AP_NavEKF: fixed build for APM environment

2013-12-29 18:37:55 +11:00 · 2013-12-29 18:37:55 +11:00 · eb505eef91
commit eb505eef91
parent 0dd5463e77
2 changed files with 966 additions and 925 deletions
--- a/libraries/AP_NavEKF/AP_NavEKF.cpp
+++ b/libraries/AP_NavEKF/AP_NavEKF.cpp
--- a/libraries/AP_NavEKF/AP_NavEKF.h
+++ b/libraries/AP_NavEKF/AP_NavEKF.h
@ -20,10 +20,6 @@
 #ifndef AP_NavEKF
 #define AP_NavEKF
 #endif
 #include <AP_Math.h>
 #include <AP_AHRS.h>
@ -38,194 +34,228 @@ class NavEKF
 public:
    // Constructor 
-    // Don't know how to do this !!
+    NavEKF(const AP_AHRS &ahrs, AP_Baro &baro);
    NavEKF(AP_AHRS* ahrs, AP_Baro* baro, GPS* gps) :
        _ahrs(ahrs),
        _baro(baro),
        _gps(gps)
    // Initialise the filter states from the AHRS and magnetometer data (if present)
-    void InitialiseFilter();
+    void InitialiseFilter(void);
    // Update Filter States - this should be called whenever new IMU data is available
-    void UpdateFilter();
+    void UpdateFilter(void);
-    // return the Lat (rad), long(rad) and height (m) of the reference point
+
-    void getRefLLH();
+    // fill in latitude, longitude and height of the reference point
-    // return the last calculated NED position relative to the reference point (m)
+    void getRefLLH(struct Location &loc);
-    void getPosNED();
+
    // return the last calculated NED position relative to the
    // reference point (m). Return false if no position is available
    bool getPosNED(Vector3f &pos);
    // return the last calculated NED velocity (m/s)
-    void getVelNED();
+    void getVelNED(Vector3f &vel);
-    // return the last calculated Lat (rad), long(rad) and height (m)
+
-    void getLLH();
+    // return the last calculated latitude, longitude and height
    bool getLLH(struct Location &loc);
    // return the Euler roll, pitch and yaw angle in radians
-    void getEulAng();
+    void getEulerAngles(Vector3f &eulers);
    // get the transformation matrix from NED to XYD (body) axes
-    void getTnb();
+    void getRotationNEDToBody(Matrix3f &mat);
    // get the transformation matrix from XYZ (body) to NED axes
-    void getTbn();
+    void getRotationBodyToNED(Matrix3f &mat);
    // get the quaternions defining the rotation from NED to XYZ (body) axes
-    void getQuat();
+    void getQuaternion(Quaternion &quat);
 private:
    const AP_AHRS &_ahrs;
    AP_Baro &_baro;
-void UpdateStrapdownEquationsNED();
+    void UpdateStrapdownEquationsNED();
-void CovariancePrediction();
+    void CovariancePrediction();
    void FuseVelPosNED();
    void FuseMagnetometer();
    void FuseAirspeed();
-void FuseVelPosNED();
+    void zeroRows(float covMat[24][24], uint8_t first, uint8_t last);
-void FuseMagnetometer();
+    void zeroCols(float covMat[24][24], uint8_t first, uint8_t last);
-void FuseAirspeed();
+    void quatNorm(float quatOut[4], float quatIn[4]);
-void zeroRows(float covMat[24][24], uint8_t first, uint8_t last);
+    // store states along with system time stamp in msces
    void StoreStates(void);
-void zeroCols(float covMat[24][24], uint8_t first, uint8_t last);
+    // recall state vector stored at closest time to the one specified by msec
    void RecallStates(float statesForFusion[24], uint32_t msec);
-void quatNorm(float quatOut[4], float quatIn[4]);
+    void quat2Tnb(Matrix3f &Tnb, float quat[4]);
-// store states along with system time stamp in msces
+    void quat2Tbn(Matrix3f &Tbn, float quat[4]);
 void StoreStates(uint32_t msec);
-// recall state vector stored at closest time to the one specified by msec
+    void calcEarthRateNED(Vector3f &omega, float latitude);
 void RecallStates(float statesForFusion[24], uint32_t msec);
-void quat2Tnb(Matrix3f &Tnb, float quat[4]);
+    void eul2quat(float quat[4], float eul[3]);
-void quat2Tbn(Matrix3f &Tbn, float quat[4]);
+    void quat2eul(float eul[3],float quat[4]);
-void calcEarthRateNED(Vector3f &omega, float latitude);
+    void calcvelNED(float velNED[3], float gpsCourse, float gpsGndSpd, float gpsVelD);
-void eul2quat(float quat[4], float eul[3]);
+    void calcposNE(float lat, float lon);
-void quat2eul(float eul[3],float quat[4]);
+    void calcllh(float &lat, float &lon, float &hgt);
-void calcvelNED(float velNED[3], float gpsCourse, float gpsGndSpd, float gpsVelD);
+    void OnGroundCheck();
-void calcposNE(float posNE[2], float lat, float lon, float latRef, float lonRef);
+    void CovarianceInit();
-void calcllh(float posNED[3], float lat, float lon, float hgt, float latRef, float lonRef, float hgtRef);
+    void readIMUData();
-void OnGroundCheck();
+    void readGpsData();
-void CovarianceInit();
+    void readHgtData();
-void readIMUData();
+    void readMagData();
-void readGpsData();
+    void readAirSpdData();
-void readHgtData();
+    void SelectVelPosFusion();
 void readMagData();
 void readAirSpdData();
 void SelectVelPosFusion();
-void SelectHgtFusion();
+    void SelectHgtFusion();
-void SelectTasFusion();
+    void SelectTasFusion();
-void SelectMagFusion();
+    void SelectMagFusion();
 #define deg2rad 0.017453292
 #define rad2deg 57.295780
 #define pi 3.141592657
 #define earthRate 0.000072921
 #define earthRadius 6378145.0
 static float KH[24][24]; //  intermediate result used for covariance updates
 static float KHP[24][24]; // intermediate result used for covariance updates
 static float P[24][24]; // covariance matrix
 static float Kfusion[24]; // Kalman gains
 static float states[24]; // state matrix
 static float storedStates[24][50]; // state vectors stored for the last 50 time steps
 static uint32_t statetimeStamp[50]; // time stamp for each state vector stored
 static Vector3f correctedDelAng; // delta angles about the xyz body axes corrected for errors (rad)
 static Vector3f correctedDelVel; // delta velocities along the XYZ body axes corrected for errors (m/s)
 static Vector3f summedDelAng; // summed delta angles about the xyz body axes corrected for errors (rad)
 static Vector3f summedDelVel; // summed delta velocities along the XYZ body axes corrected for errors (m/s)
 static float accNavMag; // magnitude of navigation accel (- used to adjust GPS obs variance (m/s^2)
 static Vector3f earthRateNED; // earths angular rate vector in NED (rad/s)
 static Vector3f dVelIMU; // delta velocity vector in XYZ body axes measured by the IMU (m/s)
 static Vector3f dAngIMU; // delta angle vector in XYZ body axes measured by the IMU (rad)
 static float dtIMU; // time lapsed since the last IMU measurement or covariance update (sec)
 static float dt; // time lapsed since last covariance prediction
 static bool onGround; // boolean true when the flight vehicle is on the ground (not flying)
 const bool useAirspeed = true; // boolean true if airspeed data is being used
 const bool useCompass = true; // boolean true if magnetometer data is being used
 const uint8_t fusionModeGPS = 0; // 0 = GPS outputs 3D velocity, 1 = GPS outputs 2D velocity, 2 = GPS outputs no velocity
 static float innovVelPos[6]; // innovation output
 static float varInnovVelPos[6]; // innovation variance output
 static bool fuseVelData; // this boolean causes the posNE and velNED obs to be fused
 static bool fusePosData; // this boolean causes the posNE and velNED obs to be fused
 static bool fuseHgtData; // this boolean causes the hgtMea obs to be fused
 static float velNED[3]; // North, East, Down velocity obs (m/s)
 static float posNE[2]; // North, East position obs (m)
 static float hgtMea; //  measured height (m)
 static float posNED[3]; // North, East Down position (m)
 static float statesAtVelTime[24]; // States at the effective measurement time for posNE and velNED measurements
 static float statesAtPosTime[24]; // States at the effective measurement time for posNE and velNED measurements
 static float statesAtHgtTime[24]; // States at the effective measurement time for the hgtMea measurement
 static float innovMag[3]; // innovation output
 static float varInnovMag[3]; // innovation variance output
 static bool fuseMagData; // boolean true when magnetometer data is to be fused
 static Vector3f magData; // magnetometer flux radings in X,Y,Z body axes
 static float statesAtMagMeasTime[24]; // filter satates at the effective measurement time
 static float innovVtas; // innovation output
 static float varInnovVtas; // innovation variance output
 static bool fuseVtasData; // boolean true when airspeed data is to be fused
 static float VtasMeas; // true airspeed measurement (m/s)
 static float statesAtVtasMeasTime[24]; // filter states at the effective measurement time
 static float latRef; // WGS-84 latitude of reference point (rad)
 static float lonRef; // WGS-84 longitude of reference point (rad)
 static float hgtRef; // WGS-84 height of reference point (m)
 static Vector3f magBias; // states representing magnetometer bias vector in XYZ body axes
 static float eulerEst[3]; // Euler angles calculated from filter states
 static float eulerDif[3]; // difference between Euler angle estimated by EKF and the AHRS solution
 const float covTimeStepMax = 0.07; // maximum time allowed between covariance predictions
 const float covDelAngMax = 0.05; // maximum delta angle between covariance predictions
 static bool covPredStep; // boolean set to true when a covariance prediction step has been performed
 static bool magFuseStep; // boolean set to true when magnetometer fusion steps are being performed
 static bool posVelFuseStep; // boolean set to true when position and velocity fusion is being performed
 static bool tasFuseStep; // boolean set to true when airspeed fusion is being performed
 static uint32_t TASmsecPrev; // time stamp of last TAS fusion step
 const uint32_t TASmsecTgt = 250; // target interval between TAS fusion steps
 static uint32_t MAGmsecPrev; // time stamp of last compass fusion step
 const uint32_t MAGmsecTgt = 200; // target interval between compass fusion steps
 static uint32_t HGTmsecPrev; // time stamp of last height measurement fusion step
 const uint32_t HGTmsecTgt = 200; // target interval between height measurement fusion steps
-// Estimated time delays (msec)
+    bool statesInitialised;
 const uint32_t msecVelDelay = 200;
 const uint32_t msecPosDelay = 200;
 const uint32_t msecHgtDelay = 350;
 const uint32_t msecMagDelay = 30;
 const uint32_t msecTasDelay = 200;
-// IMU input data variables
+    float KH[24][24]; //  intermediate result used for covariance updates
-static float imuIn;
+    float KHP[24][24]; // intermediate result used for covariance updates
-static float tempImu[8];
+    float P[24][24]; // covariance matrix
-static uint32_t IMUmsec;
+    float states[24]; // state matrix
    float storedStates[24][50]; // state vectors stored for the last 50 time steps
    uint32_t statetimeStamp[50]; // time stamp for each state vector stored
    Vector3f correctedDelAng; // delta angles about the xyz body axes corrected for errors (rad)
    Vector3f correctedDelVel; // delta velocities along the XYZ body axes corrected for errors (m/s)
    Vector3f summedDelAng; // summed delta angles about the xyz body axes corrected for errors (rad)
    Vector3f summedDelVel; // summed delta velocities along the XYZ body axes corrected for errors (m/s)
    float accNavMag; // magnitude of navigation accel (- used to adjust GPS obs variance (m/s^2)
    Vector3f earthRateNED; // earths angular rate vector in NED (rad/s)
    Vector3f dVelIMU; // delta velocity vector in XYZ body axes measured by the IMU (m/s)
    Vector3f dAngIMU; // delta angle vector in XYZ body axes measured by the IMU (rad)
    float dtIMU; // time lapsed since the last IMU measurement or covariance update (sec)
    float dt; // time lapsed since last covariance prediction
    bool onGround; // boolean true when the flight vehicle is on the ground (not flying)
    const bool useAirspeed; // boolean true if airspeed data is being used
    const bool useCompass; // boolean true if magnetometer data is being used
    const uint8_t fusionModeGPS; // 0 = GPS outputs 3D velocity, 1 = GPS outputs 2D velocity, 2 = GPS outputs no velocity
    float innovVelPos[6]; // innovation output
    float varInnovVelPos[6]; // innovation variance output
    bool fuseVelData; // this boolean causes the posNE and velNED obs to be fused
    bool fusePosData; // this boolean causes the posNE and velNED obs to be fused
    bool fuseHgtData; // this boolean causes the hgtMea obs to be fused
    float velNED[3]; // North, East, Down velocity obs (m/s)
    float posNE[2]; // North, East position obs (m)
    float hgtMea; //  measured height (m)
    float posNED[3]; // North, East Down position (m)
    float statesAtVelTime[24]; // States at the effective measurement time for posNE and velNED measurements
    float statesAtPosTime[24]; // States at the effective measurement time for posNE and velNED measurements
    float statesAtHgtTime[24]; // States at the effective measurement time for the hgtMea measurement
    float innovMag[3]; // innovation output
    float varInnovMag[3]; // innovation variance output
    bool fuseMagData; // boolean true when magnetometer data is to be fused
    Vector3f magData; // magnetometer flux radings in X,Y,Z body axes
    float statesAtMagMeasTime[24]; // filter satates at the effective measurement time
    float innovVtas; // innovation output
    float varInnovVtas; // innovation variance output
    bool fuseVtasData; // boolean true when airspeed data is to be fused
    float VtasMeas; // true airspeed measurement (m/s)
    float statesAtVtasMeasTime[24]; // filter states at the effective measurement time
    float latRef; // WGS-84 latitude of reference point (rad)
    float lonRef; // WGS-84 longitude of reference point (rad)
    float hgtRef; // WGS-84 height of reference point (m)
    Vector3f magBias; // states representing magnetometer bias vector in XYZ body axes
    float eulerEst[3]; // Euler angles calculated from filter states
    float eulerDif[3]; // difference between Euler angle estimated by EKF and the AHRS solution
    const float covTimeStepMax; // maximum time allowed between covariance predictions
    const float covDelAngMax; // maximum delta angle between covariance predictions
    bool covPredStep; // boolean set to true when a covariance prediction step has been performed
    bool magFuseStep; // boolean set to true when magnetometer fusion steps are being performed
    bool posVelFuseStep; // boolean set to true when position and velocity fusion is being performed
    bool tasFuseStep; // boolean set to true when airspeed fusion is being performed
    uint32_t TASmsecPrev; // time stamp of last TAS fusion step
    const uint32_t TASmsecTgt; // target interval between TAS fusion steps
    uint32_t MAGmsecPrev; // time stamp of last compass fusion step
    const uint32_t MAGmsecTgt; // target interval between compass fusion steps
    uint32_t HGTmsecPrev; // time stamp of last height measurement fusion step
    const uint32_t HGTmsecTgt; // target interval between height measurement fusion steps
    // Estimated time delays (msec)
    const uint32_t msecVelDelay;
    const uint32_t msecPosDelay;
    const uint32_t msecHgtDelay;
    const uint32_t msecMagDelay;
    const uint32_t msecTasDelay;
-// GPS input data variables
+    // IMU input data variables
-static float gpsCourse;
+    float imuIn;
-static float gpsGndSpd;
+    float tempImu[8];
-static float gpsVelD;
+    uint32_t IMUmsec;
 static float gpsLat;
 static float gpsLon;
 static float gpsHgt;
 static bool newDataGps;
 static uint8_t GPSstatus;
-// Magnetometer input data variables
+    // GPS input data variables
-static float magIn;
+    float gpsCourse;
-static float tempMag[8];
+    float gpsGndSpd;
-static float tempMagPrev[8];
+    float gpsLat;
-static uint32_t MAGframe;
+    float gpsLon;
-static uint32_t MAGtime;
+    float gpsHgt;
-static uint32_t lastMAGtime;
+    bool newDataGps;
 static bool newDataMag;
-// AHRS input data variables
+    // Magnetometer input data variables
-static float ahrsEul[3];
+    float magIn;
    float tempMag[8];
    float tempMagPrev[8];
    uint32_t MAGframe;
    uint32_t MAGtime;
    uint32_t lastMAGtime;
    bool newDataMag;
    // AHRS input data variables
    float ahrsEul[3];
 	uint32_t velFailTime;
 	uint32_t posFailTime;
 	uint32_t hgtFailTime;
 	Vector3f  prevDelAng;
    Matrix3f  prevTnb;
    struct {
    	float q0;
        float q1;
        float q2;
        float q3;
        float magN;
        float magE;
        float magD;
        float magXbias;
        float magYbias;
        float magZbias;
        uint8_t obsIndex;
        Matrix3f DCM;
        Vector3f MagPred;
        float R_MAG;
        float SH_MAG[9];
 	} mag_state;
 	uint8_t storeIndex;
 	uint32_t lastIMUusec;
 	uint32_t lastFixTime;
 };
 #endif // AP_NavEKF