mirror of https://github.com/ArduPilot/ardupilot
372 lines
13 KiB
C++
372 lines
13 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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This is an INS driver for the combination L3G4200D gyro and ADXL345 accelerometer.
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This combination is available as a cheap 10DOF sensor on ebay
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*/
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// ADXL345 Accelerometer http://www.analog.com/static/imported-files/data_sheets/ADXL345.pdf
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// L3G4200D gyro http://www.st.com/st-web-ui/static/active/en/resource/technical/document/datasheet/CD00265057.pdf
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#include <AP_HAL.h>
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#if CONFIG_HAL_BOARD == HAL_BOARD_LINUX || CONFIG_HAL_BOARD == HAL_BOARD_ERLE
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#include <AP_Math.h>
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#include "AP_InertialSensor_L3G4200D.h"
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#include <stdio.h>
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#include <unistd.h>
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const extern AP_HAL::HAL& hal;
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///////
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/// Accelerometer ADXL345 register definitions
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#define ADXL345_ACCELEROMETER_ADDRESS 0x53
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#define ADXL345_ACCELEROMETER_XL345_DEVID 0xe5
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#define ADXL345_ACCELEROMETER_ADXLREG_BW_RATE 0x2c
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#define ADXL345_ACCELEROMETER_ADXLREG_POWER_CTL 0x2d
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#define ADXL345_ACCELEROMETER_ADXLREG_DATA_FORMAT 0x31
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#define ADXL345_ACCELEROMETER_ADXLREG_DEVID 0x00
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#define ADXL345_ACCELEROMETER_ADXLREG_DATAX0 0x32
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#define ADXL345_ACCELEROMETER_ADXLREG_FIFO_CTL 0x38
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#define ADXL345_ACCELEROMETER_ADXLREG_FIFO_CTL_STREAM 0x9F
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#define ADXL345_ACCELEROMETER_ADXLREG_FIFO_STATUS 0x39
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// ADXL345 accelerometer scaling
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// Result will be scaled to 1m/s/s
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// ADXL345 in Full resolution mode (any g scaling) is 256 counts/g, so scale by 9.81/256 = 0.038320312
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#define ADXL345_ACCELEROMETER_SCALE_M_S (GRAVITY_MSS / 256.0f)
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/// Gyro ITG3205 register definitions
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#define L3G4200D_I2C_ADDRESS 0x69
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#define L3G4200D_REG_WHO_AM_I 0x0f
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#define L3G4200D_REG_WHO_AM_I_VALUE 0xd3
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#define L3G4200D_REG_CTRL_REG1 0x20
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#define L3G4200D_REG_CTRL_REG1_DRBW_800_110 0xf0
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#define L3G4200D_REG_CTRL_REG1_PD 0x08
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#define L3G4200D_REG_CTRL_REG1_XYZ_ENABLE 0x07
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#define L3G4200D_REG_CTRL_REG4 0x23
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#define L3G4200D_REG_CTRL_REG4_FS_2000 0x30
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#define L3G4200D_REG_CTRL_REG5 0x24
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#define L3G4200D_REG_CTRL_REG5_FIFO_EN 0x40
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#define L3G4200D_REG_FIFO_CTL 0x2e
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#define L3G4200D_REG_FIFO_CTL_STREAM 0x40
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#define L3G4200D_REG_FIFO_SRC 0x2f
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#define L3G4200D_REG_FIFO_SRC_ENTRIES_MASK 0x1f
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#define L3G4200D_REG_FIFO_SRC_EMPTY 0x20
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#define L3G4200D_REG_FIFO_SRC_OVERRUN 0x40
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#define L3G4200D_REG_XL 0x28
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// this bit is ORd into the register to enable auto-increment mode
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#define L3G4200D_REG_AUTO_INCREMENT 0x80
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// L3G4200D Gyroscope scaling
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// running at 2000 DPS full range, 16 bit signed data, datasheet
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// specifies 70 mdps per bit
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#define L3G4200D_GYRO_SCALE_R_S (DEG_TO_RAD * 70.0f * 0.001f)
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// constructor
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AP_InertialSensor_L3G4200D::AP_InertialSensor_L3G4200D() :
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AP_InertialSensor(),
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_accel_filter_x(800, 10),
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_accel_filter_y(800, 10),
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_accel_filter_z(800, 10),
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_gyro_filter_x(800, 10),
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_gyro_filter_y(800, 10),
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_gyro_filter_z(800, 10)
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{}
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uint16_t AP_InertialSensor_L3G4200D::_init_sensor( Sample_rate sample_rate )
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{
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switch (sample_rate) {
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case RATE_50HZ:
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_default_filter_hz = 10;
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_sample_period_usec = (1000*1000) / 50;
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_gyro_samples_needed = 16;
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break;
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case RATE_100HZ:
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_default_filter_hz = 20;
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_sample_period_usec = (1000*1000) / 100;
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_gyro_samples_needed = 8;
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break;
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case RATE_200HZ:
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default:
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_default_filter_hz = 20;
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_sample_period_usec = (1000*1000) / 200;
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_gyro_samples_needed = 4;
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break;
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}
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// get pointer to i2c bus semaphore
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AP_HAL::Semaphore* i2c_sem = hal.i2c->get_semaphore();
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// take i2c bus sempahore
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if (!i2c_sem->take(HAL_SEMAPHORE_BLOCK_FOREVER))
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return false;
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// Init the accelerometer
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uint8_t data = 0;
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hal.i2c->readRegister(ADXL345_ACCELEROMETER_ADDRESS, ADXL345_ACCELEROMETER_ADXLREG_DEVID, &data);
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if (data != ADXL345_ACCELEROMETER_XL345_DEVID) {
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hal.scheduler->panic(PSTR("AP_InertialSensor_L3G4200D: could not find ADXL345 accelerometer sensor"));
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}
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hal.i2c->writeRegister(ADXL345_ACCELEROMETER_ADDRESS, ADXL345_ACCELEROMETER_ADXLREG_POWER_CTL, 0x00);
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hal.scheduler->delay(5);
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hal.i2c->writeRegister(ADXL345_ACCELEROMETER_ADDRESS, ADXL345_ACCELEROMETER_ADXLREG_POWER_CTL, 0xff);
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hal.scheduler->delay(5);
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// Measure mode:
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hal.i2c->writeRegister(ADXL345_ACCELEROMETER_ADDRESS, ADXL345_ACCELEROMETER_ADXLREG_POWER_CTL, 0x08);
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hal.scheduler->delay(5);
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// Full resolution, 8g:
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// Caution, this must agree with ADXL345_ACCELEROMETER_SCALE_1G
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// In full resoution mode, the scale factor need not change
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hal.i2c->writeRegister(ADXL345_ACCELEROMETER_ADDRESS, ADXL345_ACCELEROMETER_ADXLREG_DATA_FORMAT, 0x08);
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hal.scheduler->delay(5);
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// Normal power, 800Hz Output Data Rate, 400Hz bandwidth:
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hal.i2c->writeRegister(ADXL345_ACCELEROMETER_ADDRESS, ADXL345_ACCELEROMETER_ADXLREG_BW_RATE, 0x0d);
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hal.scheduler->delay(5);
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// enable FIFO in stream mode. This will allow us to read the accelerometers much less frequently
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hal.i2c->writeRegister(ADXL345_ACCELEROMETER_ADDRESS,
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ADXL345_ACCELEROMETER_ADXLREG_FIFO_CTL,
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ADXL345_ACCELEROMETER_ADXLREG_FIFO_CTL_STREAM);
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// Init the Gyro
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// Expect to read the right 'WHO_AM_I' value
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hal.i2c->readRegister(L3G4200D_I2C_ADDRESS, L3G4200D_REG_WHO_AM_I, &data);
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if (data != L3G4200D_REG_WHO_AM_I_VALUE)
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hal.scheduler->panic(PSTR("AP_InertialSensor_L3G4200D: could not find L3G4200D gyro sensor"));
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// setup for 800Hz sampling with 110Hz filter
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hal.i2c->writeRegister(L3G4200D_I2C_ADDRESS,
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L3G4200D_REG_CTRL_REG1,
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L3G4200D_REG_CTRL_REG1_DRBW_800_110 |
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L3G4200D_REG_CTRL_REG1_PD |
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L3G4200D_REG_CTRL_REG1_XYZ_ENABLE);
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hal.scheduler->delay(1);
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hal.i2c->writeRegister(L3G4200D_I2C_ADDRESS,
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L3G4200D_REG_CTRL_REG1,
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L3G4200D_REG_CTRL_REG1_DRBW_800_110 |
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L3G4200D_REG_CTRL_REG1_PD |
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L3G4200D_REG_CTRL_REG1_XYZ_ENABLE);
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hal.scheduler->delay(1);
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hal.i2c->writeRegister(L3G4200D_I2C_ADDRESS,
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L3G4200D_REG_CTRL_REG1,
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L3G4200D_REG_CTRL_REG1_DRBW_800_110 |
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L3G4200D_REG_CTRL_REG1_PD |
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L3G4200D_REG_CTRL_REG1_XYZ_ENABLE);
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hal.scheduler->delay(1);
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// setup for 2000 degrees/sec full range
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hal.i2c->writeRegister(L3G4200D_I2C_ADDRESS,
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L3G4200D_REG_CTRL_REG4,
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L3G4200D_REG_CTRL_REG4_FS_2000);
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hal.scheduler->delay(1);
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// enable FIFO
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hal.i2c->writeRegister(L3G4200D_I2C_ADDRESS,
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L3G4200D_REG_CTRL_REG5,
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L3G4200D_REG_CTRL_REG5_FIFO_EN);
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hal.scheduler->delay(1);
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// enable FIFO in stream mode. This will allow us to read the gyros much less frequently
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hal.i2c->writeRegister(L3G4200D_I2C_ADDRESS,
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L3G4200D_REG_FIFO_CTL,
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L3G4200D_REG_FIFO_CTL_STREAM);
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hal.scheduler->delay(1);
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// Set up the filter desired
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_set_filter_frequency(_mpu6000_filter);
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// give back i2c semaphore
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i2c_sem->give();
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// start the timer process to read samples
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hal.scheduler->register_timer_process(AP_HAL_MEMBERPROC(&AP_InertialSensor_L3G4200D::_accumulate));
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return AP_PRODUCT_ID_L3G4200D;
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}
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/*
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set the filter frequency
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*/
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void AP_InertialSensor_L3G4200D::_set_filter_frequency(uint8_t filter_hz)
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{
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if (filter_hz == 0)
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filter_hz = _default_filter_hz;
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_accel_filter_x.set_cutoff_frequency(800, filter_hz);
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_accel_filter_y.set_cutoff_frequency(800, filter_hz);
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_accel_filter_z.set_cutoff_frequency(800, filter_hz);
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_gyro_filter_x.set_cutoff_frequency(800, filter_hz);
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_gyro_filter_y.set_cutoff_frequency(800, filter_hz);
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_gyro_filter_z.set_cutoff_frequency(800, filter_hz);
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}
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/*================ AP_INERTIALSENSOR PUBLIC INTERFACE ==================== */
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bool AP_InertialSensor_L3G4200D::update(void)
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{
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if (!wait_for_sample(1000)) {
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return false;
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}
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Vector3f accel_scale = _accel_scale[0].get();
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_previous_accel[0] = _accel[0];
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hal.scheduler->suspend_timer_procs();
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_accel[0] = _accel_filtered;
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_gyro[0] = _gyro_filtered;
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_gyro_samples_available = 0;
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hal.scheduler->resume_timer_procs();
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// add offsets and rotation
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_accel[0].rotate(_board_orientation);
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// Adjust for chip scaling to get m/s/s
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_accel[0] *= ADXL345_ACCELEROMETER_SCALE_M_S;
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// Now the calibration scale factor
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_accel[0].x *= accel_scale.x;
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_accel[0].y *= accel_scale.y;
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_accel[0].z *= accel_scale.z;
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_accel[0] -= _accel_offset[0];
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_gyro[0].rotate(_board_orientation);
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// Adjust for chip scaling to get radians/sec
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_gyro[0] *= L3G4200D_GYRO_SCALE_R_S;
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_gyro[0] -= _gyro_offset[0];
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if (_last_filter_hz != _mpu6000_filter) {
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_set_filter_frequency(_mpu6000_filter);
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_last_filter_hz = _mpu6000_filter;
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}
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return true;
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}
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float AP_InertialSensor_L3G4200D::get_delta_time(void) const
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{
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return _sample_period_usec * 1.0e-6f;
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}
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float AP_InertialSensor_L3G4200D::get_gyro_drift_rate(void)
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{
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// 0.5 degrees/second/minute (a guess)
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return ToRad(0.5/60);
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}
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// Accumulate values from accels and gyros
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void AP_InertialSensor_L3G4200D::_accumulate(void)
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{
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// get pointer to i2c bus semaphore
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AP_HAL::Semaphore* i2c_sem = hal.i2c->get_semaphore();
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// take i2c bus sempahore
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if (!i2c_sem->take_nonblocking())
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return;
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// Read accelerometer FIFO to find out how many samples are available
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uint8_t num_samples_available;
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uint8_t fifo_status = 0;
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hal.i2c->readRegister(ADXL345_ACCELEROMETER_ADDRESS,
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ADXL345_ACCELEROMETER_ADXLREG_FIFO_STATUS,
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&fifo_status);
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num_samples_available = fifo_status & 0x3F;
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// read the samples and apply the filter
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for (uint8_t i=0; i<num_samples_available; i++) {
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int16_t buffer[3];
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if (hal.i2c->readRegisters(ADXL345_ACCELEROMETER_ADDRESS,
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ADXL345_ACCELEROMETER_ADXLREG_DATAX0, sizeof(buffer), (uint8_t *)buffer) == 0) {
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_accel_filtered = Vector3f(_accel_filter_x.apply(buffer[0]),
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_accel_filter_y.apply(-buffer[1]),
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_accel_filter_z.apply(-buffer[2]));
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}
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}
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// Read gyro FIFO status
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fifo_status = 0;
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hal.i2c->readRegister(L3G4200D_I2C_ADDRESS,
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L3G4200D_REG_FIFO_SRC,
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&fifo_status);
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if (fifo_status & L3G4200D_REG_FIFO_SRC_OVERRUN) {
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// FIFO is full
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num_samples_available = 32;
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} else if (fifo_status & L3G4200D_REG_FIFO_SRC_EMPTY) {
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// FIFO is empty
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num_samples_available = 0;
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} else {
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// FIFO is partly full
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num_samples_available = fifo_status & L3G4200D_REG_FIFO_SRC_ENTRIES_MASK;
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}
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if (num_samples_available > 0) {
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// read all the entries in one go, using AUTO_INCREMENT. This saves a lot of time on I2C setup
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int16_t buffer[num_samples_available][3];
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if (hal.i2c->readRegisters(L3G4200D_I2C_ADDRESS, L3G4200D_REG_XL | L3G4200D_REG_AUTO_INCREMENT,
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sizeof(buffer), (uint8_t *)&buffer[0][0]) == 0) {
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for (uint8_t i=0; i<num_samples_available; i++) {
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_gyro_filtered = Vector3f(_gyro_filter_x.apply(buffer[i][0]),
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_gyro_filter_y.apply(-buffer[i][1]),
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_gyro_filter_z.apply(-buffer[i][2]));
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_gyro_samples_available++;
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}
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}
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}
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// give back i2c semaphore
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i2c_sem->give();
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}
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bool AP_InertialSensor_L3G4200D::_sample_available(void)
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{
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return (_gyro_samples_available >= _gyro_samples_needed);
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}
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bool AP_InertialSensor_L3G4200D::wait_for_sample(uint16_t timeout_ms)
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{
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if (_sample_available()) {
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_last_sample_time = hal.scheduler->micros();
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return true;
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}
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uint32_t start = hal.scheduler->millis();
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while ((hal.scheduler->millis() - start) < timeout_ms) {
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hal.scheduler->delay_microseconds(100);
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_accumulate();
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if (_sample_available()) {
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_last_sample_time = hal.scheduler->micros();
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return true;
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}
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}
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return false;
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}
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#endif // CONFIG_HAL_BOARD
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