John Alexander
VL53L1X sensor class, for ARM Mbed platform. Based on Ultra-lite, Mass-market C Driver.
Dependencies: X_NUCLEO_COMMON ST_INTERFACES
vl53l1x_class.cpp
- Committer:
- dmathew
- Date:
- 2019-05-17
- Revision:
- 6:aa13392d16bb
- Parent:
- 5:f16727052990
File content as of revision 6:aa13392d16bb:
/**
******************************************************************************
* @file vl53l1x_class.cpp
* @author JS
* @version V0.0.1
* @date 15-January-2019
* @brief Implementation file for the VL53L1 sensor component driver class
******************************************************************************
* @attention
*
* <h2><center>© COPYRIGHT(c) 2018 STMicroelectronics</center></h2>
*
* Redistribution and use in source and binary forms, with or without modification,
* are permitted provided that the following conditions are met:
* 1. Redistributions of source code must retain the above copyright notice,
* this list of conditions and the following disclaimer.
* 2. 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.
* 3. 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 AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS 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.
*
******************************************************************************
*/
/* Includes */
#include <stdlib.h>
#include "vl53l1x_class.h"
#define ALGO__PART_TO_PART_RANGE_OFFSET_MM 0x001E
#define MM_CONFIG__INNER_OFFSET_MM 0x0020
#define MM_CONFIG__OUTER_OFFSET_MM 0x0022
#include "vl53l1x_configuration.h"
VL53L1X_ERROR VL53L1X::VL53L1X_GetSWVersion(VL53L1X_Version_t *pVersion)
{
VL53L1X_ERROR Status = 0;
pVersion->major = VL53L1X_IMPLEMENTATION_VER_MAJOR;
pVersion->minor = VL53L1X_IMPLEMENTATION_VER_MINOR;
pVersion->build = VL53L1X_IMPLEMENTATION_VER_SUB;
pVersion->revision = VL53L1X_IMPLEMENTATION_VER_REVISION;
return Status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_SetI2CAddress(uint8_t new_address)
{
VL53L1X_ERROR status = 0;
status = VL53L1_WrByte(Device, VL53L1_I2C_SLAVE__DEVICE_ADDRESS, new_address >> 1);
Device->I2cDevAddr = new_address;
return status;
}
int VL53L1X::init_sensor(uint8_t new_addr)
{
Device->I2cDevAddr = new_addr;
int status = 0;
VL53L1_Off();
VL53L1_On();
status = is_present();
if (!status) {
printf("Failed to init VL53L0X sensor!\n\r");
return status;
}
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_SensorInit()
{
VL53L1X_ERROR status = 0;
uint8_t Addr = 0x00;
for (Addr = 0x2D; Addr <= 0x87; Addr++){
status = VL53L1_WrByte(Device, Addr, VL51L1X_DEFAULT_CONFIGURATION[Addr - 0x2D]);
if (status != 0)
{
printf("Writing config failed - %d\r\n", status);
}
}
uint16_t sensorID= 0;
status = VL53L1X_GetSensorId(&sensorID);
printf("Sensor id is - %d (%X)\r\n", sensorID, sensorID);
status = VL53L1X_StartRanging();
if (status != 0)
{
printf("start ranging failed - %d\r\n", status);
}
status = VL53L1X_ClearInterrupt();
status = VL53L1X_StopRanging();
status = VL53L1_WrByte(Device, VL53L1_VHV_CONFIG__TIMEOUT_MACROP_LOOP_BOUND, 0x09); /* two bounds VHV */
status = VL53L1_WrByte(Device, 0x0B, 0); /* start VHV from the previous temperature */
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_ClearInterrupt()
{
VL53L1X_ERROR status = 0;
status = VL53L1_WrByte(Device, SYSTEM__INTERRUPT_CLEAR, 0x01);
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_SetInterruptPolarity(uint8_t NewPolarity)
{
uint8_t Temp;
VL53L1X_ERROR status = 0;
status = VL53L1_RdByte(Device, GPIO_HV_MUX__CTRL, &Temp);
Temp = Temp & 0xEF;
status = VL53L1_WrByte(Device, GPIO_HV_MUX__CTRL, Temp | (!(NewPolarity & 1)) << 4);
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_GetInterruptPolarity(uint8_t *pInterruptPolarity)
{
uint8_t Temp;
VL53L1X_ERROR status = 0;
status = VL53L1_RdByte(Device, GPIO_HV_MUX__CTRL, &Temp);
Temp = Temp & 0x10;
*pInterruptPolarity = !(Temp>>4);
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_StartRanging()
{
VL53L1X_ERROR status = 0;
status = VL53L1_WrByte(Device, SYSTEM__MODE_START, 0x40); /* Enable VL53L1X */
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_StopRanging()
{
VL53L1X_ERROR status = 0;
status = VL53L1_WrByte(Device, SYSTEM__MODE_START, 0x00); /* Disable VL53L1X */
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_CheckForDataReady(uint8_t *isDataReady)
{
uint8_t Temp;
uint8_t IntPol;
VL53L1X_ERROR status = 0;
status = VL53L1X_GetInterruptPolarity(&IntPol);
status = VL53L1_RdByte(Device, GPIO__TIO_HV_STATUS, &Temp);
/* Read in the register to check if a new value is available */
if (status == 0){
if ((Temp & 1) == IntPol)
*isDataReady = 1;
else
*isDataReady = 0;
}
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_SetTimingBudgetInMs(uint16_t TimingBudgetInMs)
{
uint16_t DM;
VL53L1X_ERROR status=0;
status = VL53L1X_GetDistanceMode(&DM);
if (DM == 0)
return 1;
else if (DM == 1) { /* Short DistanceMode */
switch (TimingBudgetInMs) {
case 15: /* only available in short distance mode */
VL53L1_WrWord(Device, RANGE_CONFIG__TIMEOUT_MACROP_A_HI,
0x01D);
VL53L1_WrWord(Device, RANGE_CONFIG__TIMEOUT_MACROP_B_HI,
0x0027);
break;
case 20:
VL53L1_WrWord(Device, RANGE_CONFIG__TIMEOUT_MACROP_A_HI,
0x0051);
VL53L1_WrWord(Device, RANGE_CONFIG__TIMEOUT_MACROP_B_HI,
0x006E);
break;
case 33:
VL53L1_WrWord(Device, RANGE_CONFIG__TIMEOUT_MACROP_A_HI,
0x00D6);
VL53L1_WrWord(Device, RANGE_CONFIG__TIMEOUT_MACROP_B_HI,
0x006E);
break;
case 50:
VL53L1_WrWord(Device, RANGE_CONFIG__TIMEOUT_MACROP_A_HI,
0x1AE);
VL53L1_WrWord(Device, RANGE_CONFIG__TIMEOUT_MACROP_B_HI,
0x01E8);
break;
case 100:
VL53L1_WrWord(Device, RANGE_CONFIG__TIMEOUT_MACROP_A_HI,
0x02E1);
VL53L1_WrWord(Device, RANGE_CONFIG__TIMEOUT_MACROP_B_HI,
0x0388);
break;
case 200:
VL53L1_WrWord(Device, RANGE_CONFIG__TIMEOUT_MACROP_A_HI,
0x03E1);
VL53L1_WrWord(Device, RANGE_CONFIG__TIMEOUT_MACROP_B_HI,
0x0496);
break;
case 500:
VL53L1_WrWord(Device, RANGE_CONFIG__TIMEOUT_MACROP_A_HI,
0x0591);
VL53L1_WrWord(Device, RANGE_CONFIG__TIMEOUT_MACROP_B_HI,
0x05C1);
break;
default:
status = 1;
break;
}
} else {
switch (TimingBudgetInMs) {
case 20:
VL53L1_WrWord(Device, RANGE_CONFIG__TIMEOUT_MACROP_A_HI,
0x001E);
VL53L1_WrWord(Device, RANGE_CONFIG__TIMEOUT_MACROP_B_HI,
0x0022);
break;
case 33:
VL53L1_WrWord(Device, RANGE_CONFIG__TIMEOUT_MACROP_A_HI,
0x0060);
VL53L1_WrWord(Device, RANGE_CONFIG__TIMEOUT_MACROP_B_HI,
0x006E);
break;
case 50:
VL53L1_WrWord(Device, RANGE_CONFIG__TIMEOUT_MACROP_A_HI,
0x00AD);
VL53L1_WrWord(Device, RANGE_CONFIG__TIMEOUT_MACROP_B_HI,
0x00C6);
break;
case 100:
VL53L1_WrWord(Device, RANGE_CONFIG__TIMEOUT_MACROP_A_HI,
0x01CC);
VL53L1_WrWord(Device, RANGE_CONFIG__TIMEOUT_MACROP_B_HI,
0x01EA);
break;
case 200:
VL53L1_WrWord(Device, RANGE_CONFIG__TIMEOUT_MACROP_A_HI,
0x02D9);
VL53L1_WrWord(Device, RANGE_CONFIG__TIMEOUT_MACROP_B_HI,
0x02F8);
break;
case 500:
VL53L1_WrWord(Device, RANGE_CONFIG__TIMEOUT_MACROP_A_HI,
0x048F);
VL53L1_WrWord(Device, RANGE_CONFIG__TIMEOUT_MACROP_B_HI,
0x04A4);
break;
default:
status = 1;
break;
}
}
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_GetTimingBudgetInMs(uint16_t *pTimingBudget)
{
uint16_t Temp;
VL53L1X_ERROR status = 0;
status = VL53L1_RdWord(Device, RANGE_CONFIG__TIMEOUT_MACROP_A_HI, &Temp);
switch (Temp) {
case 0x001D :
*pTimingBudget = 15;
break;
case 0x0051 :
case 0x001E :
*pTimingBudget = 20;
break;
case 0x00D6 :
case 0x0060 :
*pTimingBudget = 33;
break;
case 0x1AE :
case 0x00AD :
*pTimingBudget = 50;
break;
case 0x02E1 :
case 0x01CC :
*pTimingBudget = 100;
break;
case 0x03E1 :
case 0x02D9 :
*pTimingBudget = 200;
break;
case 0x0591 :
case 0x048F :
*pTimingBudget = 500;
break;
default:
*pTimingBudget = 0;
break;
}
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_SetDistanceMode(uint16_t DM)
{
uint16_t TB;
VL53L1X_ERROR status = 0;
status = VL53L1X_GetTimingBudgetInMs(&TB);
switch (DM) {
case 1:
status = VL53L1_WrByte(Device, PHASECAL_CONFIG__TIMEOUT_MACROP, 0x14);
status = VL53L1_WrByte(Device, RANGE_CONFIG__VCSEL_PERIOD_A, 0x07);
status = VL53L1_WrByte(Device, RANGE_CONFIG__VCSEL_PERIOD_B, 0x05);
status = VL53L1_WrByte(Device, RANGE_CONFIG__VALID_PHASE_HIGH, 0x38);
status = VL53L1_WrWord(Device, SD_CONFIG__WOI_SD0, 0x0705);
status = VL53L1_WrWord(Device, SD_CONFIG__INITIAL_PHASE_SD0, 0x0606);
break;
case 2:
status = VL53L1_WrByte(Device, PHASECAL_CONFIG__TIMEOUT_MACROP, 0x0A);
status = VL53L1_WrByte(Device, RANGE_CONFIG__VCSEL_PERIOD_A, 0x0F);
status = VL53L1_WrByte(Device, RANGE_CONFIG__VCSEL_PERIOD_B, 0x0D);
status = VL53L1_WrByte(Device, RANGE_CONFIG__VALID_PHASE_HIGH, 0xB8);
status = VL53L1_WrWord(Device, SD_CONFIG__WOI_SD0, 0x0F0D);
status = VL53L1_WrWord(Device, SD_CONFIG__INITIAL_PHASE_SD0, 0x0E0E);
break;
default:
break;
}
status = VL53L1X_SetTimingBudgetInMs(TB);
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_GetDistanceMode(uint16_t *DM)
{
uint8_t TempDM, status=0;
status = VL53L1_RdByte(Device,PHASECAL_CONFIG__TIMEOUT_MACROP, &TempDM);
if (TempDM == 0x14)
*DM=1;
if(TempDM == 0x0A)
*DM=2;
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_SetInterMeasurementInMs(uint16_t InterMeasMs)
{
uint16_t ClockPLL;
VL53L1X_ERROR status = 0;
status = VL53L1_RdWord(Device, VL53L1_RESULT__OSC_CALIBRATE_VAL, &ClockPLL);
ClockPLL = ClockPLL&0x3FF;
VL53L1_WrDWord(Device, VL53L1_SYSTEM__INTERMEASUREMENT_PERIOD,
(uint32_t)(ClockPLL * InterMeasMs * 1.075));
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_GetInterMeasurementInMs(uint16_t *pIM)
{
uint16_t ClockPLL;
VL53L1X_ERROR status = 0;
uint32_t tmp;
status = VL53L1_RdDWord(Device,VL53L1_SYSTEM__INTERMEASUREMENT_PERIOD, &tmp);
*pIM = (uint16_t)tmp;
status = VL53L1_RdWord(Device, VL53L1_RESULT__OSC_CALIBRATE_VAL, &ClockPLL);
ClockPLL = ClockPLL&0x3FF;
*pIM= (uint16_t)(*pIM/(ClockPLL*1.065));
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_BootState(uint8_t *state)
{
VL53L1X_ERROR status = 0;
uint8_t tmp = 0;
status = VL53L1_RdByte(Device,VL53L1_FIRMWARE__SYSTEM_STATUS, &tmp);
*state = tmp;
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_GetSensorId(uint16_t *sensorId)
{
VL53L1X_ERROR status = 0;
uint16_t tmp = 0;
status = VL53L1_RdWord(Device, VL53L1_IDENTIFICATION__MODEL_ID, &tmp);
*sensorId = tmp;
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_GetDistance(uint16_t *distance)
{
VL53L1X_ERROR status = 0;
uint16_t tmp;
status = (VL53L1_RdWord(Device,
VL53L1_RESULT__FINAL_CROSSTALK_CORRECTED_RANGE_MM_SD0, &tmp));
*distance = tmp;
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_GetSignalPerSpad(uint16_t *signalRate)
{
VL53L1X_ERROR status = 0;
uint16_t SpNb=1, signal;
status = VL53L1_RdWord(Device,
VL53L1_RESULT__PEAK_SIGNAL_COUNT_RATE_CROSSTALK_CORRECTED_MCPS_SD0, &signal);
status = VL53L1_RdWord(Device,
VL53L1_RESULT__DSS_ACTUAL_EFFECTIVE_SPADS_SD0, &SpNb);
*signalRate = (uint16_t) (2000.0*signal/SpNb);
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_GetAmbientPerSpad(uint16_t *ambPerSp)
{
VL53L1X_ERROR status=0;
uint16_t AmbientRate, SpNb=1;
status = VL53L1_RdWord(Device, RESULT__AMBIENT_COUNT_RATE_MCPS_SD, &AmbientRate);
status = VL53L1_RdWord(Device, VL53L1_RESULT__DSS_ACTUAL_EFFECTIVE_SPADS_SD0, &SpNb);
*ambPerSp=(uint16_t) (2000.0 * AmbientRate / SpNb);
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_GetSignalRate(uint16_t *signal)
{
VL53L1X_ERROR status = 0;
uint16_t tmp;
status = VL53L1_RdWord(Device,
VL53L1_RESULT__PEAK_SIGNAL_COUNT_RATE_CROSSTALK_CORRECTED_MCPS_SD0, &tmp);
*signal = tmp*8;
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_GetSpadNb(uint16_t *spNb)
{
VL53L1X_ERROR status = 0;
uint16_t tmp;
status = VL53L1_RdWord(Device,
VL53L1_RESULT__DSS_ACTUAL_EFFECTIVE_SPADS_SD0, &tmp);
*spNb = tmp >> 8;
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_GetAmbientRate(uint16_t *ambRate)
{
VL53L1X_ERROR status = 0;
uint16_t tmp;
status = VL53L1_RdWord(Device, RESULT__AMBIENT_COUNT_RATE_MCPS_SD, &tmp);
*ambRate = tmp*8;
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_GetRangeStatus(uint8_t *rangeStatus)
{
VL53L1X_ERROR status = 0;
uint8_t RgSt;
status = VL53L1_RdByte(Device, VL53L1_RESULT__RANGE_STATUS, &RgSt);
RgSt = RgSt&0x1F;
switch (RgSt) {
case 9:
RgSt = 0;
break;
case 6:
RgSt = 1;
break;
case 4:
RgSt = 2;
break;
case 8:
RgSt = 3;
break;
case 5:
RgSt = 4;
break;
case 3:
RgSt = 5;
break;
case 19:
RgSt = 6;
break;
case 7:
RgSt = 7;
break;
case 12:
RgSt = 9;
break;
case 18:
RgSt = 10;
break;
case 22:
RgSt = 11;
break;
case 23:
RgSt = 12;
break;
case 13:
RgSt = 13;
break;
default:
RgSt = 255;
break;
}
*rangeStatus = RgSt;
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_SetOffset(int16_t OffsetValue)
{
VL53L1X_ERROR status = 0;
int16_t Temp;
Temp = (OffsetValue*4);
VL53L1_WrWord(Device, ALGO__PART_TO_PART_RANGE_OFFSET_MM,
(uint16_t)Temp);
VL53L1_WrWord(Device, MM_CONFIG__INNER_OFFSET_MM, 0x0);
VL53L1_WrWord(Device, MM_CONFIG__OUTER_OFFSET_MM, 0x0);
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_GetOffset(int16_t *offset)
{
VL53L1X_ERROR status = 0;
uint16_t Temp;
status = VL53L1_RdWord(Device,ALGO__PART_TO_PART_RANGE_OFFSET_MM, &Temp);
Temp = Temp<<3;
Temp = Temp >>5;
*offset = (int16_t)(Temp);
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_SetXtalk(uint16_t XtalkValue)
{
/* XTalkValue in count per second to avoid float type */
VL53L1X_ERROR status = 0;
status = VL53L1_WrWord(Device,
ALGO__CROSSTALK_COMPENSATION_X_PLANE_GRADIENT_KCPS,
0x0000);
status = VL53L1_WrWord(Device, ALGO__CROSSTALK_COMPENSATION_Y_PLANE_GRADIENT_KCPS,
0x0000);
status = VL53L1_WrWord(Device, ALGO__CROSSTALK_COMPENSATION_PLANE_OFFSET_KCPS,
(XtalkValue<<9)/1000); /* * << 9 (7.9 format) and /1000 to convert cps to kpcs */
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_GetXtalk(uint16_t *xtalk )
{
VL53L1X_ERROR status = 0;
uint16_t tmp;
status = VL53L1_RdWord(Device,ALGO__CROSSTALK_COMPENSATION_PLANE_OFFSET_KCPS, &tmp);
*xtalk = (tmp*1000)>>9; /* * 1000 to convert kcps to cps and >> 9 (7.9 format) */
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_SetDistanceThreshold(uint16_t ThreshLow,
uint16_t ThreshHigh, uint8_t Window,
uint8_t IntOnNoTarget)
{
VL53L1X_ERROR status = 0;
uint8_t Temp = 0;
status = VL53L1_RdByte(Device, SYSTEM__INTERRUPT_CONFIG_GPIO, &Temp);
Temp = Temp & 0x47;
if (IntOnNoTarget == 0) {
status = VL53L1_WrByte(Device, SYSTEM__INTERRUPT_CONFIG_GPIO,
(Temp | (Window & 0x07)));
} else {
status = VL53L1_WrByte(Device, SYSTEM__INTERRUPT_CONFIG_GPIO,
((Temp | (Window & 0x07)) | 0x40));
}
status = VL53L1_WrWord(Device, SYSTEM__THRESH_HIGH, ThreshHigh);
status = VL53L1_WrWord(Device, SYSTEM__THRESH_LOW, ThreshLow);
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_GetDistanceThresholdWindow(uint16_t *window)
{
VL53L1X_ERROR status = 0;
uint8_t tmp;
status = VL53L1_RdByte(Device,SYSTEM__INTERRUPT_CONFIG_GPIO, &tmp);
*window = (uint16_t)(tmp & 0x7);
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_GetDistanceThresholdLow(uint16_t *low)
{
VL53L1X_ERROR status = 0;
uint16_t tmp;
status = VL53L1_RdWord(Device,SYSTEM__THRESH_LOW, &tmp);
*low = tmp;
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_GetDistanceThresholdHigh(uint16_t *high)
{
VL53L1X_ERROR status = 0;
uint16_t tmp;
status = VL53L1_RdWord(Device,SYSTEM__THRESH_HIGH, &tmp);
*high = tmp;
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_SetROI(uint16_t X, uint16_t Y)
{
uint8_t OpticalCenter;
VL53L1X_ERROR status = 0;
status =VL53L1_RdByte(Device, VL53L1_ROI_CONFIG__MODE_ROI_CENTRE_SPAD, &OpticalCenter);
if (X > 16)
X = 16;
if (Y > 16)
Y = 16;
if (X > 10 || Y > 10){
OpticalCenter = 199;
}
status = VL53L1_WrByte(Device, ROI_CONFIG__USER_ROI_CENTRE_SPAD, OpticalCenter);
status = VL53L1_WrByte(Device, ROI_CONFIG__USER_ROI_REQUESTED_GLOBAL_XY_SIZE,
(Y - 1) << 4 | (X - 1));
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_GetROI_XY(uint16_t *ROI_X, uint16_t *ROI_Y)
{
VL53L1X_ERROR status = 0;
uint8_t tmp;
status = VL53L1_RdByte(Device,ROI_CONFIG__USER_ROI_REQUESTED_GLOBAL_XY_SIZE, &tmp);
*ROI_X = ((uint16_t)tmp & 0x0F) + 1;
*ROI_Y = (((uint16_t)tmp & 0xF0) >> 4) + 1;
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_SetSignalThreshold(uint16_t Signal)
{
VL53L1X_ERROR status = 0;
VL53L1_WrWord(Device,RANGE_CONFIG__MIN_COUNT_RATE_RTN_LIMIT_MCPS,Signal>>3);
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_GetSignalThreshold(uint16_t *signal)
{
VL53L1X_ERROR status = 0;
uint16_t tmp;
status = VL53L1_RdWord(Device,
RANGE_CONFIG__MIN_COUNT_RATE_RTN_LIMIT_MCPS, &tmp);
*signal = tmp <<3;
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_SetSigmaThreshold(uint16_t Sigma)
{
VL53L1X_ERROR status = 0;
if(Sigma>(0xFFFF>>2)){
return 1;
}
/* 16 bits register 14.2 format */
status = VL53L1_WrWord(Device,RANGE_CONFIG__SIGMA_THRESH,Sigma<<2);
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_GetSigmaThreshold(uint16_t *sigma)
{
VL53L1X_ERROR status = 0;
uint16_t tmp;
status = VL53L1_RdWord(Device,RANGE_CONFIG__SIGMA_THRESH, &tmp);
*sigma = tmp >> 2;
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1X_StartTemperatureUpdate()
{
VL53L1X_ERROR status = 0;
uint8_t tmp=0;
status = VL53L1_WrByte(Device,VL53L1_VHV_CONFIG__TIMEOUT_MACROP_LOOP_BOUND,0x81); /* full VHV */
status = VL53L1_WrByte(Device,0x0B,0x92);
status = VL53L1X_StartRanging();
while(tmp==0){
status = VL53L1X_CheckForDataReady(&tmp);
}
tmp = 0;
status = VL53L1X_ClearInterrupt();
status = VL53L1X_StopRanging();
status = VL53L1_WrByte(Device, VL53L1_VHV_CONFIG__TIMEOUT_MACROP_LOOP_BOUND, 0x09); /* two bounds VHV */
status = VL53L1_WrByte(Device, 0x0B, 0); /* start VHV from the previous temperature */
return status;
}
/* VL53L1X_calibration.h functions */
int8_t VL53L1X::VL53L1X_CalibrateOffset(uint16_t TargetDistInMm, int16_t *offset)
{
uint8_t i = 0, tmp;
int16_t AverageDistance = 0;
uint16_t distance;
VL53L1X_ERROR status = 0;
status = VL53L1_WrWord(Device, ALGO__PART_TO_PART_RANGE_OFFSET_MM, 0x0);
status = VL53L1_WrWord(Device, MM_CONFIG__INNER_OFFSET_MM, 0x0);
status = VL53L1_WrWord(Device, MM_CONFIG__OUTER_OFFSET_MM, 0x0);
status = VL53L1X_StartRanging(); /* Enable VL53L1X sensor */
for (i = 0; i < 50; i++) {
while (tmp == 0){
status = VL53L1X_CheckForDataReady(&tmp);
}
tmp = 0;
status = VL53L1X_GetDistance(&distance);
status = VL53L1X_ClearInterrupt();
AverageDistance = AverageDistance + distance;
}
status = VL53L1X_StopRanging();
AverageDistance = AverageDistance / 50;
*offset = TargetDistInMm - AverageDistance;
status = VL53L1_WrWord(Device, ALGO__PART_TO_PART_RANGE_OFFSET_MM, *offset*4);
return status;
}
int8_t VL53L1X::VL53L1X_CalibrateXtalk(uint16_t TargetDistInMm, uint16_t *xtalk)
{
uint8_t i, tmp= 0;
float AverageSignalRate = 0;
float AverageDistance = 0;
float AverageSpadNb = 0;
uint16_t distance = 0, spadNum;
uint16_t sr;
VL53L1X_ERROR status = 0;
status = VL53L1_WrWord(Device, 0x0016,0);
status = VL53L1X_StartRanging();
for (i = 0; i < 50; i++) {
while (tmp == 0){
status = VL53L1X_CheckForDataReady(&tmp);
}
tmp=0;
status= VL53L1X_GetSignalRate(&sr);
status= VL53L1X_GetDistance(&distance);
status = VL53L1X_ClearInterrupt();
AverageDistance = AverageDistance + distance;
status = VL53L1X_GetSpadNb(&spadNum);
AverageSpadNb = AverageSpadNb + spadNum;
AverageSignalRate =
AverageSignalRate + sr;
}
status = VL53L1X_StopRanging();
AverageDistance = AverageDistance / 50;
AverageSpadNb = AverageSpadNb / 50;
AverageSignalRate = AverageSignalRate / 50;
/* Calculate Xtalk value */
*xtalk = (uint16_t)(512*(AverageSignalRate*(1-(AverageDistance/TargetDistInMm)))/AverageSpadNb);
status = VL53L1_WrWord(Device, 0x0016, *xtalk);
return status;
}
/* Write and read functions from I2C */
VL53L1X_ERROR VL53L1X::VL53L1_WriteMulti(VL53L1_DEV Dev, uint16_t index, uint8_t *pdata, uint32_t count)
{
int status;
status = VL53L1_I2CWrite(Dev->I2cDevAddr, index, pdata, (uint16_t)count);
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1_ReadMulti(VL53L1_DEV Dev, uint16_t index, uint8_t *pdata, uint32_t count)
{
int status;
status = VL53L1_I2CRead(Dev->I2cDevAddr, index, pdata, (uint16_t)count);
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1_WrByte(VL53L1_DEV Dev, uint16_t index, uint8_t data)
{
int status;
status=VL53L1_I2CWrite(Dev->I2cDevAddr, index, &data, 1);
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1_WrWord(VL53L1_DEV Dev, uint16_t index, uint16_t data)
{
int status;
uint8_t buffer[2];
buffer[0] = data >> 8;
buffer[1] = data & 0x00FF;
status=VL53L1_I2CWrite(Dev->I2cDevAddr, index, (uint8_t *)buffer, 2);
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1_WrDWord(VL53L1_DEV Dev, uint16_t index, uint32_t data)
{
int status;
uint8_t buffer[4];
buffer[0] = (data >> 24) & 0xFF;
buffer[1] = (data >> 16) & 0xFF;
buffer[2] = (data >> 8) & 0xFF;
buffer[3] = (data >> 0) & 0xFF;
status=VL53L1_I2CWrite(Dev->I2cDevAddr, index, (uint8_t *)buffer, 4);
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1_RdByte(VL53L1_DEV Dev, uint16_t index, uint8_t *data)
{
int status;
status = VL53L1_I2CRead(Dev->I2cDevAddr, index, data, 1);
if(status)
return -1;
return 0;
}
VL53L1X_ERROR VL53L1X::VL53L1_RdWord(VL53L1_DEV Dev, uint16_t index, uint16_t *data)
{
int status;
uint8_t buffer[2] = {0,0};
status = VL53L1_I2CRead(Dev->I2cDevAddr, index, buffer, 2);
if (!status)
{
*data = (buffer[0] << 8) + buffer[1];
}
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1_RdDWord(VL53L1_DEV Dev, uint16_t index, uint32_t *data)
{
int status;
uint8_t buffer[4] = {0,0,0,0};
status = VL53L1_I2CRead(Dev->I2cDevAddr, index, buffer, 4);
if(!status)
{
*data = (buffer[0] << 24) + (buffer[1] << 16) + (buffer[2] << 8) + buffer[3];
}
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1_UpdateByte(VL53L1_DEV Dev, uint16_t index, uint8_t AndData, uint8_t OrData)
{
int status;
uint8_t buffer = 0;
/* read data direct onto buffer */
status = VL53L1_I2CRead(Dev->I2cDevAddr, index, &buffer,1);
if (!status)
{
buffer = (buffer & AndData) | OrData;
status = VL53L1_I2CWrite(Dev->I2cDevAddr, index, &buffer, (uint16_t)1);
}
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1_I2CWrite(uint8_t DeviceAddr, uint16_t RegisterAddr, uint8_t* pBuffer, uint16_t NumByteToWrite)
{
int ret;
ret = dev_i2c->v53l1x_i2c_write(pBuffer, DeviceAddr, RegisterAddr, NumByteToWrite);
if (ret) {
return -1;
}
return 0;
}
VL53L1X_ERROR VL53L1X::VL53L1_I2CRead(uint8_t DeviceAddr, uint16_t RegisterAddr, uint8_t* pBuffer, uint16_t NumByteToRead)
{
int ret;
ret = dev_i2c->v53l1x_i2c_read(pBuffer, DeviceAddr, RegisterAddr, NumByteToRead);
if (ret) {
return -1;
}
return 0;
}
VL53L1X_ERROR VL53L1X::VL53L1_GetTickCount(
uint32_t *ptick_count_ms)
{
/* Returns current tick count in [ms] */
VL53L1X_ERROR status = VL53L1_ERROR_NONE;
*ptick_count_ms = 0;
return status;
}
VL53L1X_ERROR VL53L1X::VL53L1_WaitUs(VL53L1_Dev_t *pdev, int32_t wait_us)
{
return VL53L1_ERROR_NONE;
}
VL53L1X_ERROR VL53L1X::VL53L1_WaitMs(VL53L1_Dev_t *pdev, int32_t wait_ms)
{
return VL53L1_ERROR_NONE;
}
VL53L1X_ERROR VL53L1X::VL53L1_WaitValueMaskEx(
VL53L1_Dev_t *pdev,
uint32_t timeout_ms,
uint16_t index,
uint8_t value,
uint8_t mask,
uint32_t poll_delay_ms)
{
/*
* Platform implementation of WaitValueMaskEx V2WReg script command
*
* WaitValueMaskEx(
* duration_ms,
* index,
* value,
* mask,
* poll_delay_ms);
*/
VL53L1_Error status = VL53L1_ERROR_NONE;
uint32_t start_time_ms = 0;
uint32_t current_time_ms = 0;
uint32_t polling_time_ms = 0;
uint8_t byte_value = 0;
uint8_t found = 0;
/* calculate time limit in absolute time */
VL53L1_GetTickCount(&start_time_ms);
/* remember current trace functions and temporarily disable
* function logging
*/
/* wait until value is found, timeout reached on error occurred */
while ((status == VL53L1_ERROR_NONE) &&
(polling_time_ms < timeout_ms) &&
(found == 0)) {
if (status == VL53L1_ERROR_NONE)
status = VL53L1_RdByte(
pdev,
index,
&byte_value);
if ((byte_value & mask) == value)
found = 1;
if (status == VL53L1_ERROR_NONE &&
found == 0 &&
poll_delay_ms > 0)
status = VL53L1_WaitMs(
pdev,
poll_delay_ms);
/* Update polling time (Compare difference rather than absolute to
negate 32bit wrap around issue) */
VL53L1_GetTickCount(¤t_time_ms);
polling_time_ms = current_time_ms - start_time_ms;
}
if (found == 0 && status == VL53L1_ERROR_NONE)
status = VL53L1_ERROR_TIME_OUT;
return status;
}
int VL53L1X::handle_irq(uint16_t *distance)
{
int status;
status = get_measurement(distance);
enable_interrupt_measure_detection_irq();
return status;
}
int VL53L1X::get_measurement(uint16_t *distance)
{
int status = 0;
status = VL53L1X_GetDistance(distance);
status = VL53L1X_ClearInterrupt();
return status;
}
int VL53L1X::start_measurement(void (*fptr)(void))
{
int status = 0;
if (_gpio1Int == NULL) {
printf("GPIO1 Error\r\n");
return 1;
}
status = VL53L1X_StopRanging(); // it is safer to do this while sensor is stopped
if (status == 0) {
attach_interrupt_measure_detection_irq(fptr);
enable_interrupt_measure_detection_irq();
}
if (status == 0) {
status = VL53L1X_StartRanging();
}
return status;
}
int VL53L1X::stop_measurement()
{
int status = 0;
if (status == 0) {
printf("Call of VL53L0X_StopMeasurement\n");
status = VL53L1X_StopRanging();
}
if (status == 0)
status = VL53L1X_ClearInterrupt();
return status;
}