Exemplo n.º 1
0
int main(void)
	{
	//*******************************************************************
	Init();
	TMRInit(2);		// Initialize Timer interface with Priority=2
	BLIInit();		// Initialize Signal interface
	//*******************************************************************
	//_T1IE 	= 0; 	// Temporarily disable Timer1 interrupt
	//*******************************************************************
	LogInit();	// Initialize Data Logger	
	//*******************************************************************
	//-------------------------------------------------------------------
	#define		MaxRec		60
	//-------------------------------------------------------------------
	struct
		{
		DWORD	TS;
		WORD	Index;
		char	filler[506];
		}	Data;
	//-------------------------------------------------------------------
	uint	i;
	for (i = 0; i < sizeof(Data.filler); i++)
		{
		Data.filler[i] = 0;
		}
	//-------------------------------------------------------------------
	DWORD	TimeStart;
	float	TimePoints[MaxRec];
//	WORD	TimeIndex[MaxRec];
	//-------------------------------------------------------------------
	char		pFN[15];

	
	WORD			RC;
	
	uint			ReadCnt;
	FSFILE			File;
	//*******************************************************************
	BLISignalON();
	//------------------------------
	// Create (Open) Log file for Writing and Reading 
	//------------------------------
	RC = LogNewFile(&File);
	while ( RC != LE_GOOD );
	//------------------------------
	// Retrieve and save for future new log file name 
	//------------------------------
	RC = FS_GetName(pFN, 15, &File);
	while ( RC != LE_GOOD );
	//------------------------------
	// Write sample data to file
	//------------------------------
	for (i=0; i < MaxRec; i++)
		{
		Data.Index 	= i;
		Data.TS		= TMRGetTS();
	   	RC = FS_WriteSector(&File, &Data);
		while (CE_GOOD != RC);
		}
	//------------------------------
	// Check position in the file
	//------------------------------
   	i = FS_GetPosition (&File);
	while (i != 512*MaxRec);
	//------------------------------
	// Close the file - save changes
	//------------------------------
	RC = FS_Flush(&File);
   	while ( RC != CE_GOOD );
	//------------------------------

	//------------------------------
	// Open file for Reading 
	//------------------------------
	RC = FS_CreateFile(pFN, FS_READ_ONLY, &File);
	while ( RC != CE_GOOD );
	//------------------------------
	// Reed records
	//------------------------------
	for (i=0; i < MaxRec; i++)
		{
	   	RC = FS_Read (&File, &Data, sizeof(Data), &ReadCnt);
		while (CE_GOOD != RC);
		//--------------------------
//		TimeIndex[i] = Data.Index;
		//--------------------------
		if (0 == i)
			TimeStart = Data.TS;
		//--------------------------
		TimePoints[i] = (Data.TS - TimeStart) * TMRGetTSRate() * 1000.0;	// in msec
		//--------------------------
		TimeStart = Data.TS;
		}
	//------------------------------
	// Close the file - save changes
	//------------------------------
	RC = FS_Flush(&File);
   	while ( RC != CE_GOOD );
	//*******************************************************************
	BLISignalOFF();
	//------------------------------
	i = 1 + i;
	//------------------------------
	while(1);
	return 0;
	}
Exemplo n.º 2
0
//==================================================================================
uint		DCMUpdate(	ulong		GyroTS,	// Gyro timestamp
                        Vector*		Gyro,   // Gyro measurement
                        //--------------------------------------
                        ulong		AccTS,	// Acc timestamp
                        Vector*		Acc,    // Acc measurement
                        //--------------------------------------
                        ulong		MagTS,  // Mag timestamp
                        Vector*		Mag,    // Mag measurement
                        //--------------------------------------
                        DCMData*	IMUResult)
{
    //==========================================================================
    if (_DCMInit != 1)
        return DCM_NOTINIT;
    //==========================================================================
    // Calculate integration time interval for respective sensors
    //--------------------------------------------------------------------------
    float	GyroDT	= TMRGetTSRate() * (GyroTS - _DCM_GyroTS);
    float	AccDT	= TMRGetTSRate() * (AccTS  - _DCM_AccTS);
    float	MagDT	= TMRGetTSRate() * (MagTS  - _DCM_MagTS);
    //--------------------------------------------------------------------------
    // Update last sample timestamps for respective sensors
    //--------------------------------------------------------------------------
    _DCM_GyroTS     = GyroTS;
    _DCM_AccTS		= AccTS;
    _DCM_MagTS		= MagTS;
    //==========================================================================

    //==========================================================================
    // Accelerometer-based and Magnetometer-based rotation correction vectors
    //--------------------------------------------------------------------------
    Vector			DriftComp;		// Current step total drift compensation
    VectorSet(0.0, 0.0, 0.0, &DriftComp);
    //--------------------------------------------------------------------------
    if (TRUE == _DCM_UseAcc)
    {
        // <editor-fold defaultstate="collapsed" desc="Calculate Acc-based correction">
        //--------------------------------------------------------------------------
        // Local variables used in calculations of the Accelerometer-based correction
        //--------------------------------------------------------------------------
        Vector			EarthZ;		// Earth vertical in the Body frame
        Vector			AccNorm;	// Normalized Accelerometer measurement
        // in the Body frame
        Vector			AccError;	// Rotational "error" between the Earth
        // vertical (in Body frame) and
        // acceleration vector.
        Vector			AccPterm;	// Proportional term
        Vector			AccIterm;	// Current step component of Integral term
        //--------------------------------------------------------------------------
        // Calculating Accelerometer-based correction
        //--------------------------------------------------------------------------
        // Extract Z-axis in the Earth frame as seen from the Body frame
        // from the DCM
        DCMEarthZ(&EarthZ);
        //---------------------------------------------------------
        // We have to "normalize" gravity vector so that calculated
        // error proportional to rotation error and independent of
        // the level of current acceleration
        //---------------------------------------------------------
        VectorNormalize(Acc, &AccNorm);
        //---------------------------------------------------------
        // Cross-product of the axis Z in the Earth frame (as seen
        // from the Body frame) of the DCM with the normalized
        // Accelerometer measurement (true Z-axis of Earth frame
        // in the Body frame ignoring linear accelerations) is the
        // ERROR accumulated in DCM and defines how much the Rotation
        // Matrix need to be rotated so that these vectors match.
        //---------------------------------------------------------
        VectorCrossProduct(&EarthZ, &AccNorm, &AccError);
        //---------------------------------------------------------
        // Accelerometer correction P-Term
        //---------------------------------------------------------
        VectorScale(&AccError,  _DCMAccKp,              &AccPterm);
        //---------------------------------------------------------
        // Accelerometer correction I-Term
        //---------------------------------------------------------
        VectorScale(&AccError, (_DCMAccKi * AccDT),  &AccIterm);
        VectorAdd(&_DCMAccIterm, &AccIterm, &_DCMAccIterm);
        //---------------------------------------------------------
        // Adjust drift compensation vector with Accelerometer-
        // based correction factors
        //---------------------------------------------------------
        VectorAdd(&DriftComp, &AccPterm,     &DriftComp);
        VectorAdd(&DriftComp, &_DCMAccIterm, &DriftComp);
        //--------------------------------------------------------------------------
        // </editor-fold>
    }
    //--------------------------------------------------------------------------
    if (TRUE == _DCM_UseMag)
    {
        // <editor-fold defaultstate="collapsed" desc="Calculate Mag-based correction">
        //--------------------------------------------------------------------------
        // Local variables used in calculations of the Magnetometer-based correction
        //--------------------------------------------------------------------------
        Vector			EarthMag;	// Magnetic vector measurement
        // transformed to Earth frame using
        // current rotation matrix
        Vector			MagNorm;	// Normalized Magnetometer measurement
        // in the Earth frame
        Vector			MagError;	// Rotational "error" between rotated
        // magnetic vector (in Body frame) and
        // measured magnetic vector.
        Vector			MagPterm;	// Proportional term
        Vector			MagIterm;	// Current step component of Integral term
        //--------------------------------------------------------------------------
        // Calculating Magnetometer-based correction
        //--------------------------------------------------------------------------
        // Transform magnetic vector measurement to Earth frame
        DCMToEarth(Mag, &EarthMag);
        //---------------------------------------------------------
        // We have to "normalize" magnetic vector so that calculated
        // error proportional to rotation error and independent of
        // the strength of magnetic field
        //---------------------------------------------------------
        VectorNormalize(&EarthMag, &MagNorm);
        //------------------------------------------------------------------
        // If magnetic vector is used ONLY for Yaw drift compensation we
        // should nullify Z-axis component (Z-axis component of the reference
        // vector _DCM_BaseMAG was nullified in DCMReset(...) )
        //------------------------------------------------------------------
        if (TRUE == _DCM_UseMagYawOnly)
            MagNorm.Z = 0.0;
        //---------------------------------------------------------
        // Cross-product of the original magnetic vector transformed
        // to Body frame using the DCM with the normalized
        // magnetometer measurement in the Body frame is the ERROR
        // accumulated in DCM and defines how much the Rotation
        // Matrix need to be rotated so that these vectors match.
        //---------------------------------------------------------
        VectorCrossProduct(&MagNorm, &_DCM_BaseMAG, &MagError);
        //---------------------------------------------------------
        // Magnetometer correction P-Term
        //---------------------------------------------------------
        VectorScale(&MagError,  _DCMMagKp,              &MagPterm);
        //---------------------------------------------------------
        // Magnetometer correction I-Term
        //---------------------------------------------------------
        VectorScale(&MagError, (_DCMMagKi * MagDT),  &MagIterm);
        VectorAdd(&_DCMMagIterm, &MagIterm, &_DCMMagIterm);
        //---------------------------------------------------------
        // Adjust drift compensation vector with Magnetometer-
        // based correction factors
        //---------------------------------------------------------
        VectorAdd(&DriftComp, &MagPterm,     &DriftComp);
        VectorAdd(&DriftComp, &_DCMMagIterm, &DriftComp);
        //--------------------------------------------------------------------------
        // </editor-fold>
    }
    //==========================================================================

    //==========================================================================
    // Local variables used in "rotating" Rotational Matrix
    //--------------------------------------------------------------------------
    Vector  RotationDelta;
    Matrix  SmallRotation;
    Matrix  Rotated;
    //--------------------------------------------------------------------------
    // Calculating total adjustment and "rotate" Rotational Matrix
    //--------------------------------------------------------------------------
    // Calculate rotation delta in body frame in radians through "integration"
    // of the gyro rotation rates
    VectorScale(	Gyro, GyroDT, &RotationDelta);
    //--------------------------------------------------------------------------
    VectorAdd(&RotationDelta, &DriftComp, &RotationDelta);
    // Construct "infinitesimal" rotation matrix
    MatrixSetSmallRotation(&RotationDelta, &SmallRotation);
    // Rotate DCM by "small rotation"
    MatrixMult(&_DCMRM, &SmallRotation, &Rotated);
    // Normalize and store current DCM Rotation Matrix
    _DCMNormalize(&Rotated, &_DCMRM);
    //==========================================================================

    //--------------------------------------------------------------------------
    // Load Current orientation parameters into DCMData
    //--------------------------------------------------------------------------
    IMUResult->Roll     = _DCMRoll(&_DCMRM);
    IMUResult->Pitch	= _DCMPitch(&_DCMRM);
    IMUResult->Yaw		= _DCMYaw(&_DCMRM);
    //------------------------------------------------------------
    IMUResult->Incl     = _DCMIncl(&_DCMRM);
    //--------------------------------------------------------------------------
    IMUResult->Azimuth	= DCMRangeTo2Pi(_DCM_BaseAzimuth + IMUResult->Yaw);
    //--------------------------------------------------------------------------
    IMUResult->TS       = TMRGetTS();
    //--------------------------------------------------------------------------
    return	DCM_OK;
}