mirror of https://github.com/ArduPilot/ardupilot
388 lines
12 KiB
C++
388 lines
12 KiB
C++
/// -*- tab-width: 4; Mode: C++; c-basic-offset: 4; indent-tabs-mode: nil -*-
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/*
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This program is free software: you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation, either version 3 of the License, or
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(at your option) any later version.
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This program is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with this program. If not, see <http://www.gnu.org/licenses/>.
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*/
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/*
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* AP_Compass_HMC5843.cpp - Arduino Library for HMC5843 I2C magnetometer
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* Code by Jordi Muñoz and Jose Julio. DIYDrones.com
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*
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* Sensor is conected to I2C port
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* Sensor is initialized in Continuos mode (10Hz)
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*
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*/
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// AVR LibC Includes
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#include <AP_Math.h>
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#include <AP_HAL.h>
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#include "AP_Compass_HMC5843.h"
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extern const AP_HAL::HAL& hal;
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#define COMPASS_ADDRESS 0x1E
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#define ConfigRegA 0x00
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#define ConfigRegB 0x01
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#define magGain 0x20
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#define PositiveBiasConfig 0x11
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#define NegativeBiasConfig 0x12
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#define NormalOperation 0x10
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#define ModeRegister 0x02
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#define ContinuousConversion 0x00
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#define SingleConversion 0x01
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// ConfigRegA valid sample averaging for 5883L
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#define SampleAveraging_1 0x00
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#define SampleAveraging_2 0x01
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#define SampleAveraging_4 0x02
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#define SampleAveraging_8 0x03
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// ConfigRegA valid data output rates for 5883L
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#define DataOutputRate_0_75HZ 0x00
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#define DataOutputRate_1_5HZ 0x01
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#define DataOutputRate_3HZ 0x02
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#define DataOutputRate_7_5HZ 0x03
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#define DataOutputRate_15HZ 0x04
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#define DataOutputRate_30HZ 0x05
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#define DataOutputRate_75HZ 0x06
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// read_register - read a register value
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bool AP_Compass_HMC5843::read_register(uint8_t address, uint8_t *value)
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{
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if (hal.i2c->readRegister((uint8_t)COMPASS_ADDRESS, address, value) != 0) {
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_healthy[0] = false;
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return false;
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}
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return true;
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}
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// write_register - update a register value
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bool AP_Compass_HMC5843::write_register(uint8_t address, uint8_t value)
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{
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if (hal.i2c->writeRegister((uint8_t)COMPASS_ADDRESS, address, value) != 0) {
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_healthy[0] = false;
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return false;
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}
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return true;
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}
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// Read Sensor data
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bool AP_Compass_HMC5843::read_raw()
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{
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uint8_t buff[6];
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if (hal.i2c->readRegisters(COMPASS_ADDRESS, 0x03, 6, buff) != 0) {
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if (_healthy[0]) {
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hal.i2c->setHighSpeed(false);
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}
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_healthy[0] = false;
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_i2c_sem->give();
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return false;
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}
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int16_t rx, ry, rz;
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rx = (((int16_t)buff[0]) << 8) | buff[1];
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if (product_id == AP_COMPASS_TYPE_HMC5883L) {
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rz = (((int16_t)buff[2]) << 8) | buff[3];
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ry = (((int16_t)buff[4]) << 8) | buff[5];
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} else {
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ry = (((int16_t)buff[2]) << 8) | buff[3];
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rz = (((int16_t)buff[4]) << 8) | buff[5];
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}
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if (rx == -4096 || ry == -4096 || rz == -4096) {
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// no valid data available
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return false;
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}
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_mag_x = -rx;
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_mag_y = ry;
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_mag_z = -rz;
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return true;
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}
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// accumulate a reading from the magnetometer
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void AP_Compass_HMC5843::accumulate(void)
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{
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if (!_initialised) {
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// someone has tried to enable a compass for the first time
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// mid-flight .... we can't do that yet (especially as we won't
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// have the right orientation!)
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return;
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}
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uint32_t tnow = hal.scheduler->micros();
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if (_healthy[0] && _accum_count != 0 && (tnow - _last_accum_time) < 13333) {
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// the compass gets new data at 75Hz
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return;
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}
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if (!_i2c_sem->take(1)) {
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// the bus is busy - try again later
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return;
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}
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bool result = read_raw();
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_i2c_sem->give();
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if (result) {
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// the _mag_N values are in the range -2048 to 2047, so we can
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// accumulate up to 15 of them in an int16_t. Let's make it 14
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// for ease of calculation. We expect to do reads at 10Hz, and
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// we get new data at most 75Hz, so we don't expect to
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// accumulate more than 8 before a read
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_mag_x_accum += _mag_x;
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_mag_y_accum += _mag_y;
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_mag_z_accum += _mag_z;
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_accum_count++;
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if (_accum_count == 14) {
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_mag_x_accum /= 2;
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_mag_y_accum /= 2;
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_mag_z_accum /= 2;
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_accum_count = 7;
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}
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_last_accum_time = tnow;
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}
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}
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/*
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* re-initialise after a IO error
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*/
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bool AP_Compass_HMC5843::re_initialise()
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{
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if (!write_register(ConfigRegA, _base_config) ||
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!write_register(ConfigRegB, magGain) ||
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!write_register(ModeRegister, ContinuousConversion))
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return false;
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return true;
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}
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// Public Methods //////////////////////////////////////////////////////////////
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bool
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AP_Compass_HMC5843::init()
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{
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int numAttempts = 0, good_count = 0;
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bool success = false;
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uint8_t calibration_gain = 0x20;
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uint16_t expected_x = 715;
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uint16_t expected_yz = 715;
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float gain_multiple = 1.0;
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hal.scheduler->delay(10);
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_i2c_sem = hal.i2c->get_semaphore();
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if (!_i2c_sem->take(HAL_SEMAPHORE_BLOCK_FOREVER)) {
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hal.scheduler->panic(PSTR("Failed to get HMC5843 semaphore"));
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}
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// determine if we are using 5843 or 5883L
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_base_config = 0;
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if (!write_register(ConfigRegA, SampleAveraging_8<<5 | DataOutputRate_75HZ<<2 | NormalOperation) ||
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!read_register(ConfigRegA, &_base_config)) {
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_healthy[0] = false;
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_i2c_sem->give();
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return false;
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}
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if ( _base_config == (SampleAveraging_8<<5 | DataOutputRate_75HZ<<2 | NormalOperation)) {
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// a 5883L supports the sample averaging config
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product_id = AP_COMPASS_TYPE_HMC5883L;
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calibration_gain = 0x60;
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/*
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note that the HMC5883 datasheet gives the x and y expected
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values as 766 and the z as 713. Experiments have shown the x
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axis is around 766, and the y and z closer to 713.
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*/
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expected_x = 766;
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expected_yz = 713;
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gain_multiple = 660.0 / 1090; // adjustment for runtime vs calibration gain
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} else if (_base_config == (NormalOperation | DataOutputRate_75HZ<<2)) {
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product_id = AP_COMPASS_TYPE_HMC5843;
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} else {
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// not behaving like either supported compass type
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_i2c_sem->give();
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return false;
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}
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calibration[0] = 0;
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calibration[1] = 0;
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calibration[2] = 0;
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while ( success == 0 && numAttempts < 25 && good_count < 5)
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{
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// record number of attempts at initialisation
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numAttempts++;
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// force positiveBias (compass should return 715 for all channels)
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if (!write_register(ConfigRegA, PositiveBiasConfig))
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continue; // compass not responding on the bus
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hal.scheduler->delay(50);
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// set gains
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if (!write_register(ConfigRegB, calibration_gain) ||
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!write_register(ModeRegister, SingleConversion))
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continue;
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// read values from the compass
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hal.scheduler->delay(50);
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if (!read_raw())
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continue; // we didn't read valid values
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hal.scheduler->delay(10);
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float cal[3];
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// hal.console->printf_P(PSTR("mag %d %d %d\n"), _mag_x, _mag_y, _mag_z);
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cal[0] = fabsf(expected_x / (float)_mag_x);
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cal[1] = fabsf(expected_yz / (float)_mag_y);
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cal[2] = fabsf(expected_yz / (float)_mag_z);
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// hal.console->printf_P(PSTR("cal=%.2f %.2f %.2f\n"), cal[0], cal[1], cal[2]);
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// we throw away the first two samples as the compass may
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// still be changing its state from the application of the
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// strap excitation. After that we accept values in a
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// reasonable range
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if (numAttempts > 2 &&
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cal[0] > 0.7f && cal[0] < 1.35f &&
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cal[1] > 0.7f && cal[1] < 1.35f &&
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cal[2] > 0.7f && cal[2] < 1.35f) {
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// hal.console->printf_P(PSTR("cal=%.2f %.2f %.2f good\n"), cal[0], cal[1], cal[2]);
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good_count++;
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calibration[0] += cal[0];
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calibration[1] += cal[1];
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calibration[2] += cal[2];
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}
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#if 0
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/* useful for debugging */
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hal.console->printf_P(PSTR("MagX: %d MagY: %d MagZ: %d\n"), (int)_mag_x, (int)_mag_y, (int)_mag_z);
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hal.console->printf_P(PSTR("CalX: %.2f CalY: %.2f CalZ: %.2f\n"), cal[0], cal[1], cal[2]);
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#endif
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}
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if (good_count >= 5) {
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/*
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The use of gain_multiple below is incorrect, as the gain
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difference between 2.5Ga mode and 1Ga mode is already taken
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into account by the expected_x and expected_yz values. We
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are not going to fix it however as it would mean all
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APM1/APM2 users redoing their compass calibration. The
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impact is that the values we report on APM1/APM2 are lower
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than they should be (by a multiple of about 0.6). This
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doesn't have any impact other than the learned compass
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offsets
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*/
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calibration[0] = calibration[0] * gain_multiple / good_count;
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calibration[1] = calibration[1] * gain_multiple / good_count;
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calibration[2] = calibration[2] * gain_multiple / good_count;
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success = true;
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} else {
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/* best guess */
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calibration[0] = 1.0;
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calibration[1] = 1.0;
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calibration[2] = 1.0;
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}
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// leave test mode
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if (!re_initialise()) {
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_i2c_sem->give();
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return false;
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}
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_i2c_sem->give();
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_initialised = true;
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// perform an initial read
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_healthy[0] = true;
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read();
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#if 0
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hal.console->printf_P(PSTR("CalX: %.2f CalY: %.2f CalZ: %.2f\n"),
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calibration[0], calibration[1], calibration[2]);
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#endif
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return success;
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}
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// Read Sensor data
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bool AP_Compass_HMC5843::read()
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{
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if (!_initialised) {
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// someone has tried to enable a compass for the first time
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// mid-flight .... we can't do that yet (especially as we won't
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// have the right orientation!)
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return false;
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}
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if (!_healthy[0]) {
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if (hal.scheduler->millis() < _retry_time) {
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return false;
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}
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if (!re_initialise()) {
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_retry_time = hal.scheduler->millis() + 1000;
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hal.i2c->setHighSpeed(false);
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return false;
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}
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}
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if (_accum_count == 0) {
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accumulate();
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if (!_healthy[0] || _accum_count == 0) {
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// try again in 1 second, and set I2c clock speed slower
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_retry_time = hal.scheduler->millis() + 1000;
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hal.i2c->setHighSpeed(false);
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return false;
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}
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}
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_field[0].x = _mag_x_accum * calibration[0] / _accum_count;
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_field[0].y = _mag_y_accum * calibration[1] / _accum_count;
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_field[0].z = _mag_z_accum * calibration[2] / _accum_count;
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_accum_count = 0;
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_mag_x_accum = _mag_y_accum = _mag_z_accum = 0;
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last_update = hal.scheduler->micros(); // record time of update
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// rotate to the desired orientation
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if (product_id == AP_COMPASS_TYPE_HMC5883L) {
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_field[0].rotate(ROTATION_YAW_90);
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}
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// apply default board orientation for this compass type. This is
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// a noop on most boards
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_field[0].rotate(MAG_BOARD_ORIENTATION);
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// add user selectable orientation
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_field[0].rotate((enum Rotation)_orientation[0].get());
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if (!_external[0]) {
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// and add in AHRS_ORIENTATION setting if not an external compass
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_field[0].rotate(_board_orientation);
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}
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_field[0] += _offset[0].get();
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// apply motor compensation
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if(_motor_comp_type != AP_COMPASS_MOT_COMP_DISABLED && _thr_or_curr != 0.0f) {
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_motor_offset[0] = _motor_compensation[0].get() * _thr_or_curr;
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_field[0] += _motor_offset[0];
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}else{
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_motor_offset[0].zero();
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}
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_healthy[0] = true;
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return true;
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}
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