2011-02-14 00:42:37 -04:00
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// -*- tab-width: 4; Mode: C++; c-basic-offset: 4; indent-tabs-mode: nil -*-
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2010-12-28 19:41:00 -04:00
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//
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//
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// AP_IMU.cpp - IMU Sensor Library for Ardupilot Mega
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2011-02-14 00:42:37 -04:00
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// Code by Michael Smith, Doug Weibel, Jordi Muñoz and Jose Julio. DIYDrones.com
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2010-12-28 19:41:00 -04:00
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//
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// This library works with the ArduPilot Mega and "Oilpan"
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//
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// This library is free software; you can redistribute it and/or
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// modify it under the terms of the GNU Lesser General Public
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// License as published by the Free Software Foundation; either
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// version 2.1 of the License, or (at your option) any later version.
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//
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/// @file AP_IMU.h
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/// @brief IMU driver for the APM oilpan
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#include <FastSerial.h>
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#include <AP_Common.h>
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#include <avr/eeprom.h>
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#include "AP_IMU_Oilpan.h"
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2011-02-14 00:42:37 -04:00
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// XXX secret knowledge about the APM/oilpan wiring
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//
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#define A_LED_PIN 37
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#define C_LED_PIN 35
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2010-12-28 19:41:00 -04:00
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// Sensors: GYROX, GYROY, GYROZ, ACCELX, ACCELY, ACCELZ
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2011-02-14 00:42:37 -04:00
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const uint8_t AP_IMU_Oilpan::_sensors[6] = { 1, 2, 0, 4, 5, 6}; // Channel assignments on the APM oilpan
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const int8_t AP_IMU_Oilpan::_sensor_signs[6] = { 1,-1,-1, 1,-1,-1}; // Channel orientation vs. normal
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2010-12-28 19:41:00 -04:00
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// Temp compensation curve constants
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// These must be produced by measuring data and curve fitting
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// [X/Y/Z gyro][A/B/C or 0 order/1st order/2nd order constants]
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2011-02-14 00:42:37 -04:00
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//
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const float AP_IMU_Oilpan::_gyro_temp_curve[3][3] = {
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2011-02-25 13:49:31 -04:00
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{1658,0,0}, // Values to use if no temp compensation data available
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{1658,0,0}, // Based on average values for 20 sample boards
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{1658,0,0}
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2011-02-14 00:42:37 -04:00
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};
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2010-12-28 19:41:00 -04:00
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void
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2011-07-31 19:34:25 -03:00
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AP_IMU_Oilpan::init(Start_style style, void (*callback)(unsigned long t))
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2010-12-28 19:41:00 -04:00
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{
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2011-02-14 00:42:37 -04:00
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// if we are warm-starting, load the calibration data from EEPROM and go
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//
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if (WARM_START == style) {
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_sensor_cal.load();
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} else {
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// do cold-start calibration for both accel and gyro
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2011-07-31 19:34:25 -03:00
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_init_gyro(callback);
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_init_accel(callback);
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2011-02-14 00:42:37 -04:00
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// save calibration
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_sensor_cal.save();
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}
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2010-12-28 19:41:00 -04:00
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}
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/**************************************************/
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void
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2011-07-31 19:34:25 -03:00
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AP_IMU_Oilpan::init_gyro(void (*callback)(unsigned long t))
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2011-02-14 00:42:37 -04:00
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{
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2011-07-31 19:34:25 -03:00
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_init_gyro(callback);
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2011-02-14 00:42:37 -04:00
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_sensor_cal.save();
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}
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void
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2011-07-31 19:34:25 -03:00
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AP_IMU_Oilpan::_init_gyro(void (*callback)(unsigned long t))
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2010-12-28 19:41:00 -04:00
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{
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int flashcount = 0;
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int tc_temp;
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2011-02-14 00:42:37 -04:00
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float adc_in;
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2011-02-25 13:49:31 -04:00
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float prev[3] = {0,0,0};
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float total_change;
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float max_offset;
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2010-12-28 19:41:00 -04:00
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// cold start
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tc_temp = _adc->Ch(_gyro_temp_ch);
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callback(500);
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2011-02-25 13:49:31 -04:00
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Serial.printf_P(PSTR("Init Gyro"));
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2010-12-28 19:41:00 -04:00
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2011-02-13 19:25:04 -04:00
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for(int c = 0; c < 25; c++){ // Mostly we are just flashing the LED's here to tell the user to keep the IMU still
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2010-12-28 19:41:00 -04:00
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digitalWrite(A_LED_PIN, LOW);
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digitalWrite(C_LED_PIN, HIGH);
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2011-07-31 19:34:25 -03:00
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callback(20);
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2010-12-28 19:41:00 -04:00
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for (int i = 0; i < 6; i++)
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2011-02-14 00:42:37 -04:00
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adc_in = _adc->Ch(_sensors[i]);
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2011-02-20 19:10:18 -04:00
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2010-12-28 19:41:00 -04:00
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digitalWrite(A_LED_PIN, HIGH);
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digitalWrite(C_LED_PIN, LOW);
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2011-07-31 19:34:25 -03:00
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callback(20);
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2010-12-28 19:41:00 -04:00
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}
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2011-04-16 01:55:32 -03:00
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for (int j = 0; j <= 2; j++)
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_sensor_cal[j] = 500; // Just a large value to load prev[j] the first time
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2011-02-25 13:49:31 -04:00
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do {
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for (int j = 0; j <= 2; j++){
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2011-04-16 01:55:32 -03:00
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prev[j] = _sensor_cal[j];
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adc_in = _adc->Ch(_sensors[j]);
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adc_in -= _sensor_compensation(j, tc_temp);
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2011-02-25 13:49:31 -04:00
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_sensor_cal[j] = adc_in;
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2010-12-28 19:41:00 -04:00
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}
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2011-02-25 13:49:31 -04:00
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for(int i = 0; i < 50; i++){
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for (int j = 0; j < 3; j++){
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adc_in = _adc->Ch(_sensors[j]);
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// Subtract temp compensated typical gyro bias
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adc_in -= _sensor_compensation(j, tc_temp);
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// filter
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_sensor_cal[j] = _sensor_cal[j] * 0.9 + adc_in * 0.1;
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}
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2011-07-31 19:34:25 -03:00
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callback(20);
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2011-02-25 13:49:31 -04:00
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if(flashcount == 5) {
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Serial.printf_P(PSTR("*"));
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digitalWrite(A_LED_PIN, LOW);
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digitalWrite(C_LED_PIN, HIGH);
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}
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if(flashcount >= 10) {
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flashcount = 0;
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digitalWrite(C_LED_PIN, LOW);
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2011-04-16 01:55:32 -03:00
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digitalWrite(A_LED_PIN, HIGH);
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2011-02-25 13:49:31 -04:00
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}
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flashcount++;
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2010-12-28 19:41:00 -04:00
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}
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2011-04-16 01:55:32 -03:00
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total_change = fabs(prev[0] - _sensor_cal[0]) + fabs(prev[1] - _sensor_cal[1]) +fabs(prev[2] - _sensor_cal[2]);
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max_offset = (_sensor_cal[0] > _sensor_cal[1]) ? _sensor_cal[0] : _sensor_cal[1];
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max_offset = (max_offset > _sensor_cal[2]) ? max_offset : _sensor_cal[2];
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2011-07-31 19:34:25 -03:00
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callback(500);
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2011-02-25 13:49:31 -04:00
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} while ( total_change > _gyro_total_cal_change || max_offset > _gyro_max_cal_offset);
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2010-12-28 19:41:00 -04:00
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}
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2011-02-18 23:57:19 -04:00
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void
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AP_IMU_Oilpan::save()
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{
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_sensor_cal.save();
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}
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2011-02-14 00:42:37 -04:00
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void
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2011-07-31 19:34:25 -03:00
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AP_IMU_Oilpan::init_accel(void (*callback)(unsigned long t))
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2011-02-14 00:42:37 -04:00
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{
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2011-07-31 19:34:25 -03:00
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_init_accel(callback);
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2011-02-14 00:42:37 -04:00
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_sensor_cal.save();
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}
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2010-12-28 19:41:00 -04:00
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void
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2011-07-31 19:34:25 -03:00
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AP_IMU_Oilpan::_init_accel(void (*callback)(unsigned long t))
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2010-12-28 19:41:00 -04:00
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{
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int flashcount = 0;
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2011-02-14 00:42:37 -04:00
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float adc_in;
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2011-02-25 13:49:31 -04:00
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float prev[6] = {0,0,0};
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float total_change;
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float max_offset;
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2010-12-28 19:41:00 -04:00
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// cold start
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2011-07-31 19:34:25 -03:00
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callback(500);
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2010-12-28 19:41:00 -04:00
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2011-02-25 13:49:31 -04:00
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Serial.printf_P(PSTR("Init Accel"));
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2010-12-28 19:41:00 -04:00
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2011-02-25 13:49:31 -04:00
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for (int j=3; j<=5; j++) _sensor_cal[j] = 500; // Just a large value to load prev[j] the first time
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2011-04-16 01:55:32 -03:00
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2011-02-25 13:49:31 -04:00
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do {
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for (int j = 3; j <= 5; j++){
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prev[j] = _sensor_cal[j];
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adc_in = _adc->Ch(_sensors[j]);
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adc_in -= _sensor_compensation(j, 0); // temperature ignored
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_sensor_cal[j] = adc_in;
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}
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2010-12-28 19:41:00 -04:00
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2011-02-25 13:49:31 -04:00
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for(int i = 0; i < 50; i++){ // We take some readings...
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2010-12-28 19:41:00 -04:00
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2011-07-31 19:34:25 -03:00
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callback(20);
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2010-12-28 19:41:00 -04:00
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2011-02-25 13:49:31 -04:00
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for (int j = 3; j < 6; j++){
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adc_in = _adc->Ch(_sensors[j]);
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adc_in -= _sensor_compensation(j, 0); // temperature ignored
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_sensor_cal[j] = _sensor_cal[j] * 0.9 + adc_in * 0.1;
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}
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2010-12-28 19:41:00 -04:00
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2011-02-25 13:49:31 -04:00
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if(flashcount == 5) {
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Serial.printf_P(PSTR("*"));
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digitalWrite(A_LED_PIN, LOW);
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digitalWrite(C_LED_PIN, HIGH);
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}
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2010-12-28 19:41:00 -04:00
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2011-02-25 13:49:31 -04:00
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if(flashcount >= 10) {
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flashcount = 0;
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digitalWrite(C_LED_PIN, LOW);
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digitalWrite(A_LED_PIN, HIGH);
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}
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flashcount++;
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2010-12-28 19:41:00 -04:00
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}
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2011-02-25 13:49:31 -04:00
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// null gravity from the Z accel
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_sensor_cal[5] += _gravity * _sensor_signs[5];
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2011-04-16 01:55:32 -03:00
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2011-02-25 13:49:31 -04:00
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total_change = fabs(prev[3] - _sensor_cal[3]) + fabs(prev[4] - _sensor_cal[4]) +fabs(prev[5] - _sensor_cal[5]);
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max_offset = (_sensor_cal[3] > _sensor_cal[4]) ? _sensor_cal[3] : _sensor_cal[4];
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max_offset = (max_offset > _sensor_cal[5]) ? max_offset : _sensor_cal[5];
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2011-07-31 19:34:25 -03:00
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callback(500);
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2011-02-25 13:49:31 -04:00
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} while ( total_change > _accel_total_cal_change || max_offset > _accel_max_cal_offset);
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2011-04-16 01:55:32 -03:00
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2011-02-25 13:49:31 -04:00
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Serial.printf_P(PSTR(" "));
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2010-12-28 19:41:00 -04:00
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}
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/**************************************************/
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// Returns the temperature compensated raw gyro value
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//---------------------------------------------------
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float
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2011-02-14 00:42:37 -04:00
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AP_IMU_Oilpan::_sensor_compensation(uint8_t channel, int temperature) const
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2010-12-28 19:41:00 -04:00
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{
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2011-02-14 00:42:37 -04:00
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// do gyro temperature compensation
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if (channel < 3) {
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2010-12-28 19:41:00 -04:00
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2011-06-26 03:23:22 -03:00
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return 1658;
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/*
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2011-02-14 00:42:37 -04:00
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return _gyro_temp_curve[channel][0] +
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_gyro_temp_curve[channel][1] * temperature +
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_gyro_temp_curve[channel][2] * temperature * temperature;
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2011-06-26 03:23:22 -03:00
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//*/
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2011-02-14 00:42:37 -04:00
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}
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// do fixed-offset accelerometer compensation
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2011-02-25 13:49:31 -04:00
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return 2041; // Average raw value from a 20 board sample
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2010-12-28 19:41:00 -04:00
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}
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float
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2011-02-14 00:42:37 -04:00
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AP_IMU_Oilpan::_sensor_in(uint8_t channel, int temperature)
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2010-12-28 19:41:00 -04:00
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{
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2011-02-14 00:42:37 -04:00
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float adc_in;
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// get the compensated sensor value
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//
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adc_in = _adc->Ch(_sensors[channel]) - _sensor_compensation(channel, temperature);
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// adjust for sensor sign and apply calibration offset
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//
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if (_sensor_signs[channel] < 0) {
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adc_in = _sensor_cal[channel] - adc_in;
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} else {
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adc_in = adc_in - _sensor_cal[channel];
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}
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// constrain sensor readings to the sensible range
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//
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if (fabs(adc_in) > _adc_constraint) {
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adc_constraints++; // We keep track of the number of times
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adc_in = constrain(adc_in, -_adc_constraint, _adc_constraint); // Throw out nonsensical values
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}
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return adc_in;
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2010-12-28 19:41:00 -04:00
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}
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2011-02-14 00:42:37 -04:00
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2010-12-28 19:41:00 -04:00
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bool
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AP_IMU_Oilpan::update(void)
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{
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int tc_temp = _adc->Ch(_gyro_temp_ch);
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2011-02-14 00:42:37 -04:00
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// convert corrected gyro readings to delta acceleration
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//
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_gyro.x = ToRad(_gyro_gain_x) * _sensor_in(0, tc_temp);
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_gyro.y = ToRad(_gyro_gain_y) * _sensor_in(1, tc_temp);
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_gyro.z = ToRad(_gyro_gain_z) * _sensor_in(2, tc_temp);
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2010-12-28 19:41:00 -04:00
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2011-02-14 00:42:37 -04:00
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// convert corrected accelerometer readings to acceleration
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//
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_accel.x = _accel_scale * _sensor_in(3, tc_temp);
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_accel.y = _accel_scale * _sensor_in(4, tc_temp);
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_accel.z = _accel_scale * _sensor_in(5, tc_temp);
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2010-12-28 19:41:00 -04:00
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2011-07-08 00:58:19 -03:00
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_accel_filtered.x = _accel_filtered.x * .98 + _accel.x * .02;
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_accel_filtered.y = _accel_filtered.y * .98 + _accel.y * .02;
|
|
|
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_accel_filtered.z = _accel_filtered.z * .98 + _accel.z * .02;
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|
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2011-02-14 00:42:37 -04:00
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// always updated
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|
|
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return true;
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2010-12-28 19:41:00 -04:00
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}
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