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Dependents:   VL53L0X-mbedOS-master VL53L0X-mbedOS-masterbb

vl53l0x_api_calibration.c

Committer:
mohamedachour
Date:
2019-04-23
Revision:
2:a1dffa1ff38a
Parent:
0:e6fcdb78a136

File content as of revision 2:a1dffa1ff38a:

/*******************************************************************************
 Copyright © 2016, STMicroelectronics International N.V.
 All rights reserved.

 Redistribution and use in source and binary forms, with or without
 modification, are permitted provided that the following conditions are met:
 * Redistributions of source code must retain the above copyright
 notice, this list of conditions and the following disclaimer.
 * Redistributions in binary form must reproduce the above copyright
 notice, this list of conditions and the following disclaimer in the
 documentation and/or other materials provided with the distribution.
 * Neither the name of STMicroelectronics nor the
 names of its contributors may be used to endorse or promote products
 derived from this software without specific prior written permission.

 THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
 ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
 WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE, AND
 NON-INFRINGEMENT OF INTELLECTUAL PROPERTY RIGHTS ARE DISCLAIMED.
 IN NO EVENT SHALL STMICROELECTRONICS INTERNATIONAL N.V. BE LIABLE FOR ANY
 DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
 (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
 LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
 ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
 (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
 SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
 ******************************************************************************/

#include "vl53l0x_api.h"
#include "vl53l0x_api_core.h"
#include "vl53l0x_api_calibration.h"

#ifndef __KERNEL__
#include <stdlib.h>
#endif

#define LOG_FUNCTION_START(fmt, ...) \
	_LOG_FUNCTION_START(TRACE_MODULE_API, fmt, ##__VA_ARGS__)
#define LOG_FUNCTION_END(status, ...) \
	_LOG_FUNCTION_END(TRACE_MODULE_API, status, ##__VA_ARGS__)
#define LOG_FUNCTION_END_FMT(status, fmt, ...) \
	_LOG_FUNCTION_END_FMT(TRACE_MODULE_API, status, fmt, ##__VA_ARGS__)

#define REF_ARRAY_SPAD_0  0
#define REF_ARRAY_SPAD_5  5
#define REF_ARRAY_SPAD_10 10

uint32_t refArrayQuadrants[4] = {REF_ARRAY_SPAD_10, REF_ARRAY_SPAD_5,
		REF_ARRAY_SPAD_0, REF_ARRAY_SPAD_5 };

VL53L0X_Error VL53L0X_perform_xtalk_calibration(VL53L0X_DEV Dev,
			FixPoint1616_t XTalkCalDistance,
			FixPoint1616_t *pXTalkCompensationRateMegaCps)
{
	VL53L0X_Error Status = VL53L0X_ERROR_NONE;
	uint16_t sum_ranging = 0;
	uint16_t sum_spads = 0;
	FixPoint1616_t sum_signalRate = 0;
	FixPoint1616_t total_count = 0;
	uint8_t xtalk_meas = 0;
	VL53L0X_RangingMeasurementData_t RangingMeasurementData;
	FixPoint1616_t xTalkStoredMeanSignalRate;
	FixPoint1616_t xTalkStoredMeanRange;
	FixPoint1616_t xTalkStoredMeanRtnSpads;
	uint32_t signalXTalkTotalPerSpad;
	uint32_t xTalkStoredMeanRtnSpadsAsInt;
	uint32_t xTalkCalDistanceAsInt;
	FixPoint1616_t XTalkCompensationRateMegaCps;

	if (XTalkCalDistance <= 0)
		Status = VL53L0X_ERROR_INVALID_PARAMS;

	/* Disable the XTalk compensation */
	if (Status == VL53L0X_ERROR_NONE)
		Status = VL53L0X_SetXTalkCompensationEnable(Dev, 0);

	/* Disable the RIT */
	if (Status == VL53L0X_ERROR_NONE) {
		Status = VL53L0X_SetLimitCheckEnable(Dev,
				VL53L0X_CHECKENABLE_RANGE_IGNORE_THRESHOLD, 0);
	}

	/* Perform 50 measurements and compute the averages */
	if (Status == VL53L0X_ERROR_NONE) {
		sum_ranging = 0;
		sum_spads = 0;
		sum_signalRate = 0;
		total_count = 0;
		for (xtalk_meas = 0; xtalk_meas < 50; xtalk_meas++) {
			Status = VL53L0X_PerformSingleRangingMeasurement(Dev,
				&RangingMeasurementData);

			if (Status != VL53L0X_ERROR_NONE)
				break;

			/* The range is valid when RangeStatus = 0 */
			if (RangingMeasurementData.RangeStatus == 0) {
				sum_ranging = sum_ranging +
					RangingMeasurementData.RangeMilliMeter;
				sum_signalRate = sum_signalRate +
				RangingMeasurementData.SignalRateRtnMegaCps;
				sum_spads = sum_spads +
				RangingMeasurementData.EffectiveSpadRtnCount
					/ 256;
				total_count = total_count + 1;
			}
		}

		/* no valid values found */
		if (total_count == 0)
			Status = VL53L0X_ERROR_RANGE_ERROR;

	}


	if (Status == VL53L0X_ERROR_NONE) {
		/* FixPoint1616_t / uint16_t = FixPoint1616_t */
		xTalkStoredMeanSignalRate = sum_signalRate / total_count;
		xTalkStoredMeanRange = (FixPoint1616_t)((uint32_t)(
			sum_ranging << 16) / total_count);
		xTalkStoredMeanRtnSpads = (FixPoint1616_t)((uint32_t)(
			sum_spads << 16) / total_count);

		/* Round Mean Spads to Whole Number.
		 * Typically the calculated mean SPAD count is a whole number
		 * or very close to a whole
		 * number, therefore any truncation will not result in a
		 * significant loss in accuracy.
		 * Also, for a grey target at a typical distance of around
		 * 400mm, around 220 SPADs will
		 * be enabled, therefore, any truncation will result in a loss
		 * of accuracy of less than
		 * 0.5%.
		 */
		xTalkStoredMeanRtnSpadsAsInt = (xTalkStoredMeanRtnSpads +
			0x8000) >> 16;

		/* Round Cal Distance to Whole Number.
		 * Note that the cal distance is in mm, therefore no resolution
		 * is lost.*/
		 xTalkCalDistanceAsInt = (XTalkCalDistance + 0x8000) >> 16;

		if (xTalkStoredMeanRtnSpadsAsInt == 0 ||
		   xTalkCalDistanceAsInt == 0 ||
		   xTalkStoredMeanRange >= XTalkCalDistance) {
			XTalkCompensationRateMegaCps = 0;
		} else {
			/* Round Cal Distance to Whole Number.
			   Note that the cal distance is in mm, therefore no
			   resolution is lost.*/
			xTalkCalDistanceAsInt = (XTalkCalDistance +
				0x8000) >> 16;

			/* Apply division by mean spad count early in the
			 * calculation to keep the numbers small.
			 * This ensures we can maintain a 32bit calculation.
			 * Fixed1616 / int := Fixed1616 */
			signalXTalkTotalPerSpad = (xTalkStoredMeanSignalRate) /
				xTalkStoredMeanRtnSpadsAsInt;

			/* Complete the calculation for total Signal XTalk per
			 * SPAD
			 * Fixed1616 * (Fixed1616 - Fixed1616/int) :=
			 * (2^16 * Fixed1616)
			 */
			signalXTalkTotalPerSpad *= ((1 << 16) -
				(xTalkStoredMeanRange / xTalkCalDistanceAsInt));

			/* Round from 2^16 * Fixed1616, to Fixed1616. */
			XTalkCompensationRateMegaCps = (signalXTalkTotalPerSpad
				+ 0x8000) >> 16;
		}

		*pXTalkCompensationRateMegaCps = XTalkCompensationRateMegaCps;

		/* Enable the XTalk compensation */
		if (Status == VL53L0X_ERROR_NONE)
			Status = VL53L0X_SetXTalkCompensationEnable(Dev, 1);

		/* Enable the XTalk compensation */
		if (Status == VL53L0X_ERROR_NONE)
			Status = VL53L0X_SetXTalkCompensationRateMegaCps(Dev,
					XTalkCompensationRateMegaCps);

	}

	return Status;
}

VL53L0X_Error VL53L0X_perform_offset_calibration(VL53L0X_DEV Dev,
			FixPoint1616_t CalDistanceMilliMeter,
			int32_t *pOffsetMicroMeter)
{
	VL53L0X_Error Status = VL53L0X_ERROR_NONE;
	uint16_t sum_ranging = 0;
	FixPoint1616_t total_count = 0;
	VL53L0X_RangingMeasurementData_t RangingMeasurementData;
	FixPoint1616_t StoredMeanRange;
	uint32_t StoredMeanRangeAsInt;
	uint32_t CalDistanceAsInt_mm;
	uint8_t SequenceStepEnabled;
	int meas = 0;

	if (CalDistanceMilliMeter <= 0)
		Status = VL53L0X_ERROR_INVALID_PARAMS;

	if (Status == VL53L0X_ERROR_NONE)
		Status = VL53L0X_SetOffsetCalibrationDataMicroMeter(Dev, 0);


	/* Get the value of the TCC */
	if (Status == VL53L0X_ERROR_NONE)
		Status = VL53L0X_GetSequenceStepEnable(Dev,
				VL53L0X_SEQUENCESTEP_TCC, &SequenceStepEnabled);


	/* Disable the TCC */
	if (Status == VL53L0X_ERROR_NONE)
		Status = VL53L0X_SetSequenceStepEnable(Dev,
				VL53L0X_SEQUENCESTEP_TCC, 0);


	/* Disable the RIT */
	if (Status == VL53L0X_ERROR_NONE)
		Status = VL53L0X_SetLimitCheckEnable(Dev,
				VL53L0X_CHECKENABLE_RANGE_IGNORE_THRESHOLD, 0);

	/* Perform 50 measurements and compute the averages */
	if (Status == VL53L0X_ERROR_NONE) {
		sum_ranging = 0;
		total_count = 0;
		for (meas = 0; meas < 50; meas++) {
			Status = VL53L0X_PerformSingleRangingMeasurement(Dev,
					&RangingMeasurementData);

			if (Status != VL53L0X_ERROR_NONE)
				break;

			/* The range is valid when RangeStatus = 0 */
			if (RangingMeasurementData.RangeStatus == 0) {
				sum_ranging = sum_ranging +
					RangingMeasurementData.RangeMilliMeter;
				total_count = total_count + 1;
			}
		}

		/* no valid values found */
		if (total_count == 0)
			Status = VL53L0X_ERROR_RANGE_ERROR;
	}


	if (Status == VL53L0X_ERROR_NONE) {
		/* FixPoint1616_t / uint16_t = FixPoint1616_t */
		StoredMeanRange = (FixPoint1616_t)((uint32_t)(sum_ranging << 16)
			/ total_count);

		StoredMeanRangeAsInt = (StoredMeanRange + 0x8000) >> 16;

		/* Round Cal Distance to Whole Number.
		 * Note that the cal distance is in mm, therefore no resolution
		 * is lost.*/
		 CalDistanceAsInt_mm = (CalDistanceMilliMeter + 0x8000) >> 16;

		 *pOffsetMicroMeter = (CalDistanceAsInt_mm -
				 StoredMeanRangeAsInt) * 1000;

		/* Apply the calculated offset */
		if (Status == VL53L0X_ERROR_NONE) {
			VL53L0X_SETPARAMETERFIELD(Dev, RangeOffsetMicroMeters,
					*pOffsetMicroMeter);
			Status = VL53L0X_SetOffsetCalibrationDataMicroMeter(Dev,
					*pOffsetMicroMeter);
		}

	}

	/* Restore the TCC */
	if (Status == VL53L0X_ERROR_NONE) {
		if (SequenceStepEnabled != 0)
			Status = VL53L0X_SetSequenceStepEnable(Dev,
					VL53L0X_SEQUENCESTEP_TCC, 1);
	}

	return Status;
}


VL53L0X_Error VL53L0X_set_offset_calibration_data_micro_meter(VL53L0X_DEV Dev,
		int32_t OffsetCalibrationDataMicroMeter)
{
	VL53L0X_Error Status = VL53L0X_ERROR_NONE;
	int32_t cMaxOffsetMicroMeter = 511000;
	int32_t cMinOffsetMicroMeter = -512000;
	int16_t cOffsetRange = 4096;
	uint32_t encodedOffsetVal;

	LOG_FUNCTION_START("");

	if (OffsetCalibrationDataMicroMeter > cMaxOffsetMicroMeter)
		OffsetCalibrationDataMicroMeter = cMaxOffsetMicroMeter;
	else if (OffsetCalibrationDataMicroMeter < cMinOffsetMicroMeter)
		OffsetCalibrationDataMicroMeter = cMinOffsetMicroMeter;

	/* The offset register is 10.2 format and units are mm
	 * therefore conversion is applied by a division of
	 * 250.
	 */
	if (OffsetCalibrationDataMicroMeter >= 0) {
		encodedOffsetVal =
			OffsetCalibrationDataMicroMeter/250;
	} else {
		encodedOffsetVal =
			cOffsetRange +
			OffsetCalibrationDataMicroMeter/250;
	}

	Status = VL53L0X_WrWord(Dev,
		VL53L0X_REG_ALGO_PART_TO_PART_RANGE_OFFSET_MM,
		encodedOffsetVal);

	LOG_FUNCTION_END(Status);
	return Status;
}

VL53L0X_Error VL53L0X_get_offset_calibration_data_micro_meter(VL53L0X_DEV Dev,
		int32_t *pOffsetCalibrationDataMicroMeter)
{
	VL53L0X_Error Status = VL53L0X_ERROR_NONE;
	uint16_t RangeOffsetRegister;
	int16_t cMaxOffset = 2047;
	int16_t cOffsetRange = 4096;

	/* Note that offset has 10.2 format */

	Status = VL53L0X_RdWord(Dev,
				VL53L0X_REG_ALGO_PART_TO_PART_RANGE_OFFSET_MM,
				&RangeOffsetRegister);

	if (Status == VL53L0X_ERROR_NONE) {
		RangeOffsetRegister = (RangeOffsetRegister & 0x0fff);

		/* Apply 12 bit 2's compliment conversion */
		if (RangeOffsetRegister > cMaxOffset)
			*pOffsetCalibrationDataMicroMeter =
				(int16_t)(RangeOffsetRegister - cOffsetRange)
					* 250;
		else
			*pOffsetCalibrationDataMicroMeter =
				(int16_t)RangeOffsetRegister * 250;

	}

	return Status;
}


VL53L0X_Error VL53L0X_apply_offset_adjustment(VL53L0X_DEV Dev)
{
	VL53L0X_Error Status = VL53L0X_ERROR_NONE;
	int32_t CorrectedOffsetMicroMeters;
	int32_t CurrentOffsetMicroMeters;

	/* if we run on this function we can read all the NVM info
	 * used by the API */
	Status = VL53L0X_get_info_from_device(Dev, 7);

	/* Read back current device offset */
	if (Status == VL53L0X_ERROR_NONE) {
		Status = VL53L0X_GetOffsetCalibrationDataMicroMeter(Dev,
					&CurrentOffsetMicroMeters);
	}

	/* Apply Offset Adjustment derived from 400mm measurements */
	if (Status == VL53L0X_ERROR_NONE) {

		/* Store initial device offset */
		PALDevDataSet(Dev, Part2PartOffsetNVMMicroMeter,
			CurrentOffsetMicroMeters);

		CorrectedOffsetMicroMeters = CurrentOffsetMicroMeters +
			(int32_t)PALDevDataGet(Dev,
				Part2PartOffsetAdjustmentNVMMicroMeter);

		Status = VL53L0X_SetOffsetCalibrationDataMicroMeter(Dev,
					CorrectedOffsetMicroMeters);

		/* store current, adjusted offset */
		if (Status == VL53L0X_ERROR_NONE) {
			VL53L0X_SETPARAMETERFIELD(Dev, RangeOffsetMicroMeters,
					CorrectedOffsetMicroMeters);
		}
	}

	return Status;
}

void get_next_good_spad(uint8_t goodSpadArray[], uint32_t size,
			uint32_t curr, int32_t *next)
{
	uint32_t startIndex;
	uint32_t fineOffset;
	uint32_t cSpadsPerByte = 8;
	uint32_t coarseIndex;
	uint32_t fineIndex;
	uint8_t dataByte;
	uint8_t success = 0;

	/*
	 * Starting with the current good spad, loop through the array to find
	 * the next. i.e. the next bit set in the sequence.
	 *
	 * The coarse index is the byte index of the array and the fine index is
	 * the index of the bit within each byte.
	 */

	*next = -1;

	startIndex = curr / cSpadsPerByte;
	fineOffset = curr % cSpadsPerByte;

	for (coarseIndex = startIndex; ((coarseIndex < size) && !success);
				coarseIndex++) {
		fineIndex = 0;
		dataByte = goodSpadArray[coarseIndex];

		if (coarseIndex == startIndex) {
			/* locate the bit position of the provided current
			 * spad bit before iterating */
			dataByte >>= fineOffset;
			fineIndex = fineOffset;
		}

		while (fineIndex < cSpadsPerByte) {
			if ((dataByte & 0x1) == 1) {
				success = 1;
				*next = coarseIndex * cSpadsPerByte + fineIndex;
				break;
			}
			dataByte >>= 1;
			fineIndex++;
		}
	}
}


uint8_t is_aperture(uint32_t spadIndex)
{
	/*
	 * This function reports if a given spad index is an aperture SPAD by
	 * deriving the quadrant.
	 */
	uint32_t quadrant;
	uint8_t isAperture = 1;
	quadrant = spadIndex >> 6;
	if (refArrayQuadrants[quadrant] == REF_ARRAY_SPAD_0)
		isAperture = 0;

	return isAperture;
}


VL53L0X_Error enable_spad_bit(uint8_t spadArray[], uint32_t size,
	uint32_t spadIndex)
{
	VL53L0X_Error status = VL53L0X_ERROR_NONE;
	uint32_t cSpadsPerByte = 8;
	uint32_t coarseIndex;
	uint32_t fineIndex;

	coarseIndex = spadIndex / cSpadsPerByte;
	fineIndex = spadIndex % cSpadsPerByte;
	if (coarseIndex >= size)
		status = VL53L0X_ERROR_REF_SPAD_INIT;
	else
		spadArray[coarseIndex] |= (1 << fineIndex);

	return status;
}

VL53L0X_Error count_enabled_spads(uint8_t spadArray[],
		uint32_t byteCount, uint32_t maxSpads,
		uint32_t *pTotalSpadsEnabled, uint8_t *pIsAperture)
{
	VL53L0X_Error status = VL53L0X_ERROR_NONE;
	uint32_t cSpadsPerByte = 8;
	uint32_t lastByte;
	uint32_t lastBit;
	uint32_t byteIndex = 0;
	uint32_t bitIndex = 0;
	uint8_t tempByte;
	uint8_t spadTypeIdentified = 0;

	/* The entire array will not be used for spads, therefore the last
	 * byte and last bit is determined from the max spads value.
	 */

	lastByte = maxSpads / cSpadsPerByte;
	lastBit = maxSpads % cSpadsPerByte;

	/* Check that the max spads value does not exceed the array bounds. */
	if (lastByte >= byteCount)
		status = VL53L0X_ERROR_REF_SPAD_INIT;

	*pTotalSpadsEnabled = 0;

	/* Count the bits enabled in the whole bytes */
	for (byteIndex = 0; byteIndex <= (lastByte - 1); byteIndex++) {
		tempByte = spadArray[byteIndex];

		for (bitIndex = 0; bitIndex <= cSpadsPerByte; bitIndex++) {
			if ((tempByte & 0x01) == 1) {
				(*pTotalSpadsEnabled)++;

				if (!spadTypeIdentified) {
					*pIsAperture = 1;
					if ((byteIndex < 2) && (bitIndex < 4))
							*pIsAperture = 0;
					spadTypeIdentified = 1;
				}
			}
			tempByte >>= 1;
		}
	}

	/* Count the number of bits enabled in the last byte accounting
	 * for the fact that not all bits in the byte may be used.
	 */
	tempByte = spadArray[lastByte];

	for (bitIndex = 0; bitIndex <= lastBit; bitIndex++) {
		if ((tempByte & 0x01) == 1)
			(*pTotalSpadsEnabled)++;
	}

	return status;
}

VL53L0X_Error set_ref_spad_map(VL53L0X_DEV Dev, uint8_t *refSpadArray)
{
	VL53L0X_Error status = VL53L0X_WriteMulti(Dev,
				VL53L0X_REG_GLOBAL_CONFIG_SPAD_ENABLES_REF_0,
				refSpadArray, 6);
	return status;
}

VL53L0X_Error get_ref_spad_map(VL53L0X_DEV Dev, uint8_t *refSpadArray)
{
	VL53L0X_Error status = VL53L0X_ReadMulti(Dev,
				VL53L0X_REG_GLOBAL_CONFIG_SPAD_ENABLES_REF_0,
				refSpadArray,
				6);
	return status;
}

VL53L0X_Error enable_ref_spads(VL53L0X_DEV Dev,
				uint8_t apertureSpads,
				uint8_t goodSpadArray[],
				uint8_t spadArray[],
				uint32_t size,
				uint32_t start,
				uint32_t offset,
				uint32_t spadCount,
				uint32_t *lastSpad)
{
	VL53L0X_Error status = VL53L0X_ERROR_NONE;
	uint32_t index;
	uint32_t i;
	int32_t nextGoodSpad = offset;
	uint32_t currentSpad;
	uint8_t checkSpadArray[6];

	/*
	 * This function takes in a spad array which may or may not have SPADS
	 * already enabled and appends from a given offset a requested number
	 * of new SPAD enables. The 'good spad map' is applied to
	 * determine the next SPADs to enable.
	 *
	 * This function applies to only aperture or only non-aperture spads.
	 * Checks are performed to ensure this.
	 */

	currentSpad = offset;
	for (index = 0; index < spadCount; index++) {
		get_next_good_spad(goodSpadArray, size, currentSpad,
			&nextGoodSpad);

		if (nextGoodSpad == -1) {
			status = VL53L0X_ERROR_REF_SPAD_INIT;
			break;
		}

		/* Confirm that the next good SPAD is non-aperture */
		if (is_aperture(start + nextGoodSpad) != apertureSpads) {
			/* if we can't get the required number of good aperture
			 * spads from the current quadrant then this is an error
			 */
			status = VL53L0X_ERROR_REF_SPAD_INIT;
			break;
		}
		currentSpad = (uint32_t)nextGoodSpad;
		enable_spad_bit(spadArray, size, currentSpad);
		currentSpad++;
	}
	*lastSpad = currentSpad;

	if (status == VL53L0X_ERROR_NONE)
		status = set_ref_spad_map(Dev, spadArray);


	if (status == VL53L0X_ERROR_NONE) {
		status = get_ref_spad_map(Dev, checkSpadArray);

		i = 0;

		/* Compare spad maps. If not equal report error. */
		while (i < size) {
			if (spadArray[i] != checkSpadArray[i]) {
				status = VL53L0X_ERROR_REF_SPAD_INIT;
				break;
			}
			i++;
		}
	}
	return status;
}


VL53L0X_Error perform_ref_signal_measurement(VL53L0X_DEV Dev,
		uint16_t *refSignalRate)
{
	VL53L0X_Error status = VL53L0X_ERROR_NONE;
	VL53L0X_RangingMeasurementData_t rangingMeasurementData;

	uint8_t SequenceConfig = 0;

	/* store the value of the sequence config,
	 * this will be reset before the end of the function
	 */

	SequenceConfig = PALDevDataGet(Dev, SequenceConfig);

	/*
	 * This function performs a reference signal rate measurement.
	 */
	if (status == VL53L0X_ERROR_NONE)
		status = VL53L0X_WrByte(Dev,
			VL53L0X_REG_SYSTEM_SEQUENCE_CONFIG, 0xC0);

	if (status == VL53L0X_ERROR_NONE)
		status = VL53L0X_PerformSingleRangingMeasurement(Dev,
				&rangingMeasurementData);

	if (status == VL53L0X_ERROR_NONE)
		status = VL53L0X_WrByte(Dev, 0xFF, 0x01);

	if (status == VL53L0X_ERROR_NONE)
		status = VL53L0X_RdWord(Dev,
			VL53L0X_REG_RESULT_PEAK_SIGNAL_RATE_REF,
			refSignalRate);

	if (status == VL53L0X_ERROR_NONE)
		status = VL53L0X_WrByte(Dev, 0xFF, 0x00);

	if (status == VL53L0X_ERROR_NONE) {
		/* restore the previous Sequence Config */
		status = VL53L0X_WrByte(Dev, VL53L0X_REG_SYSTEM_SEQUENCE_CONFIG,
				SequenceConfig);
		if (status == VL53L0X_ERROR_NONE)
			PALDevDataSet(Dev, SequenceConfig, SequenceConfig);
	}

	return status;
}

VL53L0X_Error VL53L0X_perform_ref_spad_management(VL53L0X_DEV Dev,
				uint32_t *refSpadCount,
				uint8_t *isApertureSpads)
{
	VL53L0X_Error Status = VL53L0X_ERROR_NONE;
	uint8_t lastSpadArray[6];
	uint8_t startSelect = 0xB4;
	uint32_t minimumSpadCount = 3;
	uint32_t maxSpadCount = 44;
	uint32_t currentSpadIndex = 0;
	uint32_t lastSpadIndex = 0;
	int32_t nextGoodSpad = 0;
	uint16_t targetRefRate = 0x0A00; /* 20 MCPS in 9:7 format */
	uint16_t peakSignalRateRef;
	uint32_t needAptSpads = 0;
	uint32_t index = 0;
	uint32_t spadArraySize = 6;
	uint32_t signalRateDiff = 0;
	uint32_t lastSignalRateDiff = 0;
	uint8_t complete = 0;
	uint8_t VhvSettings = 0;
	uint8_t PhaseCal = 0;
	uint32_t refSpadCount_int = 0;
	uint8_t	 isApertureSpads_int = 0;

	/*
	 * The reference SPAD initialization procedure determines the minimum
	 * amount of reference spads to be enables to achieve a target reference
	 * signal rate and should be performed once during initialization.
	 *
	 * Either aperture or non-aperture spads are applied but never both.
	 * Firstly non-aperture spads are set, begining with 5 spads, and
	 * increased one spad at a time until the closest measurement to the
	 * target rate is achieved.
	 *
	 * If the target rate is exceeded when 5 non-aperture spads are enabled,
	 * initialization is performed instead with aperture spads.
	 *
	 * When setting spads, a 'Good Spad Map' is applied.
	 *
	 * This procedure operates within a SPAD window of interest of a maximum
	 * 44 spads.
	 * The start point is currently fixed to 180, which lies towards the end
	 * of the non-aperture quadrant and runs in to the adjacent aperture
	 * quadrant.
	 */


	targetRefRate = PALDevDataGet(Dev, targetRefRate);

	/*
	 * Initialize Spad arrays.
	 * Currently the good spad map is initialised to 'All good'.
	 * This is a short term implementation. The good spad map will be
	 * provided as an input.
	 * Note that there are 6 bytes. Only the first 44 bits will be used to
	 * represent spads.
	 */
	for (index = 0; index < spadArraySize; index++)
		Dev->Data.SpadData.RefSpadEnables[index] = 0;


	Status = VL53L0X_WrByte(Dev, 0xFF, 0x01);

	if (Status == VL53L0X_ERROR_NONE)
		Status = VL53L0X_WrByte(Dev,
			VL53L0X_REG_DYNAMIC_SPAD_REF_EN_START_OFFSET, 0x00);

	if (Status == VL53L0X_ERROR_NONE)
		Status = VL53L0X_WrByte(Dev,
			VL53L0X_REG_DYNAMIC_SPAD_NUM_REQUESTED_REF_SPAD, 0x2C);

	if (Status == VL53L0X_ERROR_NONE)
		Status = VL53L0X_WrByte(Dev, 0xFF, 0x00);

	if (Status == VL53L0X_ERROR_NONE)
		Status = VL53L0X_WrByte(Dev,
			VL53L0X_REG_GLOBAL_CONFIG_REF_EN_START_SELECT,
			startSelect);


	if (Status == VL53L0X_ERROR_NONE)
		Status = VL53L0X_WrByte(Dev,
				VL53L0X_REG_POWER_MANAGEMENT_GO1_POWER_FORCE, 0);

	/* Perform ref calibration */
	if (Status == VL53L0X_ERROR_NONE)
		Status = VL53L0X_perform_ref_calibration(Dev, &VhvSettings,
			&PhaseCal, 0);

	if (Status == VL53L0X_ERROR_NONE) {
		/* Enable Minimum NON-APERTURE Spads */
		currentSpadIndex = 0;
		lastSpadIndex = currentSpadIndex;
		needAptSpads = 0;
		Status = enable_ref_spads(Dev,
					needAptSpads,
					Dev->Data.SpadData.RefGoodSpadMap,
					Dev->Data.SpadData.RefSpadEnables,
					spadArraySize,
					startSelect,
					currentSpadIndex,
					minimumSpadCount,
					&lastSpadIndex);
	}

	if (Status == VL53L0X_ERROR_NONE) {
		currentSpadIndex = lastSpadIndex;

		Status = perform_ref_signal_measurement(Dev,
			&peakSignalRateRef);
		if ((Status == VL53L0X_ERROR_NONE) &&
			(peakSignalRateRef > targetRefRate)) {
			/* Signal rate measurement too high,
			 * switch to APERTURE SPADs */

			for (index = 0; index < spadArraySize; index++)
				Dev->Data.SpadData.RefSpadEnables[index] = 0;


			/* Increment to the first APERTURE spad */
			while ((is_aperture(startSelect + currentSpadIndex)
				== 0) && (currentSpadIndex < maxSpadCount)) {
				currentSpadIndex++;
			}

			needAptSpads = 1;

			Status = enable_ref_spads(Dev,
					needAptSpads,
					Dev->Data.SpadData.RefGoodSpadMap,
					Dev->Data.SpadData.RefSpadEnables,
					spadArraySize,
					startSelect,
					currentSpadIndex,
					minimumSpadCount,
					&lastSpadIndex);

			if (Status == VL53L0X_ERROR_NONE) {
				currentSpadIndex = lastSpadIndex;
				Status = perform_ref_signal_measurement(Dev,
						&peakSignalRateRef);

				if ((Status == VL53L0X_ERROR_NONE) &&
					(peakSignalRateRef > targetRefRate)) {
					/* Signal rate still too high after
					 * setting the minimum number of
					 * APERTURE spads. Can do no more
					 * therefore set the min number of
					 * aperture spads as the result.
					 */
					isApertureSpads_int = 1;
					refSpadCount_int = minimumSpadCount;
				}
			}
		} else {
			needAptSpads = 0;
		}
	}

	if ((Status == VL53L0X_ERROR_NONE) &&
		(peakSignalRateRef < targetRefRate)) {
		/* At this point, the minimum number of either aperture
		 * or non-aperture spads have been set. Proceed to add
		 * spads and perform measurements until the target
		 * reference is reached.
		 */
		isApertureSpads_int = needAptSpads;
		refSpadCount_int	= minimumSpadCount;

		memcpy(lastSpadArray, Dev->Data.SpadData.RefSpadEnables,
				spadArraySize);
		lastSignalRateDiff = abs(peakSignalRateRef -
			targetRefRate);
		complete = 0;

		while (!complete) {
			get_next_good_spad(
				Dev->Data.SpadData.RefGoodSpadMap,
				spadArraySize, currentSpadIndex,
				&nextGoodSpad);

			if (nextGoodSpad == -1) {
				Status = VL53L0X_ERROR_REF_SPAD_INIT;
				break;
			}

			(refSpadCount_int)++;

			/* Cannot combine Aperture and Non-Aperture spads, so
			 * ensure the current spad is of the correct type.
			 */
			if (is_aperture((uint32_t)startSelect + nextGoodSpad) !=
					needAptSpads) {
				Status = VL53L0X_ERROR_REF_SPAD_INIT;
				break;
			}

			currentSpadIndex = nextGoodSpad;
			Status = enable_spad_bit(
					Dev->Data.SpadData.RefSpadEnables,
					spadArraySize, currentSpadIndex);

			if (Status == VL53L0X_ERROR_NONE) {
				currentSpadIndex++;
				/* Proceed to apply the additional spad and
				 * perform measurement. */
				Status = set_ref_spad_map(Dev,
					Dev->Data.SpadData.RefSpadEnables);
			}

			if (Status != VL53L0X_ERROR_NONE)
				break;

			Status = perform_ref_signal_measurement(Dev,
					&peakSignalRateRef);

			if (Status != VL53L0X_ERROR_NONE)
				break;

			signalRateDiff = abs(peakSignalRateRef - targetRefRate);

			if (peakSignalRateRef > targetRefRate) {
				/* Select the spad map that provides the
				 * measurement closest to the target rate,
				 * either above or below it.
				 */
				if (signalRateDiff > lastSignalRateDiff) {
					/* Previous spad map produced a closer
					 * measurement, so choose this. */
					Status = set_ref_spad_map(Dev,
							lastSpadArray);
					memcpy(
					Dev->Data.SpadData.RefSpadEnables,
					lastSpadArray, spadArraySize);

					(refSpadCount_int)--;
				}
				complete = 1;
			} else {
				/* Continue to add spads */
				lastSignalRateDiff = signalRateDiff;
				memcpy(lastSpadArray,
					Dev->Data.SpadData.RefSpadEnables,
					spadArraySize);
			}

		} /* while */
	}

	if (Status == VL53L0X_ERROR_NONE) {
		*refSpadCount = refSpadCount_int;
		*isApertureSpads = isApertureSpads_int;

		VL53L0X_SETDEVICESPECIFICPARAMETER(Dev, RefSpadsInitialised, 1);
		VL53L0X_SETDEVICESPECIFICPARAMETER(Dev,
			ReferenceSpadCount, (uint8_t)(*refSpadCount));
		VL53L0X_SETDEVICESPECIFICPARAMETER(Dev,
			ReferenceSpadType, *isApertureSpads);
	}

	return Status;
}

VL53L0X_Error VL53L0X_set_reference_spads(VL53L0X_DEV Dev,
				 uint32_t count, uint8_t isApertureSpads)
{
	VL53L0X_Error Status = VL53L0X_ERROR_NONE;
	uint32_t currentSpadIndex = 0;
	uint8_t startSelect = 0xB4;
	uint32_t spadArraySize = 6;
	uint32_t maxSpadCount = 44;
	uint32_t lastSpadIndex;
	uint32_t index;

	/*
	 * This function applies a requested number of reference spads, either
	 * aperture or
	 * non-aperture, as requested.
	 * The good spad map will be applied.
	 */

	Status = VL53L0X_WrByte(Dev, 0xFF, 0x01);

	if (Status == VL53L0X_ERROR_NONE)
		Status = VL53L0X_WrByte(Dev,
			VL53L0X_REG_DYNAMIC_SPAD_REF_EN_START_OFFSET, 0x00);

	if (Status == VL53L0X_ERROR_NONE)
		Status = VL53L0X_WrByte(Dev,
			VL53L0X_REG_DYNAMIC_SPAD_NUM_REQUESTED_REF_SPAD, 0x2C);

	if (Status == VL53L0X_ERROR_NONE)
		Status = VL53L0X_WrByte(Dev, 0xFF, 0x00);

	if (Status == VL53L0X_ERROR_NONE)
		Status = VL53L0X_WrByte(Dev,
			VL53L0X_REG_GLOBAL_CONFIG_REF_EN_START_SELECT,
			startSelect);

	for (index = 0; index < spadArraySize; index++)
		Dev->Data.SpadData.RefSpadEnables[index] = 0;

	if (isApertureSpads) {
		/* Increment to the first APERTURE spad */
		while ((is_aperture(startSelect + currentSpadIndex) == 0) &&
			  (currentSpadIndex < maxSpadCount)) {
			currentSpadIndex++;
		}
	}
	Status = enable_ref_spads(Dev,
				isApertureSpads,
				Dev->Data.SpadData.RefGoodSpadMap,
				Dev->Data.SpadData.RefSpadEnables,
				spadArraySize,
				startSelect,
				currentSpadIndex,
				count,
				&lastSpadIndex);

	if (Status == VL53L0X_ERROR_NONE) {
		VL53L0X_SETDEVICESPECIFICPARAMETER(Dev, RefSpadsInitialised, 1);
		VL53L0X_SETDEVICESPECIFICPARAMETER(Dev,
			ReferenceSpadCount, (uint8_t)(count));
		VL53L0X_SETDEVICESPECIFICPARAMETER(Dev,
			ReferenceSpadType, isApertureSpads);
	}

	return Status;
}

VL53L0X_Error VL53L0X_get_reference_spads(VL53L0X_DEV Dev,
			uint32_t *pSpadCount, uint8_t *pIsApertureSpads)
{
	VL53L0X_Error Status = VL53L0X_ERROR_NONE;
	uint8_t refSpadsInitialised;
	uint8_t refSpadArray[6];
	uint32_t cMaxSpadCount = 44;
	uint32_t cSpadArraySize = 6;
	uint32_t spadsEnabled;
	uint8_t isApertureSpads = 0;

	refSpadsInitialised = VL53L0X_GETDEVICESPECIFICPARAMETER(Dev,
					RefSpadsInitialised);

	if (refSpadsInitialised == 1) {

		*pSpadCount = (uint32_t)VL53L0X_GETDEVICESPECIFICPARAMETER(Dev,
			ReferenceSpadCount);
		*pIsApertureSpads = VL53L0X_GETDEVICESPECIFICPARAMETER(Dev,
			ReferenceSpadType);
	} else {

		/* obtain spad info from device.*/
		Status = get_ref_spad_map(Dev, refSpadArray);

		if (Status == VL53L0X_ERROR_NONE) {
			/* count enabled spads within spad map array and
			 * determine if Aperture or Non-Aperture.
			 */
			Status = count_enabled_spads(refSpadArray,
							cSpadArraySize,
							cMaxSpadCount,
							&spadsEnabled,
							&isApertureSpads);

			if (Status == VL53L0X_ERROR_NONE) {

				*pSpadCount = spadsEnabled;
				*pIsApertureSpads = isApertureSpads;

				VL53L0X_SETDEVICESPECIFICPARAMETER(Dev,
					RefSpadsInitialised, 1);
				VL53L0X_SETDEVICESPECIFICPARAMETER(Dev,
					ReferenceSpadCount,
					(uint8_t)spadsEnabled);
				VL53L0X_SETDEVICESPECIFICPARAMETER(Dev,
					ReferenceSpadType, isApertureSpads);
			}
		}
	}

	return Status;
}


VL53L0X_Error VL53L0X_perform_single_ref_calibration(VL53L0X_DEV Dev,
		uint8_t vhv_init_byte)
{
	VL53L0X_Error Status = VL53L0X_ERROR_NONE;

	if (Status == VL53L0X_ERROR_NONE)
		Status = VL53L0X_WrByte(Dev, VL53L0X_REG_SYSRANGE_START,
				VL53L0X_REG_SYSRANGE_MODE_START_STOP |
				vhv_init_byte);

	if (Status == VL53L0X_ERROR_NONE)
		Status = VL53L0X_measurement_poll_for_completion(Dev);

	if (Status == VL53L0X_ERROR_NONE)
		Status = VL53L0X_ClearInterruptMask(Dev, 0);

	if (Status == VL53L0X_ERROR_NONE)
		Status = VL53L0X_WrByte(Dev, VL53L0X_REG_SYSRANGE_START, 0x00);

	return Status;
}


VL53L0X_Error VL53L0X_ref_calibration_io(VL53L0X_DEV Dev, uint8_t read_not_write,
	uint8_t VhvSettings, uint8_t PhaseCal,
	uint8_t *pVhvSettings, uint8_t *pPhaseCal,
	const uint8_t vhv_enable, const uint8_t phase_enable)
{
	VL53L0X_Error Status = VL53L0X_ERROR_NONE;
	uint8_t PhaseCalint = 0;

	/* Read VHV from device */
	Status |= VL53L0X_WrByte(Dev, 0xFF, 0x01);
	Status |= VL53L0X_WrByte(Dev, 0x00, 0x00);
	Status |= VL53L0X_WrByte(Dev, 0xFF, 0x00);

	if (read_not_write) {
		if (vhv_enable)
			Status |= VL53L0X_RdByte(Dev, 0xCB, pVhvSettings);
		if (phase_enable)
			Status |= VL53L0X_RdByte(Dev, 0xEE, &PhaseCalint);
	} else {
		if (vhv_enable)
			Status |= VL53L0X_WrByte(Dev, 0xCB, VhvSettings);
		if (phase_enable)
			Status |= VL53L0X_UpdateByte(Dev, 0xEE, 0x80, PhaseCal);
	}

	Status |= VL53L0X_WrByte(Dev, 0xFF, 0x01);
	Status |= VL53L0X_WrByte(Dev, 0x00, 0x01);
	Status |= VL53L0X_WrByte(Dev, 0xFF, 0x00);

	*pPhaseCal = (uint8_t)(PhaseCalint&0xEF);

	return Status;
}


VL53L0X_Error VL53L0X_perform_vhv_calibration(VL53L0X_DEV Dev,
	uint8_t *pVhvSettings, const uint8_t get_data_enable,
	const uint8_t restore_config)
{
	VL53L0X_Error Status = VL53L0X_ERROR_NONE;
	uint8_t SequenceConfig = 0;
	uint8_t VhvSettings = 0;
	uint8_t PhaseCal = 0;
	uint8_t PhaseCalInt = 0;

	/* store the value of the sequence config,
	 * this will be reset before the end of the function
	 */

	if (restore_config)
		SequenceConfig = PALDevDataGet(Dev, SequenceConfig);

	/* Run VHV */
	Status = VL53L0X_WrByte(Dev, VL53L0X_REG_SYSTEM_SEQUENCE_CONFIG, 0x01);

	if (Status == VL53L0X_ERROR_NONE)
		Status = VL53L0X_perform_single_ref_calibration(Dev, 0x40);

	/* Read VHV from device */
	if ((Status == VL53L0X_ERROR_NONE) && (get_data_enable == 1)) {
		Status = VL53L0X_ref_calibration_io(Dev, 1,
			VhvSettings, PhaseCal, /* Not used here */
			pVhvSettings, &PhaseCalInt,
			1, 0);
	} else
		*pVhvSettings = 0;


	if ((Status == VL53L0X_ERROR_NONE) && restore_config) {
		/* restore the previous Sequence Config */
		Status = VL53L0X_WrByte(Dev, VL53L0X_REG_SYSTEM_SEQUENCE_CONFIG,
				SequenceConfig);
		if (Status == VL53L0X_ERROR_NONE)
			PALDevDataSet(Dev, SequenceConfig, SequenceConfig);

	}

	return Status;
}

VL53L0X_Error VL53L0X_perform_phase_calibration(VL53L0X_DEV Dev,
	uint8_t *pPhaseCal, const uint8_t get_data_enable,
	const uint8_t restore_config)
{
	VL53L0X_Error Status = VL53L0X_ERROR_NONE;
	uint8_t SequenceConfig = 0;
	uint8_t VhvSettings = 0;
	uint8_t PhaseCal = 0;
	uint8_t VhvSettingsint;

	/* store the value of the sequence config,
	 * this will be reset before the end of the function
	 */

	if (restore_config)
		SequenceConfig = PALDevDataGet(Dev, SequenceConfig);

	/* Run PhaseCal */
	Status = VL53L0X_WrByte(Dev, VL53L0X_REG_SYSTEM_SEQUENCE_CONFIG, 0x02);

	if (Status == VL53L0X_ERROR_NONE)
		Status = VL53L0X_perform_single_ref_calibration(Dev, 0x0);

	/* Read PhaseCal from device */
	if ((Status == VL53L0X_ERROR_NONE) && (get_data_enable == 1)) {
		Status = VL53L0X_ref_calibration_io(Dev, 1,
			VhvSettings, PhaseCal, /* Not used here */
			&VhvSettingsint, pPhaseCal,
			0, 1);
	} else
		*pPhaseCal = 0;


	if ((Status == VL53L0X_ERROR_NONE) && restore_config) {
		/* restore the previous Sequence Config */
		Status = VL53L0X_WrByte(Dev, VL53L0X_REG_SYSTEM_SEQUENCE_CONFIG,
				SequenceConfig);
		if (Status == VL53L0X_ERROR_NONE)
			PALDevDataSet(Dev, SequenceConfig, SequenceConfig);

	}

	return Status;
}

VL53L0X_Error VL53L0X_perform_ref_calibration(VL53L0X_DEV Dev,
	uint8_t *pVhvSettings, uint8_t *pPhaseCal, uint8_t get_data_enable)
{
	VL53L0X_Error Status = VL53L0X_ERROR_NONE;
	uint8_t SequenceConfig = 0;

	/* store the value of the sequence config,
	 * this will be reset before the end of the function
	 */

	SequenceConfig = PALDevDataGet(Dev, SequenceConfig);

	/* In the following function we don't save the config to optimize
	 * writes on device. Config is saved and restored only once. */
	Status = VL53L0X_perform_vhv_calibration(
			Dev, pVhvSettings, get_data_enable, 0);


	if (Status == VL53L0X_ERROR_NONE)
		Status = VL53L0X_perform_phase_calibration(
			Dev, pPhaseCal, get_data_enable, 0);


	if (Status == VL53L0X_ERROR_NONE) {
		/* restore the previous Sequence Config */
		Status = VL53L0X_WrByte(Dev, VL53L0X_REG_SYSTEM_SEQUENCE_CONFIG,
				SequenceConfig);
		if (Status == VL53L0X_ERROR_NONE)
			PALDevDataSet(Dev, SequenceConfig, SequenceConfig);

	}

	return Status;
}

VL53L0X_Error VL53L0X_set_ref_calibration(VL53L0X_DEV Dev,
		uint8_t VhvSettings, uint8_t PhaseCal)
{
	VL53L0X_Error Status = VL53L0X_ERROR_NONE;
	uint8_t pVhvSettings;
	uint8_t pPhaseCal;

	Status = VL53L0X_ref_calibration_io(Dev, 0,
		VhvSettings, PhaseCal,
		&pVhvSettings, &pPhaseCal,
		1, 1);

	return Status;
}

VL53L0X_Error VL53L0X_get_ref_calibration(VL53L0X_DEV Dev,
		uint8_t *pVhvSettings, uint8_t *pPhaseCal)
{
	VL53L0X_Error Status = VL53L0X_ERROR_NONE;
	uint8_t VhvSettings = 0;
	uint8_t PhaseCal = 0;

	Status = VL53L0X_ref_calibration_io(Dev, 1,
		VhvSettings, PhaseCal,
		pVhvSettings, pPhaseCal,
		1, 1);

	return Status;
}