ST Expansion SW Team
/
VL53L1CB_3sensors_poll_auton_JA
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Dependencies: X_NUCLEO_53L1A2
main.cpp
- Committer:
- johnAlexander
- Date:
- 2021-06-18
- Revision:
- 12:140677759b2c
- Parent:
- 10:2da1507fa8c2
File content as of revision 12:140677759b2c:
/*
* This VL53L1CB Expansion board test application performs range measurements
* using the onboard embedded sensor, in polling mode.
* Measured ranges are ouput on the Serial Port, running at 115200 baud.
*
* This is designed to work with MBed v2.x, & MBedOS v5.x / v6.x.
*
* The Reset button can be used to restart the program.
*
* *** NOTE :
* Default Mbed build system settings disable printf() floating-point support.
* Offline builds can enable this, again.
* https://github.com/ARMmbed/mbed-os/blob/master/platform/source/minimal-printf/README.md
* .\mbed-os\platform\mbed_lib.json
*
* *** NOTE : By default hardlinks U10, U11, U15 & U18, on the underside of
* the X-NUCELO-53L1A1 expansion board are not made/OFF.
* These links must be made to allow interrupts from the Satellite boards
* to be received.
* U11 and U18 must be made/ON to allow interrupts to be received from the
* INT_L & INT_R positions; or
* U10 and U15 must be made/ON to allow interrupts to be received from the
* Alternate INT_L & INT_R positions.
* The X_NUCLEO_53L1A2 library defaults to use the INT_L/INT_R positions.
* INT_L is available on expansion board Arduino Connector CN5, pin 1 as D8.
* Alternate INT_L is on CN5 Connector pin 2 as D9.
* INT_R is available on expansion board Arduino Connector CN9, pin 3 as D2.
* Alternate INT_R is on CN9 Connector pin 5 as D4.
* The pinouts are shown here : https://developer.mbed.org/components/X-NUCLEO-53L1A2/
*
*/
#include <stdio.h>
#include <time.h>
#include "mbed.h"
#include "XNucleo53L1A2.h"
#include "ToF_I2C.h"
// i2c comms port pins
#define I2C_SDA D14
#define I2C_SCL D15
#define NUM_SENSORS 3
// define interrupt pins
PinName CentreIntPin = A2;
// the satellite pins depend on solder blobs on the back of the shield.
// they may not exist or may be one of two sets.
// the centre pin always exists
//PinName LeftIntPin = D8;
PinName RightIntPin = D2;
// alternate set
PinName LeftIntPin = D9;
//PinName RightIntPin = D4;
static XNucleo53L1A2 *board=NULL;
#if (MBED_VERSION > 60300)
UnbufferedSerial pc(USBTX, USBRX);
extern "C" void wait_ms(int ms);
#else
Serial pc(SERIAL_TX, SERIAL_RX);
#endif
void print_results(int devNumber, VL53L1_MultiRangingData_t *pMultiRangingData );
VL53L1_Dev_t devCentre;
VL53L1_DEV DevC = &devCentre;
VL53L1_Dev_t devLeft;
VL53L1_DEV DevL = &devLeft;
VL53L1_Dev_t devRight;
VL53L1_DEV DevR = &devRight;
VL53L1 *Sensor;
/* flags that handle interrupt request for sensor and user blue button*/
volatile bool int_sensor = false;
volatile bool int_stop = false;
/* ISR callback function of the centre sensor */
void sensor_irq(void)
{
int_sensor = true;
board->sensor_centre->disable_interrupt_measure_detection_irq();
}
/* Start the sensor ranging */
int init_sensor()
{
int status = 0;
DevC=&devCentre;
DevC->comms_speed_khz = 400;
DevC->comms_type = 1;
DevC->i2c_slave_address = NEW_SENSOR_CENTRE_ADDRESS;
devCentre.i2c_slave_address = NEW_SENSOR_CENTRE_ADDRESS;
// Sensor=board->sensor_centre;
DevL=&devLeft;
// Sensor=board->sensor_left;
// configure the sensors
DevL->comms_speed_khz = 400;
DevL->comms_type = 1;
DevL->i2c_slave_address = NEW_SENSOR_LEFT_ADDRESS;
devLeft.i2c_slave_address = NEW_SENSOR_LEFT_ADDRESS;
DevR=&devLeft;
// configure the sensors
DevR->comms_speed_khz = 400;
DevR->comms_type = 1;
DevR->i2c_slave_address = NEW_SENSOR_RIGHT_ADDRESS;
devRight.i2c_slave_address = NEW_SENSOR_RIGHT_ADDRESS;
for (int i = 0; i < 3; i++)
{
if (i == 0) { Sensor=board->sensor_centre; }
if (i == 1) { Sensor=board->sensor_left; }
if (i == 2) { Sensor=board->sensor_right; }
if (Sensor != NULL)
{
if (i == 0) { printf("configuring centre channel \n"); }
if (i == 1) { printf("configuring left channel \n"); }
if (i == 2) { printf("configuring right channel \n"); }
/* Device Initialization and setting */
status = Sensor->vl53L1_DataInit();
status = Sensor->vl53L1_StaticInit();
status = Sensor->vl53L1_SetPresetMode(VL53L1_PRESETMODE_AUTONOMOUS);
status = Sensor->vl53L1_SetDistanceMode(VL53L1_DISTANCEMODE_LONG);
status = Sensor->vl53L1_SetInterMeasurementPeriodMilliSeconds(500);
status = Sensor->vl53L1_SetMeasurementTimingBudgetMicroSeconds(45000);
status = Sensor->vl53L1_SetSequenceStepEnable(VL53L1_SEQUENCESTEP_MM1, 0);
status = Sensor->vl53L1_SetSequenceStepEnable(VL53L1_SEQUENCESTEP_MM2, 0);
}
}
// create interrupt handler and start measurements
if (board->sensor_centre!= NULL) {
status = board->sensor_centre->stop_measurement();
if (status != 0) {
return status;
}
status = board->sensor_centre->vl53L1_StartMeasurement();
if (status != 0) {
return status;
}
}
// create interrupt handler and start measurements
if (board->sensor_left!= NULL) {
status = board->sensor_left->stop_measurement();
if (status != 0) {
return status;
}
status = board->sensor_left->vl53L1_StartMeasurement();
if (status != 0) {
return status;
}
}
// create interrupt handler and start measurements
if (board->sensor_right!= NULL) {
status = board->sensor_right->stop_measurement();
if (status != 0) {
return status;
}
status = board->sensor_right->vl53L1_StartMeasurement();
if (status != 0) {
return status;
}
}
return status;
}
/* ISR callback function of the user blue button to switch measuring sensor. */
void measuring_stop_irq(void)
{
int_stop = true;
}
/*=================================== Main ==================================
=============================================================================*/
int main()
{
int status;
pc.baud(115200); // baud rate is important as printf statements take a lot of time
printf("mbed version : %d \r\n",MBED_VERSION);
// create i2c interface
ToF_DevI2C *dev_I2C = new ToF_DevI2C(I2C_SDA, I2C_SCL);
/* creates the 53L1A2 expansion board singleton obj */
board = XNucleo53L1A2::instance(dev_I2C, CentreIntPin, LeftIntPin, RightIntPin);
printf("board created!\r\n");
/* init the 53L1A1 expansion board with default values */
status = board->init_board();
if (status) {
printf("Failed to init board!\r\n");
return status;
}
printf("board initiated! - %d\r\n", status);
/* init an array with chars to id the sensors */
status = init_sensor();
if (status != 0) {
printf("Failed to init sensors!\r\n");
return status;
}
printf("loop forever\n");
VL53L1_MultiRangingData_t MultiRangingData;
VL53L1_MultiRangingData_t *pMultiRangingData = NULL;
while (true) {
pMultiRangingData = &MultiRangingData;
if (board->sensor_centre!= NULL) {
printf("Range result from Centre sensor\n");
status = board->sensor_centre->vl53L1_WaitMeasurementDataReady();
status = board->sensor_centre->vl53L1_GetMultiRangingData( pMultiRangingData);
print_results( devCentre.i2c_slave_address, pMultiRangingData );
status = board->sensor_centre->VL53L1_ClearInterrupt();
}
if (board->sensor_left!= NULL) {
printf("Range result from Left Satellite\n");
status = board->sensor_left->vl53L1_WaitMeasurementDataReady();
status = board->sensor_left->vl53L1_GetMultiRangingData( pMultiRangingData);
print_results( devLeft.i2c_slave_address, pMultiRangingData );
status = board->sensor_left->VL53L1_ClearInterrupt();
}
// create interrupt handler and start measurements
if (board->sensor_right!= NULL) {
printf("Range result from Right Satellite\n");
status = board->sensor_right->vl53L1_WaitMeasurementDataReady();
status = board->sensor_right->vl53L1_GetMultiRangingData( pMultiRangingData);
print_results( devRight.i2c_slave_address, pMultiRangingData );
status = board->sensor_right->VL53L1_ClearInterrupt();
}
}
printf("Terminating.\n");
}
// print what ever results are required
void print_results( int devNumber, VL53L1_MultiRangingData_t *pMultiRangingData )
{
int no_of_object_found = pMultiRangingData->NumberOfObjectsFound;
int signal_rate = 0;
int ambient_rate = 0;
int RoiNumber = pMultiRangingData->RoiNumber;
printf("no_of_object_found : %d\n", no_of_object_found);
if (( no_of_object_found < 10 ) && ( no_of_object_found != 0)) {
for(int j=0; j<no_of_object_found; j++) {
printf("RangeStatus : %d\n", pMultiRangingData->RangeData[j].RangeStatus);
if ((pMultiRangingData->RangeData[j].RangeStatus == VL53L1_RANGESTATUS_RANGE_VALID) ||
(pMultiRangingData->RangeData[j].RangeStatus == VL53L1_RANGESTATUS_RANGE_VALID_NO_WRAP_CHECK_FAIL)) {
signal_rate = pMultiRangingData->RangeData[j].SignalRateRtnMegaCps / 65535;
ambient_rate = pMultiRangingData->RangeData[j].AmbientRateRtnMegaCps / 65535;
printf("\t i2cAddr=%d \t RoiNumber=%d \t status=%d, \t D=%5dmm, \t Signal=%d Mcps, \t Ambient=%d Mcps \n",
devNumber, RoiNumber,
pMultiRangingData->RangeData[j].RangeStatus,
pMultiRangingData->RangeData[j].RangeMilliMeter,
signal_rate,
ambient_rate);
/*
// online compiler disables printf() / floating-point support, for code-size reasons.
// offline compiler can switch it on.
printf("\t i2cAddr=%d \t RoiNumber=%d \t status=%d, \t D=%5dmm, \t Signal=%2.2f Mcps, \t Ambient=%2.2f Mcps \n",
devNumber, RoiNumber,
pMultiRangingData->RangeData[j].RangeStatus,
pMultiRangingData->RangeData[j].RangeMilliMeter,
pMultiRangingData->RangeData[j].SignalRateRtnMegaCps / 65535.0,
pMultiRangingData->RangeData[j].AmbientRateRtnMegaCps / 65535.0);
*/
}
}
} // if (( no_of_object_found < 10 ) && ( no_of_object_found != 0))
}
#if (MBED_VERSION > 60300)
extern "C" void wait_ms(int ms)
{
thread_sleep_for(ms);
}
#endif