ardupilot/libraries/AP_Compass/AP_Compass_HMC5883L.cpp

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// -*- tab-width: 4; Mode: C++; c-basic-offset: 3; indent-tabs-mode: t -*-
/*
AP_Compass_HMC5883L.cpp - Arduino Library for HMC5883L I2C magnetometer
Code by Jordi Muñoz and Jose Julio. DIYDrones.com
This library is free software; you can redistribute it and/or
modify it under the terms of the GNU Lesser General Public
License as published by the Free Software Foundation; either
version 2.1 of the License, or (at your option) any later version.
Sensor is conected to I2C port
Sensor is initialized in Continuos mode (10Hz)
*/
// AVR LibC Includes
#include <math.h>
#include "WConstants.h"
#include <Wire.h>
#include "AP_Compass_HMC5883L.h"
#define COMPASS_ADDRESS 0x1E
#define ConfigRegA 0x00
#define ConfigRegB 0x01
#define ModeRegister 0x02
#define DataOutputXMSB 0x03
#define DataOutputXLSB 0x04
#define DataOutputZMSB 0x05
#define DataOutputZLSB 0x06
#define DataOutputYMSB 0x07
#define DataOutputYLSB 0x08
#define StatusRegister 0x09
#define IDRegisterA 0x0A
#define IDRegisterB 0x0B
#define IDRegisterC 0x0C
// default gain value
#define magGain 0x20
// ModeRegister valid modes
#define ContinuousConversion 0x00
#define SingleConversion 0x01
// ConfigRegA valid sample averaging
#define SampleAveraging_1 0x00
#define SampleAveraging_2 0x01
#define SampleAveraging_4 0x02
#define SampleAveraging_8 0x03
// ConfigRegA valid data output rates
#define DataOutputRate_0_75HZ 0x00
#define DataOutputRate_1_5HZ 0x01
#define DataOutputRate_3HZ 0x02
#define DataOutputRate_7_5HZ 0x03
#define DataOutputRate_15HZ 0x04
#define DataOutputRate_30HZ 0x05
#define DataOutputRate_75HZ 0x06
// ConfigRegA valid measurement configuration bits
#define NormalOperation 0x10
#define PositiveBiasConfig 0x11
#define NegativeBiasConfig 0x12
// Public Methods //////////////////////////////////////////////////////////////
bool AP_Compass_HMC5883L::init()
{
int numAttempts = 0;
int success = 0;
delay(10);
// calibration initialisation
calibration[0] = 1.0;
calibration[1] = 1.0;
calibration[2] = 1.0;
while( success == 0 && numAttempts < 5 )
{
// record number of attempts at initialisation
numAttempts++;
// force positiveBias (compass should return 715 for all channels)
Wire.beginTransmission(COMPASS_ADDRESS);
Wire.send(ConfigRegA);
Wire.send(SampleAveraging_8<<5 | DataOutputRate_75HZ<<2 | PositiveBiasConfig);
if (0 != Wire.endTransmission())
continue; // compass not responding on the bus
delay(50);
// set gains
Wire.beginTransmission(COMPASS_ADDRESS);
Wire.send(ConfigRegB);
Wire.send(magGain);
Wire.endTransmission();
delay(10);
// put compass into single-measurement mode
Wire.beginTransmission(COMPASS_ADDRESS);
Wire.send(ModeRegister);
Wire.send(SingleConversion);
Wire.endTransmission();
delay(10);
// read values from the compass
read();
delay(10);
// calibrate
if( abs(mag_x) > 500 && abs(mag_x) < 1000 && abs(mag_y) > 500 && abs(mag_y) < 1000 && abs(mag_z) > 500 && abs(mag_z) < 1000)
{
calibration[0] = fabs(715.0 / mag_x);
calibration[1] = fabs(715.0 / mag_y);
calibration[2] = fabs(715.0 / mag_z);
// mark success
success = 1;
}
// leave test mode
Wire.beginTransmission(COMPASS_ADDRESS);
Wire.send(ConfigRegA);
Wire.send(SampleAveraging_8<<5 | DataOutputRate_75HZ<<2 | NormalOperation);
Wire.endTransmission();
delay(50);
Wire.beginTransmission(COMPASS_ADDRESS);
Wire.send(ModeRegister);
Wire.send(ContinuousConversion); // Set continuous mode (default to 10Hz)
Wire.endTransmission(); // End transmission
delay(50);
}
return(success);
}
// Read Sensor data
void AP_Compass_HMC5883L::read()
{
int i = 0;
byte buff[6];
Vector3f rot_mag;
Wire.beginTransmission(COMPASS_ADDRESS);
Wire.send(0x03); //sends address to read from
Wire.endTransmission(); //end transmission
//Wire.beginTransmission(COMPASS_ADDRESS);
Wire.requestFrom(COMPASS_ADDRESS, 6); // request 6 bytes from device
while(Wire.available())
{
buff[i] = Wire.receive(); // receive one byte
i++;
}
Wire.endTransmission(); //end transmission
if (i==6) // All bytes received?
{
// MSB byte first, then LSB, X,Y,Z
mag_x = -((((int)buff[0]) << 8) | buff[1]) * calibration[0]; // X axis
mag_y = ((((int)buff[4]) << 8) | buff[5]) * calibration[1]; // Y axis
mag_z = -((((int)buff[2]) << 8) | buff[3]) * calibration[2]; // Z axis
last_update = millis(); // record time of update
// rotate and offset the magnetometer values
// XXX this could well be done in common code...
rot_mag = _orientation_matrix.get() * Vector3f(mag_x,mag_y,mag_z);
rot_mag = rot_mag + _offset.get();
mag_x = rot_mag.x;
mag_y = rot_mag.y;
mag_z = rot_mag.z;
}
}