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sensors.c
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sensors.c
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#include "sensors.h"
#include <math.h>
#define USE_MAG
#define USE_MADGWICK_AHRS
//#define USE_MAHONY_AHRS
#ifdef USE_MAHONY_AHRS
#include "MahonyAHRS.h"
#else
#include "MadgwickAHRS.h"
#endif
#define L3G_Sensitivity_250dps (float) 114.285f /*!< gyroscope sensitivity with 250 dps full scale [LSB/dps] */
#define L3G_Sensitivity_500dps (float) 57.1429f /*!< gyroscope sensitivity with 500 dps full scale [LSB/dps] */
#define L3G_Sensitivity_2000dps (float) 14.285f /*!< gyroscope sensitivity with 2000 dps full scale [LSB/dps] */
#define LSM_Acc_Sensitivity_2g (float) 1.0f /*!< accelerometer sensitivity with 2 g full scale [LSB/mg] */
#define LSM_Acc_Sensitivity_4g (float) 0.5f /*!< accelerometer sensitivity with 4 g full scale [LSB/mg] */
#define LSM_Acc_Sensitivity_8g (float) 0.25f /*!< accelerometer sensitivity with 8 g full scale [LSB/mg] */
#define LSM_Acc_Sensitivity_16g (float) 0.0834f /*!< accelerometer sensitivity with 12 g full scale [LSB/mg] */
#define QW q[0]
#define QX q[1]
#define QY q[2]
#define QZ q[3]
void AHRS_GetValues(float * val);
void readAllSensors(uint8_t *GyroTempBuf, uint8_t *AccTempBuf, uint8_t *MagTempBuf);
void readRawGyro(uint8_t *GyroTempBuf);
void processGyroData(float *GyroBuf, uint8_t *GyroTempBuf);
void processAccelData(float *AccBuf, uint8_t *AccTempBuf);
void processMagnetoData(float *MagBuf, uint8_t *MagTempBuf);
uint16_t Magn_Sensitivity_XY = 0, Magn_Sensitivity_Z = 0;
float GyroSensitivity = 0;
uint8_t Gyro_LBEFlag = 0;
uint8_t GyroDRDFlag = 0;
uint8_t Accel_LBEorFIFOFlag = 0;
float LSM_Acc_Sensitivity = LSM_Acc_Sensitivity_2g;
uint8_t Accel_cDivider;
void myFusion(float gx, float gy, float gz, float ax, float ay, float az, float mx, float my, float mz);
//float fNormAcc,fSinRoll,fCosRoll,fSinPitch,fCosPitch = 0.0f, RollAng = 0.0f, PitchAng = 0.0f;
//float fTiltedX,fTiltedY = 0.0f;
float MagBuffer[3] = {0.0f}, AccBuffer[3] = {0.0f}, GyroBuffer[3] = {0.0f};
uint8_t MagTempBuffer[6] = {0.0f}, AccTempBuffer[6] = {0.0f}, GyroTempBuffer[6] = {0.0f};
float QuaternionsBuffer[4] = {1.0f, 0.0f, 0.0f, 0.0f};
float euler[3] = {0.0f};
uint8_t eulerArr[6] = {0};
float GyroCorrectionCoeffs[3] = {0.0f};
void myFusion(float gx, float gy, float gz, float ax, float ay, float az, float mx, float my, float mz) {
float recipNorm;
q0 = 0;
q1 = gx;
q2 = gy;
q3 = gz;
// Normalise quaternion
recipNorm = 1/sqrt((q0 * q0) + (q1 * q1) + (q2 * q2) + (q3 * q3));
q0 *= recipNorm;
q1 *= recipNorm;
q2 *= recipNorm;
q3 *= recipNorm;
}
void updateQuaternions(float * quatBuf) {
float val[9] = {0.0f};
AHRS_GetValues(val);
#ifdef USE_MADGWICK_AHRS
#ifdef USE_MAG
MadgwickAHRSupdate(val[0]*PI/180.0, val[1]*PI/180.0, val[2]*PI/180.0, val[3], val[4], val[5], val[6], val[7], val[8]);
#else
MadgwickAHRSupdate(val[0]*PI/180.0, val[1]*PI/180.0, val[2]*PI/180.0, val[3], val[4], val[5], 0.0f, 0.0f, 0.0f);
//MadgwickAHRSupdate(0.0f, 0.0f, 0.0f, 100, 100, 1100, 0.0f, 0.0f, 0.0f);
#endif //#ifdef USE_MAG
#elif defined USE_MAHONY_AHRS
#ifdef USE_MAG
MahonyAHRSupdate(val[0]*PI/180.0, val[1]*PI/180.0, val[2]*PI/180.0, val[3], val[4], val[5], val[6], val[7], val[8]);
#else
MahonyAHRSupdate(val[0]*PI/180.0, val[1]*PI/180.0, val[2]*PI/180.0, val[3], val[4], val[5], 0.0f, 0.0f, 0.0f);
#endif //#ifdef USE_MAG
#else
myFusion(val[0]*PI/180.0, val[1]*PI/180.0, val[2]*PI/180.0, val[3], val[4], val[5], val[6], val[7], val[8]);
#endif
quatBuf[0] = q0;
quatBuf[1] = q1;
quatBuf[2] = q2;
quatBuf[3] = q3;
}
void readAllSensors(uint8_t *GyroTempBuf, uint8_t *AccTempBuf, uint8_t *MagTempBuf) {
L3GD20_Read(GyroTempBuf, L3GD20_OUT_X_L_ADDR, 6);
LSM303DLHC_Read(ACC_I2C_ADDRESS, LSM303DLHC_OUT_X_L_A, AccTempBuf, 6);
LSM303DLHC_Read(MAG_I2C_ADDRESS, LSM303DLHC_OUT_X_H_M, MagTempBuf, 6);
}
void readRawGyro(uint8_t *GyroTempBuf) {
L3GD20_Read(GyroTempBuf, L3GD20_OUT_X_L_ADDR, 6);
}
void AHRS_GetValues(float * val) {
STM_EVAL_LEDOn(LED8);
#if defined OUT_GYRO || defined OUT_ACCEL || defined OUT_MAG
uint8_t USART_TempBuf[100];
uint8_t byteCounter = 0;
#endif //#if defined OUT_GYRO || defined OUT_ACCEL || defined OUT_MAG
processGyroData(GyroBuffer, GyroTempBuffer);
processAccelData(AccBuffer, AccTempBuffer);
processMagnetoData(MagBuffer, MagTempBuffer);
val[0] = - (GyroBuffer[1] - GyroCorrectionCoeffs[1]);
val[1] = GyroBuffer[0] - GyroCorrectionCoeffs[0];
val[2] = GyroBuffer[2] - GyroCorrectionCoeffs[2];
#ifdef OUT_GYRO
byteCounter += sprintf((char*)(USART_TempBuf + byteCounter), "%f,%f,%f,", val[0], val[1], val[2]);
//USART_printfWithDMA("%f,%f,%f,", val[0], val[1], val[2]);
#endif //#ifdef OUT_GYRO
val[3] = AccBuffer[0];
val[4] = AccBuffer[1];
val[5] = AccBuffer[2];
#ifdef OUT_ACCEL
byteCounter += sprintf((char*)(USART_TempBuf + byteCounter), "%f,%f,%f,", val[3], val[4], val[5]);
//USART_printfWithDMA("%f,%f,%f,", val[3], val[4], val[5]);
#endif //#ifdef OUT_ACCEL
val[6] = MagBuffer[0];
val[7] = MagBuffer[1];
val[8] = MagBuffer[2];
#ifdef OUT_MAG
byteCounter += sprintf((char*)(USART_TempBuf + byteCounter), "%f,%f,%f,", val[6], val[7], val[8]);
//USART_printfWithDMA("%f,%f,%f,", val[6], val[7], val[8]);
#endif //#ifdef OUT_MAG
#if defined OUT_GYRO || defined OUT_ACCEL || defined OUT_MAG
sprintf((char*)(USART_TempBuf + byteCounter), "\r\n");
USART_printfWithDMA("%s", USART_TempBuf);
//USART_printfWithDMA("\r\n");
#endif
STM_EVAL_LEDOff(LED8);
}
void UpdateGyroBias() {
Delay_1ms(1000);
int i = 0;
for (i = 0; i < 100; i++) {
readRawGyro(GyroTempBuffer);
processGyroData(GyroBuffer, GyroTempBuffer);
GyroCorrectionCoeffs[0] += GyroBuffer[0];
GyroCorrectionCoeffs[1] += GyroBuffer[1];
GyroCorrectionCoeffs[2] += GyroBuffer[2];
Delay_1ms(10);
}
GyroCorrectionCoeffs[0] /= 100.0f;
GyroCorrectionCoeffs[1] /= 100.0f;
GyroCorrectionCoeffs[2] /= 100.0f;
}
/**
* @brief Configure the Mems to gyroscope application.
* @param None
* @retval None
*/
void Demo_GyroConfig(void)
{
L3GD20_InitTypeDef L3GD20_InitStructure;
L3GD20_FilterConfigTypeDef L3GD20_FilterStructure;
/* Configure Mems L3GD20 */
L3GD20_InitStructure.Power_Mode = L3GD20_MODE_ACTIVE;
L3GD20_InitStructure.Output_DataRate = L3GD20_OUTPUT_DATARATE_3;
L3GD20_InitStructure.Axes_Enable = L3GD20_AXES_ENABLE;
L3GD20_InitStructure.Band_Width = L3GD20_BANDWIDTH_4;
L3GD20_InitStructure.BlockData_Update = L3GD20_BlockDataUpdate_Single;
L3GD20_InitStructure.Endianness = L3GD20_BLE_LSB;
L3GD20_InitStructure.Full_Scale = L3GD20_FULLSCALE_250;
L3GD20_Init(&L3GD20_InitStructure);
L3GD20_FilterStructure.HighPassFilter_Mode_Selection =L3GD20_HPM_REF_SIGNAL;
L3GD20_FilterStructure.HighPassFilter_CutOff_Frequency = L3GD20_HPFCF_5;
L3GD20_FilterConfig(&L3GD20_FilterStructure) ;
L3GD20_FilterCmd(L3GD20_HIGHPASSFILTER_DISABLE);
L3GD20_INT2InterruptCmd(L3GD20_INT2INTERRUPT_ENABLE);
uint8_t tmpreg = 0;
L3GD20_Read(&tmpreg, L3GD20_CTRL_REG4_ADDR, 1);
/* Switch the sensitivity value set in the CRTL4 */
switch(tmpreg & 0x30)
{
case 0x00:
GyroSensitivity=L3G_Sensitivity_250dps;
break;
case 0x10:
GyroSensitivity=L3G_Sensitivity_500dps;
break;
case 0x20:
GyroSensitivity=L3G_Sensitivity_2000dps;
break;
}
Gyro_LBEFlag = tmpreg & 0x40;
}
/**
* @brief Configure the Mems to compass application.
* @param None
* @retval None
*/
void Demo_CompassConfig(void)
{
LSM303DLHCMag_InitTypeDef LSM303DLHC_InitStructure;
LSM303DLHCAcc_InitTypeDef LSM303DLHCAcc_InitStructure;
LSM303DLHCAcc_FilterConfigTypeDef LSM303DLHCFilter_InitStructure;
/* Configure MEMS magnetometer main parameters: temp, working mode, full Scale and Data rate */
LSM303DLHC_InitStructure.Temperature_Sensor = LSM303DLHC_TEMPSENSOR_DISABLE;
LSM303DLHC_InitStructure.MagOutput_DataRate =LSM303DLHC_ODR_220_HZ ;
LSM303DLHC_InitStructure.MagFull_Scale = LSM303DLHC_FS_1_3_GA;
LSM303DLHC_InitStructure.Working_Mode = LSM303DLHC_CONTINUOS_CONVERSION; //DO NOT CHANGE - IT DOES ONLY ONE CONVERSIO AND STOPS
LSM303DLHC_MagInit(&LSM303DLHC_InitStructure);
/* Fill the accelerometer structure */
LSM303DLHCAcc_InitStructure.Power_Mode = LSM303DLHC_NORMAL_MODE; // normal or low power mode
LSM303DLHCAcc_InitStructure.AccOutput_DataRate = LSM303DLHC_ODR_1344_HZ;
LSM303DLHCAcc_InitStructure.Axes_Enable= LSM303DLHC_AXES_ENABLE; // all axes are enabled
LSM303DLHCAcc_InitStructure.AccFull_Scale = LSM303DLHC_FULLSCALE_2G; //2G, 4G, 8G, 16G
LSM303DLHCAcc_InitStructure.BlockData_Update = LSM303DLHC_BlockUpdate_Continous; // Single or Continous
LSM303DLHCAcc_InitStructure.Endianness=LSM303DLHC_BLE_LSB;
LSM303DLHCAcc_InitStructure.High_Resolution=LSM303DLHC_HR_ENABLE; // High resolution enable
/* Configure the accelerometer main parameters */
LSM303DLHC_AccInit(&LSM303DLHCAcc_InitStructure);
/* Fill the accelerometer LPF structure */
LSM303DLHCFilter_InitStructure.HighPassFilter_Mode_Selection = LSM303DLHC_HPM_NORMAL_MODE;
LSM303DLHCFilter_InitStructure.HighPassFilter_CutOff_Frequency = LSM303DLHC_HPFCF_64; // 8, 16, 32, 64
LSM303DLHCFilter_InitStructure.HighPassFilter_AOI1 = LSM303DLHC_HPF_AOI1_DISABLE;
LSM303DLHCFilter_InitStructure.HighPassFilter_AOI2 = LSM303DLHC_HPF_AOI2_DISABLE;
/* Configure the accelerometer LPF main parameters */
LSM303DLHC_AccFilterConfig(&LSM303DLHCFilter_InitStructure);
LSM303DLHC_AccFilterCmd(LSM303DLHC_HIGHPASSFILTER_DISABLE);
uint8_t CTRLB = 0;
LSM303DLHC_Read(MAG_I2C_ADDRESS, LSM303DLHC_CRB_REG_M, &CTRLB, 1);
/* Switch the sensitivity set in the CRTLB*/
switch(CTRLB & 0xE0)
{
case LSM303DLHC_FS_1_3_GA:
Magn_Sensitivity_XY = LSM303DLHC_M_SENSITIVITY_XY_1_3Ga;
Magn_Sensitivity_Z = LSM303DLHC_M_SENSITIVITY_Z_1_3Ga;
break;
case LSM303DLHC_FS_1_9_GA:
Magn_Sensitivity_XY = LSM303DLHC_M_SENSITIVITY_XY_1_9Ga;
Magn_Sensitivity_Z = LSM303DLHC_M_SENSITIVITY_Z_1_9Ga;
break;
case LSM303DLHC_FS_2_5_GA:
Magn_Sensitivity_XY = LSM303DLHC_M_SENSITIVITY_XY_2_5Ga;
Magn_Sensitivity_Z = LSM303DLHC_M_SENSITIVITY_Z_2_5Ga;
break;
case LSM303DLHC_FS_4_0_GA:
Magn_Sensitivity_XY = LSM303DLHC_M_SENSITIVITY_XY_4Ga;
Magn_Sensitivity_Z = LSM303DLHC_M_SENSITIVITY_Z_4Ga;
break;
case LSM303DLHC_FS_4_7_GA:
Magn_Sensitivity_XY = LSM303DLHC_M_SENSITIVITY_XY_4_7Ga;
Magn_Sensitivity_Z = LSM303DLHC_M_SENSITIVITY_Z_4_7Ga;
break;
case LSM303DLHC_FS_5_6_GA:
Magn_Sensitivity_XY = LSM303DLHC_M_SENSITIVITY_XY_5_6Ga;
Magn_Sensitivity_Z = LSM303DLHC_M_SENSITIVITY_Z_5_6Ga;
break;
case LSM303DLHC_FS_8_1_GA:
Magn_Sensitivity_XY = LSM303DLHC_M_SENSITIVITY_XY_8_1Ga;
Magn_Sensitivity_Z = LSM303DLHC_M_SENSITIVITY_Z_8_1Ga;
break;
}
uint8_t ctrlx[2];
/* Read the register content */
LSM303DLHC_Read(ACC_I2C_ADDRESS, LSM303DLHC_CTRL_REG4_A, ctrlx, 2);
if(ctrlx[1]&0x40)
{
Accel_cDivider=64;
LSM_Acc_Sensitivity = 0.25;
}
else
{
Accel_cDivider=16;
/* normal mode */
/* switch the sensitivity value set in the CRTL4*/
switch(ctrlx[0] & 0x30)
{
case LSM303DLHC_FULLSCALE_2G:
LSM_Acc_Sensitivity = LSM_Acc_Sensitivity_2g;
break;
case LSM303DLHC_FULLSCALE_4G:
LSM_Acc_Sensitivity = LSM_Acc_Sensitivity_4g;
break;
case LSM303DLHC_FULLSCALE_8G:
LSM_Acc_Sensitivity = LSM_Acc_Sensitivity_8g;
break;
case LSM303DLHC_FULLSCALE_16G:
LSM_Acc_Sensitivity = LSM_Acc_Sensitivity_16g;
break;
}
}
Accel_LBEorFIFOFlag = (ctrlx[0] & 0x40) || (ctrlx[1] & 0x40);
}
void processGyroData(float *GyroBuf, uint8_t *GyroTempBuf) {
int16_t RawData[3] = {0};
int i = 0;
/* check in the control register 4 the data alignment (Big Endian or Little Endian)*/
if(!(Gyro_LBEFlag))
{
for(i=0; i<3; i++)
{
RawData[i]=(int16_t)(((uint16_t)GyroTempBuf[2*i+1] << 8) + GyroTempBuf[2*i]);
}
}
else
{
for(i=0; i<3; i++)
{
RawData[i]=(int16_t)(((uint16_t)GyroTempBuf[2*i] << 8) + GyroTempBuf[2*i+1]);
}
}
/* divide by sensitivity */
for(i=0; i<3; i++)
{
GyroBuf[i]=(float)RawData[i]/GyroSensitivity;
}
}
void processAccelData(float *AccBuf, uint8_t *AccelTempBuf) {
int16_t pnRawData[3];
uint8_t i;
/* check in the control register4 the data alignment*/
if(!Accel_LBEorFIFOFlag) /* Little Endian Mode or FIFO mode */
{
for(i=0; i<3; i++)
{
pnRawData[i]=((int16_t)((uint16_t)AccelTempBuf[2*i+1] << 8) + AccelTempBuf[2*i])/Accel_cDivider;
}
}
else /* Big Endian Mode */
{
for(i=0; i<3; i++)
pnRawData[i]=((int16_t)((uint16_t)AccelTempBuf[2*i] << 8) + AccelTempBuf[2*i+1])/Accel_cDivider;
}
/* Obtain the mg value for the three axis */
for(i=0; i<3; i++)
{
AccBuf[i]=(float)pnRawData[i]/LSM_Acc_Sensitivity;
}
}
void processMagnetoData(float *MagBuf, uint8_t *MagnTempBuf) {
MagBuf[0]=(float)((int16_t)(((uint16_t)MagnTempBuf[0] << 8) + MagnTempBuf[1]))/Magn_Sensitivity_XY;
MagBuf[2]=(float)((int16_t)(((uint16_t)MagnTempBuf[2] << 8) + MagnTempBuf[3]))/Magn_Sensitivity_Z; // THIS IS Z! Check datasheet!
MagBuf[1]=(float)((int16_t)(((uint16_t)MagnTempBuf[4] << 8) + MagnTempBuf[5]))/Magn_Sensitivity_XY; // THIS IS Y! Check datasheet!
}
void getEulerAngles(float *euler) {
float *q = QuaternionsBuffer;
/*euler[0] = atan2(2*q[1]*q[2]-2*q[0]*q[3], 2*q[0]*q[0]+2*q[1]*q[1]-1)*180/PI; // heading, yaw, phi
euler[1] = -asin(2*q[1]*q[3]+2*q[0]*q[2])*180/PI; // attitude, elevation, pitch, theta
euler[2] = atan2(2*q[2]*q[3]-2*q[0]*q[1], 2*q[0]*q[0]+2*q[3]*q[3]-1)*180/PI; // bank, roll, psi*/
float test = QX*QY+QZ*QW;
if (test > 0.499) {
euler[0] = 2*atan2(QX, QW)*180/PI;
euler[1] = PI*180/(2*PI);
euler[2] = 0;
} else if (test< -0.499) {
euler[0] = -2*atan2(QX, QW)*180/PI;
euler[1] = -PI*180/(2*PI);
euler[2] = 0;
} else {
euler[0] = atan2(2*QY*QW - 2*QX*QZ, 1 - 2*QY*QY - 2*QZ*QZ)*180/PI;
euler[1] = asin(2*QX*QY + 2*QZ*QW)*180/PI;
euler[2] = atan2(2*QX*QW - 2*QY*QZ, 1 - 2*QX*QX - 2*QZ*QZ)*180/PI;
}
}
void getEulerAsArray(uint8_t *eulerArr) {
int i = 0;
int16_t elrs = 0;
// Axis X - third Euler
elrs = (int16_t)(euler[0]);
eulerArr[0] = (uint8_t)elrs;
eulerArr[1] = (uint8_t)(elrs>>8);
// Axis Y - second Euler
elrs = (int16_t)(euler[1]);
eulerArr[2] = (uint8_t)elrs;
eulerArr[3] = (uint8_t)(elrs>>8);
// Axis Z - first Euler
elrs = (int16_t)(euler[2]);
eulerArr[4] = (uint8_t)elrs;
eulerArr[5] = (uint8_t)(elrs>>8);
}
/**
* @brief Basic management of the timeout situation.
* @param None.
* @retval None.
*/
uint32_t LSM303DLHC_TIMEOUT_UserCallback(void)
{
return 0;
}
/**
* @brief Basic management of the timeout situation.
* @param None.
* @retval None.
*/
uint32_t L3GD20_TIMEOUT_UserCallback(void)
{
return 0;
}