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LSM303DLHC Full Driver: Readings For Acc, Mag and Temp; Class Method for frequently-used 13 sensor parameters; Class Method to direct modify registers; Support Calibration (offset+scale);
LSM303DLHC.cpp
- Committer:
- Airium
- Date:
- 2016-06-09
- Revision:
- 4:8723c07d4c45
- Parent:
- 3:522d01930e6a
File content as of revision 4:8723c07d4c45:
#include "mbed.h"
#include "LSM303DLHC.h"
LSM303DLHC::LSM303DLHC(PinName sda, PinName scl) : i2c(sda, scl){
i2c.frequency(400000);
// HERE GIVES DEVICE DEFAULT
ACtrl(LP_OFF); // ACC Normal Power Mode
ACtrl(ADR3); // ACC ON and Date Rate 25Hz
ACtrl(XYZ); // ACC XYZ Axis Enable
ACtrl(HPF_ON); // ACC internal HPF IN USE
ACtrl(HPF_CF0); // ACC HPF Cutoff Freq = option 0
ACtrl(HPF_NORM_R); // ACC HPF Model = Normal
ACtrl(BDU_CONT); // ACC data continuous
ACtrl(G4); // ACC Range +/-4g
ACtrl(HIGH_R); // ACC in High Prec
MCtrl(MDR4); // MAG DR 15Hz
MCtrl(GN4); // MAG GN 4.0Gauss
MCtrl(MD_CONT); // MAG ON and MD Continuous
TCtrl(TEMP_ON); // TEMP ON
// DEFAULT CALIBRATION PARAMETER
acc_offset[0] = 0;
acc_offset[1] = 0;
acc_offset[2] = 0;
acc_scale[0] = 1;
acc_scale[1] = 1;
acc_scale[2] = 1;
mag_offset[0] = 0;
mag_offset[1] = 0;
mag_offset[2] = 0;
mag_scale[0] = 1;
mag_scale[1] = 1;
mag_scale[2] = 1;
temp_offset[0] = 0;
temp_scale[0] = 1;
}
void LSM303DLHC::GetAcc(float arr[3]){
data[0] = OUT_X_L_A | (1 << 7); // MSB=1 to read multiple bytes
i2c.write(ACC_ADDRESS, data, 1);
i2c.read(ACC_ADDRESS, data, 6);
arr[0] = acc_scale[0]*(acc_offset[0]+((short)(data[1]<<8 | data[0])>>4));
arr[1] = acc_scale[1]*(acc_offset[1]+((short)(data[3]<<8 | data[2])>>4));
arr[2] = acc_scale[2]*(acc_offset[2]+((short)(data[5]<<8 | data[4])>>4));
}
void LSM303DLHC::GetMag(float arr[3]){
data[0] = OUT_X_H_M;
i2c.write(MAG_ADDRESS, data, 1);
i2c.read(MAG_ADDRESS, data, 6);
arr[0] = mag_scale[0]*(mag_offset[0]+(short)(data[0]<<8 | data[1]));
arr[1] = mag_scale[1]*(mag_offset[1]+(short)(data[4]<<8 | data[5]));
arr[2] = mag_scale[2]*(mag_offset[2]+(short)(data[2]<<8 | data[3]));
}
void LSM303DLHC::GetTemp(float arr[1]){
data[0] = TEMP_OUT_H_M;
i2c.write(MAG_ADDRESS, data, 1);
i2c.read(MAG_ADDRESS, data, 2);
arr[0] = temp_scale[0]*(temp_offset[0]+((short)(data[0]<<8 | data[1])>>4));
}
void LSM303DLHC::ACtrl(ACC_ODR cmd){
data[0] = CTRL_REG1_A;
i2c.write(ACC_ADDRESS, data, 1);
i2c.read(ACC_ADDRESS, &data[1], 1);
data[1] = data[1] & (0b00001111) | (cmd<<4);
i2c.write(ACC_ADDRESS, data, 2);
}
void LSM303DLHC::ACtrl(ACC_LPen cmd){
data[0] = CTRL_REG1_A;
i2c.write(ACC_ADDRESS, data, 1);
i2c.read(ACC_ADDRESS, &data[1], 1);
data[1] = data[1] & (0b11110111) | (cmd<<3);
i2c.write(ACC_ADDRESS, data, 2);
}
void LSM303DLHC::ACtrl(ACC_AXIS cmd){
data[0] = CTRL_REG1_A;
i2c.write(ACC_ADDRESS, data, 1);
i2c.read(ACC_ADDRESS, &data[1], 1);
data[1] = data[1] & (0b11111000) | (cmd<<0);
i2c.write(ACC_ADDRESS, data, 2);
}
void LSM303DLHC::ACtrl(ACC_HPM cmd){
data[0] = CTRL_REG2_A;
i2c.write(ACC_ADDRESS, data, 1);
i2c.read(ACC_ADDRESS, &data[1], 1);
data[1] = data[1] & (0b00111111) | (cmd<<6);
i2c.write(ACC_ADDRESS, data, 2);
}
void LSM303DLHC::ACtrl(ACC_HPCF cmd){
data[0] = CTRL_REG2_A;
i2c.write(ACC_ADDRESS, data, 1);
i2c.read(ACC_ADDRESS, &data[1], 1);
data[1] = data[1] & (0b11001111) | (cmd<<4);
i2c.write(ACC_ADDRESS, data, 2);
}
void LSM303DLHC::ACtrl(ACC_FDS cmd){
data[0] = CTRL_REG2_A;
i2c.write(ACC_ADDRESS, data, 1);
i2c.read(ACC_ADDRESS, &data[1], 1);
data[1] = data[1] & (0b11110111) | (cmd<<3);
i2c.write(ACC_ADDRESS, data, 2);
}
void LSM303DLHC::ACtrl(ACC_BDU cmd){
data[0] = CTRL_REG4_A;
i2c.write(ACC_ADDRESS, data, 1);
i2c.read(ACC_ADDRESS, &data[1], 1);
data[1] = data[1] & (0b01111111) | (cmd<<7);
i2c.write(ACC_ADDRESS, data, 2);
}
void LSM303DLHC::ACtrl(ACC_FS cmd){
data[0] = CTRL_REG4_A;
i2c.write(ACC_ADDRESS, data, 1);
i2c.read(ACC_ADDRESS, &data[1], 1);
data[1] = data[1] & (0b11001111) | (cmd<<4);
i2c.write(ACC_ADDRESS, data, 2);
}
void LSM303DLHC::ACtrl(ACC_HR cmd){
data[0] = CTRL_REG4_A;
i2c.write(ACC_ADDRESS, data, 1);
i2c.read(ACC_ADDRESS, &data[1], 1);
data[1] = data[1] & (0b11110111) | (cmd<<3);
i2c.write(ACC_ADDRESS, data, 2);
}
void LSM303DLHC::TCtrl(TEMP_EN cmd){
data[0] = CRA_REG_M;
i2c.write(MAG_ADDRESS, data, 1);
i2c.read(MAG_ADDRESS, &data[1], 1);
data[1] = data[1] & (0b01111111) | (cmd<<7);
i2c.write(MAG_ADDRESS, data, 2);
}
void LSM303DLHC::MCtrl(MAG_DR cmd){
data[0] = CRA_REG_M;
i2c.write(MAG_ADDRESS, data, 1);
i2c.read(MAG_ADDRESS, &data[1], 1);
data[1] = data[1] & (0b11100011) | (cmd<<2);
i2c.write(MAG_ADDRESS, data, 2);
}
void LSM303DLHC::MCtrl(MAG_GN cmd){
data[0] = CRB_REG_M;
i2c.write(MAG_ADDRESS, data, 1);
i2c.read(MAG_ADDRESS, &data[1], 1);
data[1] = data[1] & (0b00011111) | (cmd<<5);
i2c.write(MAG_ADDRESS, data, 2);
}
void LSM303DLHC::MCtrl(MAG_MD cmd){
data[0] = MR_REG_M;
i2c.write(MAG_ADDRESS, data, 1);
i2c.read(MAG_ADDRESS, &data[1], 1);
data[1] = data[1] & (0b11111100) | (cmd<<0);
i2c.write(MAG_ADDRESS, data, 2);
}
void LSM303DLHC::WriteReg(int sad, char d[2]){
i2c.write(sad, d, 2);
}
void LSM303DLHC::ACal(float offset[3], float scale[3]){
acc_offset[0] = offset[0];
acc_offset[1] = offset[1];
acc_offset[2] = offset[2];
acc_scale[0] = scale[0];
acc_scale[1] = scale[1];
acc_scale[2] = scale[2];
}
void LSM303DLHC::MCal(float offset[3], float scale[3]){
mag_offset[0] = offset[0];
mag_offset[1] = offset[1];
mag_offset[2] = offset[2];
mag_scale[0] = scale[0];
mag_scale[1] = scale[1];
mag_scale[2] = scale[2];
}
void LSM303DLHC::TCal(float offset[1], float scale[1]){
temp_offset[0] = offset[0];
temp_scale[0] = scale[0];
}