College Project
Dependents: MPU9250_SPI_Test_1201
MPU9250.cpp
- Committer:
- kylongmu
- Date:
- 2014-07-01
- Revision:
- 9:a8733542d0fb
- Parent:
- 8:492028cb604e
- Child:
- 10:d27b3298e9e0
File content as of revision 9:a8733542d0fb:
/*CODED by Qiyong Mu on 21/06/2014 kylongmu@msn.com */ #include <mbed.h> #include "MPU9250.h" mpu9250_spi::mpu9250_spi(SPI& _spi, PinName _cs) : spi(_spi), cs(_cs) {} unsigned int mpu9250_spi::WriteReg( uint8_t WriteAddr, uint8_t WriteData ) { unsigned int temp_val; select(); spi.write(WriteAddr); temp_val=spi.write(WriteData); deselect(); wait_us(50); return temp_val; } unsigned int mpu9250_spi::ReadReg( uint8_t WriteAddr, uint8_t WriteData ) { return WriteReg(WriteAddr | READ_FLAG,WriteData); } void mpu9250_spi::ReadRegs( uint8_t ReadAddr, uint8_t *ReadBuf, unsigned int Bytes ) { unsigned int i = 0; select(); spi.write(ReadAddr | READ_FLAG); for(i=0; i<Bytes; i++) ReadBuf[i] = spi.write(0x00); deselect(); wait_us(50); } /*----------------------------------------------------------------------------------------------- INITIALIZATION usage: call this function at startup, giving the sample rate divider (raging from 0 to 255) and low pass filter value; suitable values are: BITS_DLPF_CFG_256HZ_NOLPF2 BITS_DLPF_CFG_188HZ BITS_DLPF_CFG_98HZ BITS_DLPF_CFG_42HZ BITS_DLPF_CFG_20HZ BITS_DLPF_CFG_10HZ BITS_DLPF_CFG_5HZ BITS_DLPF_CFG_2100HZ_NOLPF returns 1 if an error occurred -----------------------------------------------------------------------------------------------*/ #define MPU_InitRegNum 17 bool mpu9250_spi::init(int sample_rate_div,int low_pass_filter){ uint8_t i = 0; uint8_t MPU_Init_Data[MPU_InitRegNum][2] = { {0x80, MPUREG_PWR_MGMT_1}, // Reset Device {0x01, MPUREG_PWR_MGMT_1}, // Clock Source {0x00, MPUREG_PWR_MGMT_2}, // Enable Acc & Gyro {0x01, MPUREG_CONFIG}, // Use DLPF set Gyroscope bandwidth 184Hz, temperature bandwidth 188Hz {0x18, MPUREG_GYRO_CONFIG}, // +-2000dps {0x08, MPUREG_ACCEL_CONFIG}, // +-4G {0x09, MPUREG_ACCEL_CONFIG_2}, // Set Acc Data Rates, Enable Acc LPF , Bandwidth 184Hz {0x30, MPUREG_INT_PIN_CFG}, // //{0x40, MPUREG_I2C_MST_CTRL}, // I2C Speed 348 kHz //{0x20, MPUREG_USER_CTRL}, // Enable AUX {0x20, MPUREG_USER_CTRL}, // I2C Master mode {0x0D, MPUREG_I2C_MST_CTRL}, // I2C configuration multi-master IIC 400KHz {AK8963_I2C_ADDR, MPUREG_I2C_SLV0_ADDR}, //Set the I2C slave addres of AK8963 and set for write. //{0x09, MPUREG_I2C_SLV4_CTRL}, //{0x81, MPUREG_I2C_MST_DELAY_CTRL}, //Enable I2C delay {AK8963_CNTL2, MPUREG_I2C_SLV0_REG}, //I2C slave 0 register address from where to begin data transfer {0x01, MPUREG_I2C_SLV0_DO}, // Reset AK8963 {0x81, MPUREG_I2C_SLV0_CTRL}, //Enable I2C and set 1 byte {AK8963_CNTL1, MPUREG_I2C_SLV0_REG}, //I2C slave 0 register address from where to begin data transfer {0x12, MPUREG_I2C_SLV0_DO}, // Register value to continuous measurement in 16bit {0x81, MPUREG_I2C_SLV0_CTRL} //Enable I2C and set 1 byte }; spi.format(8,0); spi.frequency(1000000); for(i=0; i<MPU_InitRegNum; i++) { WriteReg(MPU_Init_Data[i][1], MPU_Init_Data[i][0]); wait(0.001); //I2C must slow down the write speed, otherwise it won't work } //set_acc_scale(2); //set_gyro_scale(250); Magnetometer_divider=2; return 0; } /*----------------------------------------------------------------------------------------------- ACCELEROMETER SCALE usage: call this function at startup, after initialization, to set the right range for the accelerometers. Suitable ranges are: BITS_FS_2G BITS_FS_4G BITS_FS_8G BITS_FS_16G returns the range set (2,4,8 or 16) -----------------------------------------------------------------------------------------------*/ unsigned int mpu9250_spi::set_acc_scale(int scale){ unsigned int temp_scale; WriteReg(MPUREG_ACCEL_CONFIG, scale); switch (scale){ case BITS_FS_2G: acc_divider=16384; break; case BITS_FS_4G: acc_divider=8192; break; case BITS_FS_8G: acc_divider=4096; break; case BITS_FS_16G: acc_divider=2048; break; } temp_scale=WriteReg(MPUREG_ACCEL_CONFIG|READ_FLAG, 0x00); switch (temp_scale){ case BITS_FS_2G: temp_scale=2; break; case BITS_FS_4G: temp_scale=4; break; case BITS_FS_8G: temp_scale=8; break; case BITS_FS_16G: temp_scale=16; break; } return temp_scale; } /*----------------------------------------------------------------------------------------------- GYROSCOPE SCALE usage: call this function at startup, after initialization, to set the right range for the gyroscopes. Suitable ranges are: BITS_FS_250DPS BITS_FS_500DPS BITS_FS_1000DPS BITS_FS_2000DPS returns the range set (250,500,1000 or 2000) -----------------------------------------------------------------------------------------------*/ unsigned int mpu9250_spi::set_gyro_scale(int scale){ unsigned int temp_scale; WriteReg(MPUREG_GYRO_CONFIG, scale); switch (scale){ case BITS_FS_250DPS: gyro_divider=131; break; case BITS_FS_500DPS: gyro_divider=65.5; break; case BITS_FS_1000DPS: gyro_divider=32.8; break; case BITS_FS_2000DPS: gyro_divider=16.4; break; } temp_scale=WriteReg(MPUREG_GYRO_CONFIG|READ_FLAG, 0x00); switch (temp_scale){ case BITS_FS_250DPS: temp_scale=250; break; case BITS_FS_500DPS: temp_scale=500; break; case BITS_FS_1000DPS: temp_scale=1000; break; case BITS_FS_2000DPS: temp_scale=2000; break; } return temp_scale; } /*----------------------------------------------------------------------------------------------- WHO AM I? usage: call this function to know if SPI is working correctly. It checks the I2C address of the mpu9250 which should be 104 when in SPI mode. returns the I2C address (104) -----------------------------------------------------------------------------------------------*/ unsigned int mpu9250_spi::whoami(){ unsigned int response; response=WriteReg(MPUREG_WHOAMI|READ_FLAG, 0x00); return response; } /*----------------------------------------------------------------------------------------------- READ ACCELEROMETER usage: call this function to read accelerometer data. Axis represents selected axis: 0 -> X axis 1 -> Y axis 2 -> Z axis -----------------------------------------------------------------------------------------------*/ void mpu9250_spi::read_acc() { uint8_t response[6]; int16_t bit_data; float data; int i; ReadRegs(MPUREG_ACCEL_XOUT_H,response,6); for(i=0; i<3; i++) { bit_data=((int16_t)response[i*2]<<8)|response[i*2+1]; data=(float)bit_data; accelerometer_data[i]=data/acc_divider; } } /*----------------------------------------------------------------------------------------------- READ GYROSCOPE usage: call this function to read gyroscope data. Axis represents selected axis: 0 -> X axis 1 -> Y axis 2 -> Z axis -----------------------------------------------------------------------------------------------*/ void mpu9250_spi::read_rot() { uint8_t response[6]; int16_t bit_data; float data; int i; ReadRegs(MPUREG_GYRO_XOUT_H,response,6); for(i=0; i<3; i++) { bit_data=((int16_t)response[i*2]<<8)|response[i*2+1]; data=(float)bit_data; gyroscope_data[i]=data/gyro_divider; } } /*----------------------------------------------------------------------------------------------- READ TEMPERATURE usage: call this function to read temperature data. returns the value in °C -----------------------------------------------------------------------------------------------*/ void mpu9250_spi::read_temp(){ uint8_t response[2]; int16_t bit_data; float data; ReadRegs(MPUREG_TEMP_OUT_H,response,2); bit_data=((int16_t)response[0]<<8)|response[1]; data=(float)bit_data; Temperature=(data/340)+36.53; deselect(); } /*----------------------------------------------------------------------------------------------- READ ACCELEROMETER CALIBRATION usage: call this function to read accelerometer data. Axis represents selected axis: 0 -> X axis 1 -> Y axis 2 -> Z axis returns Factory Trim value -----------------------------------------------------------------------------------------------*/ void mpu9250_spi::calib_acc() { uint8_t response[4]; int temp_scale; //READ CURRENT ACC SCALE temp_scale=WriteReg(MPUREG_ACCEL_CONFIG|READ_FLAG, 0x00); set_acc_scale(BITS_FS_8G); //ENABLE SELF TEST need modify //temp_scale=WriteReg(MPUREG_ACCEL_CONFIG, 0x80>>axis); ReadRegs(MPUREG_SELF_TEST_X,response,4); calib_data[0]=((response[0]&11100000)>>3)|((response[3]&00110000)>>4); calib_data[1]=((response[1]&11100000)>>3)|((response[3]&00001100)>>2); calib_data[2]=((response[2]&11100000)>>3)|((response[3]&00000011)); set_acc_scale(temp_scale); } uint8_t mpu9250_spi::AK8963_whoami(){ uint8_t response[2]; WriteReg(MPUREG_I2C_SLV0_ADDR,AK8963_I2C_ADDR|READ_FLAG); //Set the I2C slave addres of AK8963 and set for read. WriteReg(MPUREG_I2C_SLV0_REG, AK8963_WIA); //I2C slave 0 register address from where to begin data transfer WriteReg(MPUREG_I2C_SLV0_CTRL, 0x82); //Read 1 byte from the magnetometer //WriteReg(MPUREG_I2C_SLV0_CTRL, 0x81); //Enable I2C and set bytes wait(0.001); //response[0]=WriteReg(MPUREG_EXT_SENS_DATA_01|READ_FLAG, 0x00); //Read I2C ReadRegs(MPUREG_EXT_SENS_DATA_00,response,2); //response=WriteReg(MPUREG_I2C_SLV0_DO, 0x00); //Read I2C return response[0]; } void mpu9250_spi::AK8963_read_Magnetometer(){ uint8_t response[7]; int16_t bit_data; float data; int i; WriteReg(MPUREG_I2C_SLV0_ADDR,AK8963_I2C_ADDR|READ_FLAG); //Set the I2C slave addres of AK8963 and set for read. WriteReg(MPUREG_I2C_SLV0_REG, AK8963_HXL); //I2C slave 0 register address from where to begin data transfer WriteReg(MPUREG_I2C_SLV0_CTRL, 0x87); //Read 6 bytes from the magnetometer wait(0.001); ReadRegs(MPUREG_EXT_SENS_DATA_00,response,7); //must start your read from AK8963A register 0x03 and read seven bytes so that upon read of ST2 register 0x09 the AK8963A will unlatch the data registers for the next measurement. for(i=0; i<3; i++) { bit_data=((int16_t)response[i*2]<<8)|response[i*2+1]; data=(float)bit_data; Magnetometer[i]=data/Magnetometer_divider; } } void mpu9250_spi::read_all(){ uint8_t response[21]; int16_t bit_data; float data; int i; //Send I2C command at first WriteReg(MPUREG_I2C_SLV0_ADDR,AK8963_I2C_ADDR|READ_FLAG); //Set the I2C slave addres of AK8963 and set for read. WriteReg(MPUREG_I2C_SLV0_REG, AK8963_HXL); //I2C slave 0 register address from where to begin data transfer WriteReg(MPUREG_I2C_SLV0_CTRL, 0x87); //Read 7 bytes from the magnetometer //must start your read from AK8963A register 0x03 and read seven bytes so that upon read of ST2 register 0x09 the AK8963A will unlatch the data registers for the next measurement. //wait(0.001); ReadRegs(MPUREG_ACCEL_XOUT_H,response,21); //Get accelerometer value for(i=0; i<3; i++) { bit_data=((int16_t)response[i*2]<<8)|response[i*2+1]; data=(float)bit_data; accelerometer_data[i]=data/acc_divider; } //Get temperature bit_data=((int16_t)response[i*2]<<8)|response[i*2+1]; data=(float)bit_data; Temperature=((data-21)/333.87)+21; //Get gyroscop value for(i=4; i<7; i++) { bit_data=((int16_t)response[i*2]<<8)|response[i*2+1]; data=(float)bit_data; gyroscope_data[i-4]=data/gyro_divider; } //Get Magnetometer value for(i=7; i<10; i++) { bit_data=((int16_t)response[i*2]<<8)|response[i*2+1]; data=(float)bit_data; Magnetometer[i-7]=data/Magnetometer_divider; } } /*----------------------------------------------------------------------------------------------- SPI SELECT AND DESELECT usage: enable and disable mpu9250 communication bus -----------------------------------------------------------------------------------------------*/ void mpu9250_spi::select() { //Set CS low to start transmission (interrupts conversion) cs = 0; } void mpu9250_spi::deselect() { //Set CS high to stop transmission (restarts conversion) cs = 1; }