon_SetSequencerMode(SysMonInstPtr, XSM_SEQ_MODE_SAFE); /* * Disable all the alarms in the Configuration Register 1. */ XSysMon_SetAlarmEnables(SysMonInstPtr, 0x0); /* * Setup the Averaging to be done for the channels in the * Configuration 0 register as 16 samples: */ XSysMon_SetAvg(SysMonInstPtr, XSM_AVG_16_SAMPLES); /* * Setup the Sequence register for 1st Auxiliary channel * Setting is: * - Add acquisition time by 6 ADCCLK cycles. * - Bipolar Mode * * Setup the Sequence register for 16th Auxiliary channel * Setting is: * - Add acquisition time by 6 ADCCLK cycles. * - Unipolar Mode */ Status = XSysMon_SetSeqInputMode(SysMonInstPtr, XSM_SEQ_CH_AUX00); if (Status != XST_SUCCESS) { return XST_FAILURE; } Status = XSysMon_SetSeqAcqTime(SysMonInstPtr, XSM_SEQ_CH_AUX15 | XSM_SEQ_CH_AUX00); if (Status != XST_SUCCESS) { return XST_FAILURE; } /* * Enable the averaging on the following channels in the Sequencer * registers: * - On-chip Temperature, VCCINT/VCCAUX supply sensors * - 1st/16th Auxiliary Channels * - Calibration Channel */ Status = XSysMon_SetSeqAvgEnables(SysMonInstPtr, XSM_SEQ_CH_TEMP | XSM_SEQ_CH_VCCINT | XSM_SEQ_CH_VCCAUX | XSM_SEQ_CH_AUX00 | XSM_SEQ_CH_AUX15 | XSM_SEQ_CH_CALIB); if (Status != XST_SUCCESS) { return XST_FAILURE; } /* * Enable the following channels in the Sequencer registers: * - On-chip Temperature, VCCINT/VCCAUX supply sensors * - 1st/16th Auxiliary Channel * - Calibration Channel */ Status = XSysMon_SetSeqChEnables(SysMonInstPtr, XSM_SEQ_CH_TEMP | XSM_SEQ_CH_VCCINT | XSM_SEQ_CH_VCCAUX | XSM_SEQ_CH_AUX00 | XSM_SEQ_CH_AUX15 | XSM_SEQ_CH_CALIB); if (Status != XST_SUCCESS) { return XST_FAILURE; } /* * Set the ADCCLK frequency equal to 1/32 of System clock for the System * Monitor/ADC in the Configuration Register 2. */ XSysMon_SetAdcClkDivisor(SysMonInstPtr, 32); /* * Set the Calibration enables. */ XSysMon_SetCalibEnables(SysMonInstPtr, XSM_CFR1_CAL_PS_GAIN_OFFSET_MASK | XSM_CFR1_CAL_ADC_GAIN_OFFSET_MASK); /* * Enable the Channel Sequencer in continuous sequencer cycling mode. */ XSysMon_SetSequencerMode(SysMonInstPtr, XSM_SEQ_MODE_CONTINPASS); /* * Wait till the End of Sequence occurs */ XSysMon_GetStatus(SysMonInstPtr); /* Clear the old status */ while ((XSysMon_GetStatus(SysMonInstPtr) & XSM_SR_EOS_MASK) != XSM_SR_EOS_MASK); /* * Read the on-chip Temperature Data (Current/Maximum/Minimum) * from the ADC data registers. */ TempRawData = XSysMon_GetAdcData(SysMonInstPtr, XSM_CH_TEMP); TempData = XSysMon_RawToTemperature(TempRawData); printf("\r\nThe Current Temperature is %0d.%03d Centigrades.\r\n", (int)(TempData), SysMonFractionToInt(TempData)); TempRawData = XSysMon_GetMinMaxMeasurement(SysMonInstPtr, XSM_MAX_TEMP); MaxData = XSysMon_RawToTemperature(TempRawData); printf("The Maximum Temperature is %0d.%03d Centigrades. \r\n", (int)(MaxData), SysMonFractionToInt(MaxData)); TempRawData = XSysMon_GetMinMaxMeasurement(SysMonInstPtr, XSM_MIN_TEMP); MinData = XSysMon_RawToTemperature(TempRawData); printf("The Minimum Temperature is %0d.%03d Centigrades. \r\n", (int)(MinData), SysMonFractionToInt(MinData)); /* * Read the VccInt Votage Data (Current/Maximum/Minimum) from the * ADC data registers. */ VccIntRawData = XSysMon_GetAdcData(SysMonInstPtr, XSM_CH_VCCINT); VccIntData = XSysMon_RawToVoltage(VccIntRawData); printf("\r\nThe Current VCCINT is %0d.%03d Volts. \r\n", (int)(VccIntData), SysMonFractionToInt(VccIntData)); VccIntRawData = XSysMon_GetMinMaxMeasurement(SysMonInstPtr, XSM_MAX_VCCINT); MaxData = XSysMon_RawToVoltage(VccIntRawData); printf("The Maximum VCCINT is %0d.%03d Volts. \r\n", (int)(MaxData), SysMonFractionToInt(MaxData)); VccIntRawData = XSysMon_GetMinMaxMeasurement(SysMonInstPtr, XSM_MIN_VCCINT); MinData = XSysMon_RawToVoltage(VccIntRawData); printf("The Minimum VCCINT is %0d.%03d Volts. \r\n", (int)(MinData), SysMonFractionToInt(MinData)); /* * Read the VccAux Votage Data (Current/Maximum/Minimum) from the * ADC data registers. */ VccAuxRawData = XSysMon_GetAdcData(SysMonInstPtr, XSM_CH_VCCAUX); VccAuxData = XSysMon_RawToVoltage(VccAuxRawData); printf("\r\nThe Current VCCAUX is %0d.%03d Volts. \r\n", (int)(VccAuxData), SysMonFractionToInt(VccAuxData)); VccAuxRawData = XSysMon_GetMinMaxMeasurement(SysMonInstPtr, XSM_MAX_VCCAUX); MaxData = XSysMon_RawToVoltage(VccAuxRawData); printf("The Maximum VCCAUX is %0d.%03d Volts. \r\n", (int)(MaxData), SysMonFractionToInt(MaxData)); VccAuxRawData = XSysMon_GetMinMaxMeasurement(SysMonInstPtr, XSM_MIN_VCCAUX); MinData = XSysMon_RawToVoltage(VccAuxRawData); printf("The Minimum VCCAUX is %0d.%03d Volts. \r\n\r\n", (int)(MinData), SysMonFractionToInt(MinData)); printf("Exiting the SysMon Polled Example. \r\n"); return XST_SUCCESS; }
/*************************************************************************** * Looks up the current config and initializes XADC_WIZ * * @ Channel: Chooses channel for single channel mode. Options are Channel 6, Channel 7, * Channel 14 and Channel 15. * * @ SequencerMode: Choose between SINGLE_CHANNEL_MODE (= XSM_SEQ_MODE_SINGCHAN) for single channel mode * or CONTINUOUS_SAMPLING_MODE(= XSM_SEQ_MODE_CONTINPASS) for continuous sequencing mode. * * Always in Differential mode * Always in continuous mode * Always slow AcQCycles ( for sequence mode of operations adjust XSysMon_SetSeqAcqTime(&SysMon , SEQ_CHANNELS) to * XSysMon_SetSeqAcqTime(&SysMon , ~SEQ_CHANNELS) ) * ***************************************************************************/ void init_XADC_WIZ(char channel, u8 SequencerMode) { int Status; int ParameterStatus; int SequenceStatus; int InputStatus; int AcqStatus; int IncreaseAcqCycles = FALSE; int IsEventMode = FALSE; int IsDifferentialMode = TRUE; u8 Divisor = 0; XSysMon_Config *Config; Config = XSysMon_LookupConfig(XPAR_XADC_WIZ_0_DEVICE_ID); if (NULL == Config) { //return XST_FAILURE; } Status = XSysMon_CfgInitialize(&SysMon,Config ,Config->BaseAddress); if (Status != XST_SUCCESS) { xil_printf("XADC_WIZ initialization FAILED!\n \r"); //return XST_FAILURE; } else { xil_printf("XADC_WIZ initialization SUCCESS!\n \r"); } /* NO averaging*/ XSysMon_SetAvg(&SysMon, XSM_AVG_0_SAMPLES); /* Calibrate ADC gain and offset + Power Supply gain and offset*/ XSysMon_SetCalibEnables(&SysMon, XSM_CFR1_CAL_ADC_GAIN_OFFSET_MASK | XSM_CFR1_CAL_PS_GAIN_OFFSET_MASK); /* Sets the channel seqence mode: * - Default safe mode (XSM_SEQ_MODE_SAFE) * - One pass through sequence (XSM_SEQ_MODE_ONEPASS) * - Continuous channel sequencing (XSM_SEQ_MODE_CONTINPASS) * - Single Channel/Sequencer off (XSM_SEQ_MODE_SINGCHAN) * - Simulataneous sampling mode (XSM_SEQ_MODE_SIMUL) * - Independent mode (XSM_SEQ_MODE_INDEPENDENT) * * NOTE: We will only use single channel mode and continious channel sequencing mode!!! */ if(SequencerMode = XSM_SEQ_MODE_SINGCHAN) { XSysMon_SetSequencerMode(&SysMon,XSM_SEQ_MODE_SINGCHAN); /* Sets the parameters for the single channel mode * int ParameterStatus; => Return value, =1 when failed * int IncreaseAcqCycles = FALSE; => TRUE: increased to 10 ADCCLK cycles | FALSE: default 4 ADCCLK cycles * int IsEventMode = FALSE; => TRUE: event driven sampling mode | FALSE: continious sampling mode * int IsDifferentialMode = TRUE; => TRUE: differential mode | FALSE: unipolar mode */ ParameterStatus = XSysMon_SetSingleChParams(&SysMon,(XSM_CH_AUX_MIN + (channel -1)), IncreaseAcqCycles, IsEventMode, IsDifferentialMode); if (ParameterStatus != XST_SUCCESS) { xil_printf("Setting SingleChannelParameters FAILED!\n \r"); } } else if(SequencerMode = XSM_SEQ_MODE_CONTINPASS) { XSysMon_SetSequencerMode(&SysMon,XSM_SEQ_MODE_SAFE); /* Settings need to be applied in safe mode*/ XSysMon_SetSequencerEvent(&SysMon, IsEventMode); /* IsEventmode = FALSE => continious sampling!*/ XSysMon_SetAdcClkDivisor(&SysMon, Divisor); /* Divisor sets the clockdevision for the ADC sampling*/ SequenceStatus= XSysMon_SetSeqChEnables(&SysMon,SEQ_CHANNELS); /* Selects channels to sequence*/ if (SequenceStatus != XST_SUCCESS) { xil_printf("Enabling Sequence Channels FAILED!\n \r"); } InputStatus = XSysMon_SetSeqInputMode(&SysMon, SEQ_CHANNELS); /* Sets the channels to differential mode */ if (InputStatus != XST_SUCCESS) { xil_printf("Setting Input Mode FAILED!\n \r"); } AcqStatus = XSysMon_SetSeqAcqTime(&SysMon , SEQ_CHANNELS); /* If function is enabled: Acquisition cycles will be extended to 10 ADCCLK cycles*/ if (AcqStatus != XST_SUCCESS) { xil_printf("Setting AcqTime FAILED!\n \r"); } XSysMon_SetSequencerMode(&SysMon,XSM_SEQ_MODE_CONTINPASS); /* Continuous sampling mode enabled */ } }