ardupilot/libraries/APO/AP_Navigator.h

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2011-09-28 21:51:12 -03:00
/*
* AP_Navigator.h
* Copyright (C) James Goppert 2010 <james.goppert@gmail.com>
*
* This file is free software: you can redistribute it and/or modify it
* under the terms of the GNU General Public License as published by the
* Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* This file is distributed in the hope that it will be useful, but
* WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
* See the GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License along
* with this program. If not, see <http://www.gnu.org/licenses/>.
*/
#ifndef AP_Navigator_H
#define AP_Navigator_H
#include "AP_HardwareAbstractionLayer.h"
#include "../AP_DCM/AP_DCM.h"
#include "../AP_Math/AP_Math.h"
#include "../AP_Compass/AP_Compass.h"
#include "AP_MavlinkCommand.h"
#include "constants.h"
#include "AP_Var_keys.h"
#include "../AP_RangeFinder/AP_RangeFinder.h"
#include "../AP_IMU/AP_IMU.h"
namespace apo {
/// Navigator class
class AP_Navigator {
public:
AP_Navigator(AP_HardwareAbstractionLayer * hal) :
_hal(hal), _timeStamp(0), _roll(0), _rollRate(0), _pitch(0),
_pitchRate(0), _yaw(0), _yawRate(0), _airSpeed(0),
_groundSpeed(0), _vD(0), _lat_degInt(0),
_lon_degInt(0), _alt_intM(0) {
}
virtual void calibrate() {
}
virtual void updateFast(float dt) = 0;
virtual void updateSlow(float dt) = 0;
float getPD() const {
return AP_MavlinkCommand::home.getPD(getAlt_intM());
}
float getPE() const {
return AP_MavlinkCommand::home.getPE(getLat_degInt(), getLon_degInt());
}
float getPN() const {
return AP_MavlinkCommand::home.getPN(getLat_degInt(), getLon_degInt());
}
void setPD(float _pD) {
setAlt(AP_MavlinkCommand::home.getAlt(_pD));
}
void setPE(float _pE) {
setLat(AP_MavlinkCommand::home.getLat(_pE));
}
void setPN(float _pN) {
setLon(AP_MavlinkCommand::home.getLon(_pN));
}
float getAirSpeed() const {
return _airSpeed;
}
int32_t getAlt_intM() const {
return _alt_intM;
}
float getAlt() const {
return _alt_intM / scale_m;
}
void setAlt(float _alt) {
this->_alt_intM = _alt * scale_m;
}
float getLat() const {
//Serial.print("getLatfirst");
//Serial.println(_lat_degInt * degInt2Rad);
return _lat_degInt * degInt2Rad;
}
void setLat(float _lat) {
//Serial.print("setLatfirst");
//Serial.println(_lat * rad2DegInt);
setLat_degInt(_lat*rad2DegInt);
}
float getLon() const {
return _lon_degInt * degInt2Rad;
}
void setLon(float _lon) {
this->_lon_degInt = _lon * rad2DegInt;
}
float getVD() const {
return _vD;
}
float getVE() const {
return sin(getYaw()) * getGroundSpeed();
}
float getGroundSpeed() const {
return _groundSpeed;
}
int32_t getLat_degInt() const {
//Serial.print("getLat_degInt");
//Serial.println(_lat_degInt);
return _lat_degInt;
}
int32_t getLon_degInt() const {
return _lon_degInt;
}
float getVN() const {
return cos(getYaw()) * getGroundSpeed();
}
float getPitch() const {
return _pitch;
}
float getPitchRate() const {
return _pitchRate;
}
float getRoll() const {
return _roll;
}
float getRollRate() const {
return _rollRate;
}
float getYaw() const {
return _yaw;
}
float getYawRate() const {
return _yawRate;
}
void setAirSpeed(float airSpeed) {
_airSpeed = airSpeed;
}
void setAlt_intM(int32_t alt_intM) {
_alt_intM = alt_intM;
}
void setVD(float vD) {
_vD = vD;
}
void setGroundSpeed(float groundSpeed) {
_groundSpeed = groundSpeed;
}
void setLat_degInt(int32_t lat_degInt) {
_lat_degInt = lat_degInt;
//Serial.print("setLat_degInt");
//Serial.println(_lat_degInt);
}
void setLon_degInt(int32_t lon_degInt) {
_lon_degInt = lon_degInt;
}
void setPitch(float pitch) {
_pitch = pitch;
}
void setPitchRate(float pitchRate) {
_pitchRate = pitchRate;
}
void setRoll(float roll) {
_roll = roll;
}
void setRollRate(float rollRate) {
_rollRate = rollRate;
}
void setYaw(float yaw) {
_yaw = yaw;
}
void setYawRate(float yawRate) {
_yawRate = yawRate;
}
void setTimeStamp(int32_t timeStamp) {
_timeStamp = timeStamp;
}
int32_t getTimeStamp() const {
return _timeStamp;
}
protected:
AP_HardwareAbstractionLayer * _hal;
private:
int32_t _timeStamp; // micros clock
float _roll; // rad
float _rollRate; //rad/s
float _pitch; // rad
float _pitchRate; // rad/s
float _yaw; // rad
float _yawRate; // rad/s
float _airSpeed; // m/s
float _groundSpeed; // m/s
float _vD; // m/s
int32_t _lat_degInt; // deg / 1e7
int32_t _lon_degInt; // deg / 1e7
int32_t _alt_intM; // meters / 1e3
};
class DcmNavigator: public AP_Navigator {
private:
/**
* Sensors
*/
RangeFinder * _rangeFinderDown;
AP_DCM * _dcm;
IMU * _imu;
uint16_t _imuOffsetAddress;
public:
DcmNavigator(AP_HardwareAbstractionLayer * hal) :
AP_Navigator(hal), _dcm(), _imuOffsetAddress(0) {
// if orientation equal to front, store as front
/**
* rangeFinder<direction> is assigned values based on orientation which
* is specified in ArduPilotOne.pde.
*/
for (uint8_t i = 0; i < _hal-> rangeFinders.getSize(); i++) {
if (_hal->rangeFinders[i] == NULL)
continue;
if (_hal->rangeFinders[i]->orientation_x == 0
&& _hal->rangeFinders[i]->orientation_y == 0
&& _hal->rangeFinders[i]->orientation_z == 1)
_rangeFinderDown = _hal->rangeFinders[i];
}
if (_hal->getMode() == MODE_LIVE) {
if (_hal->adc)
_hal->imu = new AP_IMU_Oilpan(_hal->adc, k_sensorCalib);
if (_hal->imu)
_dcm = new AP_DCM(_hal->imu, _hal->gps, _hal->compass);
if (_hal->compass) {
_dcm->set_compass(_hal->compass);
}
}
}
virtual void calibrate() {
AP_Navigator::calibrate();
// TODO: handle cold/warm restart
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if (_hal->imu) {
_hal->imu->init(IMU::COLD_START,delay);
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}
}
virtual void updateFast(float dt) {
if (_hal->getMode() != MODE_LIVE)
return;
setTimeStamp(micros()); // if running in live mode, record new time stamp
//_hal->debug->println_P(PSTR("nav loop"));
/**
* The altitued is read off the barometer by implementing the following formula:
* altitude (in m) = 44330*(1-(p/po)^(1/5.255)),
* where, po is pressure in Pa at sea level (101325 Pa).
* See http://www.sparkfun.com/tutorials/253 or type this formula
* in a search engine for more information.
* altInt contains the altitude in meters.
*/
if (_hal->baro) {
if (_rangeFinderDown != NULL && _rangeFinderDown->distance <= 695)
setAlt(_rangeFinderDown->distance);
else {
float tmp = (_hal->baro->Press / 101325.0);
tmp = pow(tmp, 0.190295);
//setAlt(44330 * (1.0 - tmp)); //sets the altitude in meters XXX wrong, baro reads 0 press
setAlt(0.0);
}
}
// dcm class for attitude
if (_dcm) {
_dcm->update_DCM();
setRoll(_dcm->roll);
setPitch(_dcm->pitch);
setYaw(_dcm->yaw);
setRollRate(_dcm->get_gyro().x);
setPitchRate(_dcm->get_gyro().y);
setYawRate(_dcm->get_gyro().z);
/*
* accel/gyro debug
*/
/*
Vector3f accel = _hal->imu->get_accel();
Vector3f gyro = _hal->imu->get_gyro();
Serial.printf_P(PSTR("accel: %f %f %f gyro: %f %f %f\n"),
accel.x,accel.y,accel.z,gyro.x,gyro.y,gyro.z);
*/
}
}
virtual void updateSlow(float dt) {
if (_hal->getMode() != MODE_LIVE)
return;
setTimeStamp(micros()); // if running in live mode, record new time stamp
if (_hal->gps) {
_hal->gps->update();
updateGpsLight();
if (_hal->gps->fix && _hal->gps->new_data) {
setLat_degInt(_hal->gps->latitude);
setLon_degInt(_hal->gps->longitude);
setAlt_intM(_hal->gps->altitude * 10); // gps in cm, intM in mm
setGroundSpeed(_hal->gps->ground_speed / 100.0); // gps is in cm/s
}
}
if (_hal->compass) {
_hal->compass->read();
_hal->compass->calculate(getRoll(), getPitch());
_hal->compass->null_offsets(_dcm->get_dcm_matrix());
}
}
void updateGpsLight(void) {
// GPS LED on if we have a fix or Blink GPS LED if we are receiving data
// ---------------------------------------------------------------------
static bool GPS_light = false;
switch (_hal->gps->status()) {
case (2):
//digitalWrite(C_LED_PIN, HIGH); //Turn LED C on when gps has valid fix.
break;
case (1):
if (_hal->gps->valid_read == true) {
GPS_light = !GPS_light; // Toggle light on and off to indicate gps messages being received, but no GPS fix lock
if (GPS_light) {
digitalWrite(_hal->cLedPin, LOW);
} else {
digitalWrite(_hal->cLedPin, HIGH);
}
_hal->gps->valid_read = false;
}
break;
default:
digitalWrite(_hal->cLedPin, LOW);
break;
}
}
};
} // namespace apo
#endif // AP_Navigator_H
// vim:ts=4:sw=4:expandtab