#include <vpForceTwistMatrix.h>

Inheritance diagram for vpForceTwistMatrix:

Public Types
enum	vpDetMethod { LU_DECOMPOSITION }

Public Member Functions
	vpForceTwistMatrix ()

	vpForceTwistMatrix (const vpForceTwistMatrix &F)

	vpForceTwistMatrix (const vpHomogeneousMatrix &M)

	vpForceTwistMatrix (const vpTranslationVector &t, const vpThetaUVector &thetau)

	vpForceTwistMatrix (const vpTranslationVector &t, const vpRotationMatrix &R)

	vpForceTwistMatrix (const double tx, const double ty, const double tz, const double tux, const double tuy, const double tuz)

void	init ()

vpForceTwistMatrix	buildFrom (const vpTranslationVector &t, const vpRotationMatrix &R)

vpForceTwistMatrix	buildFrom (const vpTranslationVector &t, const vpThetaUVector &thetau)

vpForceTwistMatrix	buildFrom (const vpHomogeneousMatrix &M)

void	setIdentity ()

vpForceTwistMatrix	operator* (const vpForceTwistMatrix &F) const

vpMatrix	operator* (const vpMatrix &M) const

vpColVector	operator* (const vpColVector &H) const

vpForceTwistMatrix &	operator= (const vpForceTwistMatrix &H)

void	kill ()

void	eye (unsigned int n)

void	eye (unsigned int m, unsigned int n)

void	setIdentity (const double &val=1.0)

void	insert (const vpMatrix &A, const unsigned int r, const unsigned int c)

void	stackMatrices (const vpMatrix &A)

Columns, Rows extraction, Submatrix
void	init (const vpMatrix &m, unsigned int r, unsigned int c, unsigned int nrows, unsigned int ncols)

vpRowVector	row (const unsigned int i)

vpColVector	column (const unsigned int j)

Set/get Matrix size
unsigned int	getRows () const

unsigned int	getCols () const

void	resize (const unsigned int nrows, const unsigned int ncols, const bool nullify=true)

double	getMinValue () const

double	getMaxValue () const

Copy / assignment
vpMatrix &	operator<< (double *)

void	diag (const vpColVector &A)

Printing
int	print (std::ostream &s, unsigned int length, char const *intro=0)

std::ostream &	matlabPrint (std::ostream &os) const

std::ostream &	maplePrint (std::ostream &os) const

std::ostream &	csvPrint (std::ostream &os) const

std::ostream &	cppPrint (std::ostream &os, const char *matrixName=NULL, bool octet=false) const

void	printSize ()

Access/modification operators
double *	operator[] (unsigned int i)

double *	operator[] (unsigned int i) const

Kronecker product
void	kron (const vpMatrix &m1, vpMatrix &out)

vpMatrix	kron (const vpMatrix &m1)

void	stackColumns (vpColVector &out)

vpColVector	stackColumns ()

void	stackRows (vpRowVector &out)

vpRowVector	stackRows ()

Matrix operations
vpMatrix &	operator+= (const vpMatrix &B)

vpMatrix &	operator+= (const double x)

vpMatrix &	operator-= (const vpMatrix &B)

vpMatrix &	operator-= (const double x)

vpMatrix	operator* (const vpHomography &H) const

vpTranslationVector	operator* (const vpTranslationVector &b) const

vpMatrix	operator* (const double x) const

vpMatrix	operator+ (const vpMatrix &B) const

vpMatrix	operator- (const vpMatrix &B) const

vpMatrix	operator- () const

vpMatrix &	operator*= (const double x)

vpMatrix &	operator/= (double x)

vpMatrix	operator/ (const double x) const

double	sumSquare () const

double	det (vpDetMethod method=LU_DECOMPOSITION) const

vpMatrix	expm ()

Transpose, Identity
vpMatrix	t () const

vpMatrix	transpose () const

void	transpose (vpMatrix &C) const

vpMatrix	AAt () const

void	AAt (vpMatrix &B) const

vpMatrix	AtA () const

void	AtA (vpMatrix &B) const

Matrix inversion
vpMatrix	inverseByLU () const

vpMatrix	inverseByCholesky () const

vpMatrix	inverseByCholeskyLapack () const

vpMatrix	inverseByQR () const

vpMatrix	inverseByQRLapack () const

vpMatrix	pseudoInverse (double svThreshold=1e-6) const

unsigned int	pseudoInverse (vpMatrix &Ap, double svThreshold=1e-6) const

unsigned int	pseudoInverse (vpMatrix &Ap, vpColVector &sv, double svThreshold=1e-6) const

unsigned int	pseudoInverse (vpMatrix &Ap, vpColVector &sv, double svThreshold, vpMatrix &ImA, vpMatrix &ImAt) const

unsigned int	pseudoInverse (vpMatrix &Ap, vpColVector &sv, double svThreshold, vpMatrix &ImA, vpMatrix &ImAt, vpMatrix &kerA) const

SVD decomposition
void	svd (vpColVector &w, vpMatrix &v)

void	solveBySVD (const vpColVector &B, vpColVector &x) const

vpColVector	solveBySVD (const vpColVector &B) const

unsigned int	kernel (vpMatrix &KerA, double svThreshold=1e-6)

double	cond ()

Eigen values
vpColVector	eigenValues ()

void	eigenValues (vpColVector &evalue, vpMatrix &evector)

Norms
double	euclideanNorm () const

double	infinityNorm () const

Static Public Member Functions
static void	add2Matrices (const vpMatrix &A, const vpMatrix &B, vpMatrix &C)

static void	add2WeightedMatrices (const vpMatrix &A, const double &wA, const vpMatrix &B, const double &wB, vpMatrix &C)

static vpMatrix	computeCovarianceMatrix (const vpMatrix &A, const vpColVector &x, const vpColVector &b)

static vpMatrix	computeCovarianceMatrix (const vpMatrix &A, const vpColVector &x, const vpColVector &b, const vpMatrix &w)

static void	computeHLM (const vpMatrix &H, const double &alpha, vpMatrix &HLM)

static void	createDiagonalMatrix (const vpColVector &A, vpMatrix &DA)

static vpMatrix	insert (const vpMatrix &A, const vpMatrix &B, const unsigned int r, const unsigned int c)

static void	insert (const vpMatrix &A, const vpMatrix &B, vpMatrix &C, const unsigned int r, const unsigned int c)

static vpMatrix	juxtaposeMatrices (const vpMatrix &A, const vpMatrix &B)

static void	juxtaposeMatrices (const vpMatrix &A, const vpMatrix &B, vpMatrix &C)

static void	kron (const vpMatrix &m1, const vpMatrix &m2, vpMatrix &out)

static vpMatrix	kron (const vpMatrix &m1, const vpMatrix &m2)

static bool	loadMatrix (std::string filename, vpMatrix &M, const bool binary=false, char *Header=NULL)

static bool	loadMatrix (const char filename, vpMatrix &M, const bool binary=false, char Header=NULL)

static void	mult2Matrices (const vpMatrix &A, const vpMatrix &B, vpMatrix &C)

static void	multMatrixVector (const vpMatrix &A, const vpColVector &b, vpColVector &c)

static void	negateMatrix (const vpMatrix &A, vpMatrix &C)

static bool	saveMatrix (std::string filename, const vpMatrix &M, const bool binary=false, const char *Header="")

static bool	saveMatrix (const char filename, const vpMatrix &M, const bool binary=false, const char Header="")

static bool	saveMatrixYAML (std::string filename, const vpMatrix &M, const char *header="")

static bool	saveMatrixYAML (const char filename, const vpMatrix &M, const char header="")

static bool	loadMatrixYAML (std::string filename, vpMatrix &M, char *header=NULL)

static bool	loadMatrixYAML (const char filename, vpMatrix &M, char header=NULL)

static vpMatrix	stackMatrices (const vpMatrix &A, const vpMatrix &B)

static void	stackMatrices (const vpMatrix &A, const vpMatrix &B, vpMatrix &C)

static void	sub2Matrices (const vpMatrix &A, const vpMatrix &B, vpMatrix &C)

Public Attributes
double *	data

Protected Attributes
unsigned int	rowNum

unsigned int	colNum

double **	rowPtrs

unsigned int	dsize

unsigned int	trsize

Friends
class	vpMatrix

Related Functions
(Note that these are not member functions.)
enum	vpGEMMmethod

vpMatrix	operator* (const double &x, const vpMatrix &B)

void	vpGEMM (const vpMatrix &A, const vpMatrix &B, const double &alpha, const vpMatrix &C, const double &beta, vpMatrix &D, const unsigned int &ops=0)

void	skew (const vpTranslationVector &t, vpMatrix &M)

Detailed Description

Class that consider the particular case of twist transformation matrix that allows to transform a force/troque vector from one frame to an other.

The vpForceTwistMatrix is derived from vpMatrix.

The twist transformation matrix that allows to transform the force/torque vector expressed at frame ${\cal F}_b$ into the frame ${\cal F}_a$ is a 6 by 6 matrix defined as

$^a{\bf F}_b = \left[ \begin{array}{cc} ^a{\bf R}_b & {\bf 0}_{3\times 3}\\ {[^a{\bf t}_b]}_{\times} \; ^a{\bf R}_b & ^a{\bf R}_b \end{array} \right]$

$^a{\bf R}_b$ is a rotation matrix and $^a{\bf t}_b$ is a translation vector.

The code belows shows for example how to convert a force/torque skew from probe frame to a sensor frame.

#include <visp/vpColVector.h>
#include <visp/vpForceTwistMatrix.h>
int main()
{
  vpForceTwistMatrix sFp; // Twist transformation matrix from sensor to probe frame
  vpHomogeneousMatrix sMp; // Force/torque sensor frame to probe frame transformation
  // ... sMp need here to be initialized
  sFp.buildFrom(sMp); 
 
  vpColVector p_H(6); // Force/torque skew in the probe frame: fx,fy,fz,tx,ty,tz 
  // ... p_H should here have an initial value
  vpColVector s_H(6); // Force/torque skew in the sensor frame: fx,fy,fz,tx,ty,tz 
  // Compute the value of the force/torque in the sensor frame
  s_H = sFp * p_H;
}

Definition at line 104 of file vpForceTwistMatrix.h.

Member Enumeration Documentation

enum vpMatrix::vpDetMethod

inherited

Method used to compute the determinant of a square matrix.

See also: det()

Enumerator
LU_DECOMPOSITION	LU decomposition method.

Definition at line 105 of file vpMatrix.h.

Constructor & Destructor Documentation

vpForceTwistMatrix::vpForceTwistMatrix ( )

Initialize a force/torque twist transformation matrix as identity.

Definition at line 112 of file vpForceTwistMatrix.cpp.

References init().

vpForceTwistMatrix::vpForceTwistMatrix ( const vpForceTwistMatrix & F )

Initialize a force/torque twist transformation matrix from another force/torque twist matrix.

Parameters

F	: Force/torque twist matrix used as initializer.

Definition at line 124 of file vpForceTwistMatrix.cpp.

References init().

vpForceTwistMatrix::vpForceTwistMatrix ( const vpHomogeneousMatrix & M )

Initialize a force/torque twist transformation matrix from an homogeneous matrix. Given the homogenous transformation

$^a{\bf M}_b = \left(\begin{array}{cc} ^a{\bf R}_b & ^a{\bf t}_b\\ 0 & 1 \end{array} \right)$

the force/torque twist matrix is given by :

$^a{\bf F}_b = \left[\begin{array}{cc} ^a{\bf R}_b & {\bf 0}_{3\times 3}\\ {[^a{\bf t}_b]}_{\times} \; ^a{\bf R}_b & ^a{\bf R}_b \end{array} \right]$

Parameters

M	: Homogeneous matrix $^a{\bf M}_b$ used to initialize the twist transformation matrix.

Definition at line 154 of file vpForceTwistMatrix.cpp.

References buildFrom(), and init().

vpForceTwistMatrix::vpForceTwistMatrix	(	const vpTranslationVector &	tv,
		const vpThetaUVector &	thetau
	)

Initialize a force/torque twist transformation matrix from a translation vector t and a rotation vector with $\theta u$ parametrization.

Parameters

tv	: Translation vector.
thetau	: $\theta u$ rotation vector.

Definition at line 170 of file vpForceTwistMatrix.cpp.

References buildFrom(), and init().

vpForceTwistMatrix::vpForceTwistMatrix	(	const vpTranslationVector &	tv,
		const vpRotationMatrix &	R
	)

Initialize a force/torque twist transformation matrix from a translation vector t and a rotation matrix R.

Parameters

tv	: Translation vector.
R	: Rotation matrix.

Definition at line 187 of file vpForceTwistMatrix.cpp.

References buildFrom(), and init().

vpForceTwistMatrix::vpForceTwistMatrix	(	const double	tx,
		const double	ty,
		const double	tz,
		const double	tux,
		const double	tuy,
		const double	tuz
	)

Initialize a force/torque twist transformation matrix from a translation vector t and a rotation vector with $\theta u$ parametrization.

Parameters

tx,ty,tz	: Translation vector in meters.
tux,tuy,tuz	: $\theta u$ rotation vector expressed in radians.

Definition at line 203 of file vpForceTwistMatrix.cpp.

References buildFrom(), and init().

Member Function Documentation

vpMatrix vpMatrix::AAt ( ) const

inherited

Computes the $AA^T$ operation $B = A*A^T$

Returns

See also: AAt(vpMatrix &) const

Definition at line 1297 of file vpMatrix.cpp.

void vpMatrix::AAt ( vpMatrix & B ) const

inherited

Compute the AAt operation such as $B = A*A^T$ .

The result is placed in the parameter B and not returned.

A new matrix won't be allocated for every use of the function. This results in a speed gain if used many times with the same result matrix size.

See also: AAt()

Definition at line 1317 of file vpMatrix.cpp.

References vpMatrix::colNum, vpMatrix::resize(), vpMatrix::rowNum, vpMatrix::rowPtrs, vpCERROR, and vpERROR_TRACE.

void vpMatrix::add2Matrices	(	const vpMatrix &	A,
		const vpMatrix &	B,
		vpMatrix &	C
	)

staticinherited

Operation C = A + B.

The result is placed in the third parameter C and not returned. A new matrix won't be allocated for every use of the function (Speed gain if used many times with the same result matrix size).

See also: operator+()

Definition at line 542 of file vpMatrix.cpp.

References vpMatrix::colNum, vpMatrix::getCols(), vpMatrix::getRows(), vpMatrixException::incorrectMatrixSizeError, vpMatrix::resize(), vpMatrix::rowNum, vpMatrix::rowPtrs, and vpERROR_TRACE.

Referenced by vpMatrix::operator+().

void vpMatrix::add2WeightedMatrices	(	const vpMatrix &	A,
		const double &	wA,
		const vpMatrix &	B,
		const double &	wB,
		vpMatrix &	C
	)

staticinherited

Operation C = A*wA + B*wB

The result is placed in the third parameter C and not returned. A new matrix won't be allocated for every use of the function (Speed gain if used many times with the same result matrix size).

See also: operator+()

Definition at line 503 of file vpMatrix.cpp.

References vpMatrix::colNum, vpMatrix::getCols(), vpMatrix::getRows(), vpMatrixException::incorrectMatrixSizeError, vpMatrix::resize(), vpMatrix::rowNum, vpMatrix::rowPtrs, and vpERROR_TRACE.

vpMatrix vpMatrix::AtA ( ) const

inherited

Compute the AtA operation such as $B = A^T*A$

Returns

See also: AtA(vpMatrix &) const

Examples:: photometricVisualServoing.cpp, and testMatrixInverse.cpp.

Definition at line 1408 of file vpMatrix.cpp.

Referenced by vpCalibration::calibrationTsai(), vpMbEdgeKltTracker::computeVVS(), vpMbKltTracker::computeVVS(), vpTemplateTrackerWarpHomographySL3::findWarp(), and vpNurbs::globalCurveApprox().

void vpMatrix::AtA ( vpMatrix & B ) const

inherited

Compute the AtA operation such as $B = A^T*A$ .

The result is placed in the parameter B and not returned.

A new matrix won't be allocated for every use of the function. This results in a speed gain if used many times with the same result matrix size.

See also: AtA()

Definition at line 1360 of file vpMatrix.cpp.

References vpMatrix::colNum, vpMatrix::data, vpMatrix::resize(), vpMatrix::rowNum, vpCERROR, and vpERROR_TRACE.

vpForceTwistMatrix vpForceTwistMatrix::buildFrom	(	const vpTranslationVector &	tv,
		const vpRotationMatrix &	R
	)

Build a force/torque twist transformation matrix from a translation vector t and a rotation matrix M.

Parameters

tv	: Translation vector.
R	: Rotation matrix.

Definition at line 374 of file vpForceTwistMatrix.cpp.

References vpTranslationVector::skew().

Referenced by buildFrom(), and vpForceTwistMatrix().

vpForceTwistMatrix vpForceTwistMatrix::buildFrom	(	const vpTranslationVector &	tv,
		const vpThetaUVector &	thetau
	)

Initialize a force/torque twist transformation matrix from a translation vector t and a rotation vector with $\theta u$ parametrization.

Parameters

tv	: Translation vector.
thetau	: $\theta u$ rotation vector.

Definition at line 401 of file vpForceTwistMatrix.cpp.

References buildFrom(), and vpRotationMatrix::buildFrom().

vpForceTwistMatrix vpForceTwistMatrix::buildFrom ( const vpHomogeneousMatrix & M )

Initialize a force/torque twist transformation matrix from an homogeneous matrix $M$ with

${\bf M} = \left[\begin{array}{cc} {\bf R} & {\bf t} \\ {\bf 0}_{1\times 3} & 1 \end{array} \right]$

Parameters

M	: Homogeneous matrix used to initialize the force/torque twist transformation matrix.

Definition at line 422 of file vpForceTwistMatrix.cpp.

References buildFrom(), and vpHomogeneousMatrix::extract().

vpColVector vpMatrix::column ( const unsigned int j )

inherited

Column extraction.

Return the ith columns of the matrix.

Warning: notice column(1) is the 0th column.

Definition at line 2289 of file vpMatrix.cpp.

References vpMatrix::getRows().

Referenced by vpHomography::DLT(), vpPose::poseDementhonPlan(), and vpPose::poseFromRectangle().

vpMatrix vpMatrix::computeCovarianceMatrix	(	const vpMatrix &	A,
		const vpColVector &	x,
		const vpColVector &	b
	)

staticinherited

Compute the covariance matrix of the parameters x from a least squares minimisation defined as: Ax = b

Parameters

A	: Matrix A from Ax = b.
x	: Vector x from Ax = b corresponding to the parameters to estimate.
b	: Vector b from Ax = b.

Definition at line 56 of file vpMatrix_covariance.cpp.

References vpMatrix::pseudoInverse(), vpColVector::t(), and vpMatrix::t().

Referenced by vpMbEdgeKltTracker::computeVVS(), vpMbKltTracker::computeVVS(), vpMbEdgeTracker::computeVVS(), vpPose::poseVirtualVS(), and vpPose::poseVirtualVSrobust().

vpMatrix vpMatrix::computeCovarianceMatrix	(	const vpMatrix &	A,
		const vpColVector &	x,
		const vpColVector &	b,
		const vpMatrix &	W
	)

staticinherited

Compute the covariance matrix of the parameters x from a least squares minimisation defined as: WAx = Wb

Parameters

A	: Matrix A from WAx = Wb.
x	: Vector x from WAx = Wb corresponding to the parameters to estimate.
b	: Vector b from WAx = Wb.
W	: Diagonal weigths matrix from WAx = Wb.

Definition at line 74 of file vpMatrix_covariance.cpp.

References vpMatrix::pseudoInverse(), and vpMatrix::t().

void vpMatrix::computeHLM	(	const vpMatrix &	H,
		const double &	alpha,
		vpMatrix &	HLM
	)

staticinherited

Compute ${\bf H} + \alpha * diag({\bf H})$

Parameters

H	: input Matrix ${\bf H}$ . This matrix should be square.
alpha	: Scalar $\alpha$
HLM	: Resulting operation.

Definition at line 4051 of file vpMatrix.cpp.

References vpMatrix::getCols(), vpMatrix::getRows(), vpMatrixException::incorrectMatrixSizeError, vpMatrix::resize(), and vpTRACE.

Referenced by vpTemplateTrackerWarpHomographySL3::findWarp(), vpTemplateTrackerSSDESM::initCompInverse(), vpTemplateTrackerSSDInverseCompositional::initCompInverse(), vpTemplateTrackerZNCCForwardAdditional::initHessienDesired(), vpTemplateTrackerZNCCInverseCompositional::initHessienDesired(), vpTemplateTracker::setHDes(), vpTemplateTrackerSSDForwardCompositional::trackNoPyr(), vpTemplateTrackerSSDESM::trackNoPyr(), and vpTemplateTrackerSSDForwardAdditional::trackNoPyr().

double vpMatrix::cond ( )

inherited

Returns: The condition number, the ratio of the largest singular value of the matrix to the smallest.

Definition at line 4026 of file vpMatrix.cpp.

References vpMatrix::getCols(), and vpMatrix::svd().

std::ostream & vpMatrix::cppPrint	(	std::ostream &	os,
		const char *	matrixName = `NULL`,
		bool	octet = `false`
	)		const

inherited

Print to be used as part of a C++ code later.

Print under the following form: vpMatrix A(6,4); A[0][0] = 1.4; A[0][1] = 0.6; ...

Parameters

os	the stream to be printed in.
matrixName	name of the matrix, "A" by default, to be used for the line vpMatrix A(6,7) (see example).
octet	if false, print using double, if true, print byte per byte each bytes of the double array.

Definition at line 2851 of file vpMatrix.cpp.

References vpMatrix::getRows().

void vpMatrix::createDiagonalMatrix	(	const vpColVector &	A,
		vpMatrix &	DA
	)

staticinherited

Create a diagonal matrix with the element of a vector $DA_{ii} = A_i$ .

Parameters

A	: Vector which element will be put in the diagonal.
DA	: Diagonal matrix DA[i][i] = A[i]

See also: diag()

Definition at line 2600 of file vpMatrix.cpp.

References vpMatrix::getRows(), vpMatrix::resize(), vpCERROR, and vpERROR_TRACE.

std::ostream & vpMatrix::csvPrint ( std::ostream & os ) const

inherited

Print matrix in csv format.

Print as comma separated values so that this output can be imported into any program which has a csv data import option: 0.939846, 0.0300754, 0.340272 0.0300788, 0.984961, -0.170136 -0.340272, 0.170136, 0.924807

Definition at line 2818 of file vpMatrix.cpp.

References vpMatrix::getCols(), and vpMatrix::getRows().

double vpMatrix::det ( vpDetMethod method = LU_DECOMPOSITION ) const

inherited

Compute the determinant of a n-by-n matrix.

Parameters

method : Method used to compute the determinant. Default LU decomposition methos is faster than the method based on Gaussian elimination.

Returns: Determinant of the matrix.

#include <iostream>
#include <visp/vpMatrix.h>
int main()
{
vpMatrix A(3,3);
A[0][0] = 1/1.; A[0][1] = 1/2.; A[0][2] = 1/3.;
A[1][0] = 1/3.; A[1][1] = 1/4.; A[1][2] = 1/5.;
A[2][0] = 1/6.; A[2][1] = 1/7.; A[2][2] = 1/8.;
std::cout << "Initial matrix: \n" << A << std::endl;
// Compute the determinant
std:: cout << "Determinant by default method  : " << 
A.det() << std::endl;
std:: cout << "Determinant by LU decomposition: " << 
A.det(vpMatrix::LU_DECOMPOSITION ) << std::endl;
}

Examples:: testMatrixInverse.cpp.

Definition at line 3496 of file vpMatrix.cpp.

References vpMatrix::LU_DECOMPOSITION.

void vpMatrix::diag ( const vpColVector & A )

inherited

Create a diagonal matrix with the element of a vector.

Parameters

A	: Vector which element will be put in the diagonal.

See also: createDiagonalMatrix()

#include <iostream>
#include <visp/vpColVector.h>
#include <visp/vpMatrix.h>
int main()
{
vpMatrix A;
vpColVector v(3);
v[0] = 1;
v[1] = 2;
v[2] = 3;
A.diag(v);
std::cout << "A:\n" << A << std::endl;
// A is now equal to:
// 1 0 0
// 0 2 0
// 0 0 3
}

Definition at line 2572 of file vpMatrix.cpp.

References vpMatrix::getRows(), vpMatrix::resize(), vpCERROR, and vpERROR_TRACE.

Referenced by vpMbEdgeKltTracker::computeVVS(), vpMbKltTracker::computeVVS(), and vpMbEdgeTracker::computeVVS().

vpColVector vpMatrix::eigenValues ( )

inherited

Compute the eigenvalues of a n-by-n real symmetric matrix.

Returns: The eigenvalues of a n-by-n real symmetric matrix.

Warning: This method is only available if the Gnu Scientific Library (GSL) is detected as a third party library.

Exceptions

vpMatrixException::matrixError	If the matrix is not square or if the matrix is not symmetric.
vpMatrixException::notImplementedError	If the GSL library is not detected

Here an example:

#include <iostream>
#include <visp/vpColVector.h>
#include <visp/vpMatrix.h>
int main()
{
vpMatrix A(3,3); // A is a symmetric matrix
A[0][0] = 1/1.; A[0][1] = 1/2.; A[0][2] = 1/3.;
A[1][0] = 1/2.; A[1][1] = 1/3.; A[1][2] = 1/4.;
A[2][0] = 1/3.; A[2][1] = 1/4.; A[2][2] = 1/5.;
std::cout << "Initial symmetric matrix: \n" << A << std::endl;
// Compute the eigen values
vpColVector evalue; // Eigenvalues
evalue = A.eigenValues();
std::cout << "Eigen values: \n" << evalue << std::endl;
}

See also: eigenValues(vpColVector &, vpMatrix &)

Definition at line 3079 of file vpMatrix.cpp.

References vpMatrix::colNum, vpMatrixException::matrixError, vpMatrixException::notImplementedError, vpMatrix::rowNum, vpMatrix::t(), and vpERROR_TRACE.

void vpMatrix::eigenValues	(	vpColVector &	evalue,
		vpMatrix &	evector
	)

inherited

Compute the eigenvalues of a n-by-n real symmetric matrix.

Returns: The eigenvalues of a n-by-n real symmetric matrix.

Warning: This method is only available if the Gnu Scientific Library (GSL) is detected as a third party library.

Parameters

evalue	: Eigenvalues of the matrix.
evector	: Eigenvector of the matrix.

Exceptions

vpMatrixException::matrixError	If the matrix is not square or if the matrix is not symmetric.
vpMatrixException::notImplementedError	If the GSL library is not detected

Here an example:

#include <iostream>
#include <visp/vpColVector.h>
#include <visp/vpMatrix.h>
int main()
{
vpMatrix A(4,4); // A is a symmetric matrix
A[0][0] = 1/1.; A[0][1] = 1/2.; A[0][2] = 1/3.; A[0][3] = 1/4.;
A[1][0] = 1/2.; A[1][1] = 1/3.; A[1][2] = 1/4.; A[1][3] = 1/5.;
A[2][0] = 1/3.; A[2][1] = 1/4.; A[2][2] = 1/5.; A[2][3] = 1/6.;
A[3][0] = 1/4.; A[3][1] = 1/5.; A[3][2] = 1/6.; A[3][3] = 1/7.;
std::cout << "Initial symmetric matrix: \n" << A << std::endl;
vpColVector d; // Eigenvalues
vpMatrix    V; // Eigenvectors
// Compute the eigenvalues and eigenvectors
A.eigenValues(d, V);
std::cout << "Eigen values: \n" << d << std::endl;
std::cout << "Eigen vectors: \n" << V << std::endl;
vpMatrix D;
D.diag(d); // Eigenvalues are on the diagonal
std::cout << "D: " << D << std::endl;
// Verification: A * V = V * D
std::cout << "AV-VD = 0 ? \n" << (A*V) - (V*D) << std::endl;
}

See also: eigenValues()

Definition at line 3198 of file vpMatrix.cpp.

References vpMatrix::colNum, vpMatrix::data, vpMatrixException::matrixError, vpMatrixException::notImplementedError, vpColVector::resize(), vpMatrix::resize(), vpMatrix::rowNum, vpMatrix::t(), and vpERROR_TRACE.

double vpMatrix::euclideanNorm ( ) const

inherited

Compute and return the Euclidean norm $||x|| = \sqrt{ \sum{x_{ij}^2}}$ .

Returns: The Euclidean norm if the matrix is initialized, 0 otherwise.

See also: infinityNorm()

Definition at line 2899 of file vpMatrix.cpp.

References vpMatrix::data, and vpMatrix::dsize.

Referenced by vpSimulatorAfma6::setPosition().

vpMatrix vpMatrix::expm ( )

inherited

Compute the exponential matrix of a square matrix.

Returns: Return the exponential matrix.

Definition at line 3868 of file vpMatrix.cpp.

References vpMatrix::colNum, vpMatrix::data, vpMatrixException::incorrectMatrixSizeError, vpMatrix::inverseByLU(), vpMatrix::rowNum, vpMatrix::setIdentity(), and vpTRACE.

Referenced by vpTemplateTrackerWarpHomographySL3::computeCoeff().

void vpMatrix::eye ( unsigned int n )

inherited

Set an n-by-n matrix to identity.

eye(n) is an n-by-n matrix with ones on the diagonal and zeros else where.

Examples:: testMatrix.cpp.

Definition at line 1181 of file vpMatrix.cpp.

References vpCERROR, and vpERROR_TRACE.

Referenced by vpServo::setServo().

void vpMatrix::eye	(	unsigned int	m,
		unsigned int	n
	)

inherited

Set an m-by-n matrix to identity.

eye(m,n) is an m-by-n matrix with ones on the diagonal and zeros else where.

Definition at line 1201 of file vpMatrix.cpp.

References vpMatrix::colNum, vpMatrix::resize(), vpMatrix::rowNum, vpCERROR, and vpERROR_TRACE.

unsigned int vpMatrix::getCols ( ) const

inlineinherited

Return the number of columns of the matrix.

Examples:: servoViper850Point2DArtVelocity-jointAvoidance-basic.cpp, testMatrixInverse.cpp, and testSvd.cpp.

Definition at line 163 of file vpMatrix.h.

Referenced by vpMatrix::add2Matrices(), vpMatrix::add2WeightedMatrices(), vpSubRowVector::checkParentStatus(), vpSubMatrix::checkParentStatus(), vpServo::computeControlLaw(), vpMatrix::computeHLM(), vpServo::computeInteractionMatrix(), vpMbTracker::computeJTR(), vpMatrix::cond(), vpMatrix::csvPrint(), vpImageSimulator::getImage(), vpSubRowVector::init(), vpSubMatrix::init(), vpCameraParameters::initFromCalibrationMatrix(), vpMatrix::insert(), vpMatrix::inverseByCholeskyLapack(), vpMatrix::inverseByQRLapack(), vpMatrix::juxtaposeMatrices(), vpMatrix::kernel(), vpMatrix::kron(), vpMatrix::maplePrint(), vpRowVector::operator*(), vpRotationMatrix::operator*(), vpVelocityTwistMatrix::operator*(), operator*(), vpMatrix::operator*(), vpMatrix::operator+=(), vpMatrix::operator-=(), vpSubRowVector::operator=(), vpRowVector::operator=(), vpSubColVector::operator=(), vpSubMatrix::operator=(), vpRotationMatrix::operator=(), vpColVector::operator=(), vpHomography::operator=(), vpPose::poseDementhonPlan(), vpMatrix::print(), vpMatrix::pseudoInverse(), vpIoTools::readConfigVar(), vpRowVector::reshape(), vpColVector::reshape(), vpMatrix::row(), vpMatrix::saveMatrix(), vpMatrix::saveMatrixYAML(), vpServo::secondaryTask(), vpRowVector::size(), vpMatrix::stackMatrices(), vpMatrix::sub2Matrices(), and vpMatrix::svd().

double vpMatrix::getMaxValue ( ) const

inherited

Examples:: servoMomentImage.cpp.

Definition at line 3969 of file vpMatrix.cpp.

References vpMatrix::data, and vpMatrix::dsize.

double vpMatrix::getMinValue ( ) const

inherited

Examples:: servoMomentImage.cpp.

Definition at line 3955 of file vpMatrix.cpp.

References vpMatrix::data, and vpMatrix::dsize.

unsigned int vpMatrix::getRows ( ) const

inlineinherited

Return the number of rows of the matrix.

Examples:: testMatrixInverse.cpp, and testSvd.cpp.

Definition at line 161 of file vpMatrix.h.

Referenced by vpMatrix::add2Matrices(), vpMatrix::add2WeightedMatrices(), vpLine::changeFrame(), vpSubColVector::checkParentStatus(), vpSubMatrix::checkParentStatus(), vpMatrix::column(), vpServo::computeError(), vpMatrix::computeHLM(), vpServo::computeInteractionMatrix(), vpMbTracker::computeJTR(), vpPtu46::computeMGD(), vpPose::computeResidual(), vpMbEdgeKltTracker::computeVVS(), vpMbKltTracker::computeVVS(), vpMbEdgeTracker::computeVVS(), vpMatrix::cppPrint(), vpMatrix::createDiagonalMatrix(), vpColVector::crossProd(), vpMatrix::csvPrint(), vpDot2::defineDots(), vpMatrix::diag(), vpProjectionDisplay::display(), vpColVector::dotProd(), vpGenericFeature::error(), vpImageFilter::filter(), vpPtu46::get_eJe(), vpBiclops::get_eJe(), vpPtu46::get_fJe(), vpBiclops::get_fJe(), vpBiclops::get_fMe(), vpGenericFeature::get_s(), vpBasicFeature::getDimension(), vpImageSimulator::getImage(), vpAfma6::getInverseKinematics(), vpViper::getInverseKinematicsWrist(), vpSubColVector::init(), vpSubMatrix::init(), vpCameraParameters::initFromCalibrationMatrix(), vpMatrix::insert(), vpFeatureLuminance::interaction(), vpGenericFeature::interaction(), vpMatrix::inverseByCholeskyLapack(), vpMatrix::inverseByLU(), vpMatrix::inverseByQRLapack(), vpColVector::invSort(), vpMatrix::juxtaposeMatrices(), vpMatrix::kernel(), vpScale::KernelDensity(), vpScale::KernelDensityGradient(), vpMatrix::kron(), vpMatrix::maplePrint(), vpMatrix::matlabPrint(), vpColVector::mean(), vpScale::MeanShift(), vpColVector::median(), vpRobust::MEstimator(), vpMatrix::multMatrixVector(), vpRowVector::operator*(), vpRotationMatrix::operator*(), vpVelocityTwistMatrix::operator*(), operator*(), vpMatrix::operator*(), vpMatrix::operator+=(), vpMatrix::operator-=(), vpColVector::operator<<(), vpSubColVector::operator=(), vpSubMatrix::operator=(), vpSubRowVector::operator=(), vpRotationMatrix::operator=(), vpColVector::operator=(), vpRGBa::operator=(), vpHomography::operator=(), vpPlot::plot(), vpPose::poseDementhonPlan(), vpPose::poseVirtualVSrobust(), vpKalmanFilter::prediction(), vpMatrix::print(), vpLine::projection(), vpMatrix::pseudoInverse(), vpIoTools::readConfigVar(), vpRowVector::reshape(), vpColVector::reshape(), vpMatrix::saveMatrix(), vpMatrix::saveMatrixYAML(), vpGenericFeature::set_s(), vpGenericFeature::setError(), vpGenericFeature::setInteractionMatrix(), vpSimulatorAfma6::setJointLimit(), vpSimulatorViper850::setJointLimit(), vpRobotBiclopsController::setPosition(), vpRobotAfma4::setPosition(), vpRobotBiclopsController::setVelocity(), vpRobotPtu46::setVelocity(), vpRobotBiclops::setVelocity(), vpSimulatorAfma6::setVelocity(), vpSimulatorViper850::setVelocity(), vpRobotAfma4::setVelocity(), vpLine::setWorldCoordinates(), vpRobust::simultMEstimator(), vpColVector::size(), vpColVector::skew(), vpColVector::sort(), vpColVector::stack(), vpMatrix::stackMatrices(), vpMatrix::sub2Matrices(), vpMatrix::svd(), and vpColVector::vpColVector().

double vpMatrix::infinityNorm ( ) const

inherited

Compute and return the infinity norm ${||x||}_{\infty} = max\left(\sum_{j=0}^{n}{\mid x_{ij} \mid}\right)$ with $i \in \{0, ..., m\}$ where $(m,n)$ is the matrix size.

Returns: The infinity norm if the matrix is initialized, 0 otherwise.

See also: euclideanNorm()

Definition at line 2923 of file vpMatrix.cpp.

References vpMatrix::colNum, vpMatrix::rowNum, and vpMatrix::rowPtrs.

void vpForceTwistMatrix::init ( )

Initialize the force/torque 6 by 6 twist matrix as identity.

Definition at line 87 of file vpForceTwistMatrix.cpp.

References vpMatrix::resize(), and vpERROR_TRACE.

Referenced by operator=(), setIdentity(), and vpForceTwistMatrix().

void vpMatrix::init	(	const vpMatrix &	m,
		unsigned int	r,
		unsigned int	c,
		unsigned int	nrows,
		unsigned int	ncols
	)

inherited

subvpMatrix extraction

Definition at line 272 of file vpMatrix.cpp.

References vpMatrix::resize(), and vpERROR_TRACE.

void vpMatrix::insert	(	const vpMatrix &	A,
		const unsigned int	r,
		const unsigned int	c
	)

inherited

Insert matrix A at the given position in the current matrix.

Warning: Throw vpMatrixException::incorrectMatrixSizeError if the dimensions of the matrices do not allow the operation.

Parameters

A	: The matrix to insert.
r	: The index of the row to begin to insert data.
c	: The index of the column to begin to insert data.

Definition at line 3022 of file vpMatrix.cpp.

References vpMatrix::colNum, vpMatrix::getCols(), vpMatrix::getRows(), vpMatrixException::incorrectMatrixSizeError, and vpMatrix::rowNum.

Referenced by vpNurbs::curveKnotIns(), vpMatrix::insert(), vpPioneerPan::set_mMp(), and vpPioneerPan::set_pMe().

vpMatrix vpMatrix::insert	(	const vpMatrix &	A,
		const vpMatrix &	B,
		const unsigned int	r,
		const unsigned int	c
	)

staticinherited

Insert matrix B in matrix A at the given position.

Parameters

A	: Main matrix.
B	: Matrix to insert.
r	: Index of the row where to add the matrix.
c	: Index of the column where to add the matrix.

Returns: Matrix with B insert in A.

Warning: Throw exception if the sizes of the matrices do not allow the insertion.

Definition at line 2397 of file vpMatrix.cpp.

References vpMatrix::insert(), and vpCERROR.

void insert	(	const vpMatrix &	A,
		const vpMatrix &	B,
		vpMatrix &	C,
		const unsigned int	r,
		const unsigned int	c
	)

staticinherited

Insert matrix B in matrix A at the given position.

Parameters

A	: Main matrix.
B	: Matrix to insert.
C	: Result matrix.
r	: Index of the row where to insert matrix B.
c	: Index of the column where to insert matrix B.

Warning: Throw exception if the sizes of the matrices do not allow the insertion.

Definition at line 2428 of file vpMatrix.cpp.

References vpMatrix::getCols(), vpMatrix::getRows(), vpMatrixException::incorrectMatrixSizeError, vpMatrix::resize(), vpCERROR, and vpERROR_TRACE.

vpMatrix vpMatrix::inverseByCholesky ( ) const

inherited

Compute the inverse of a n-by-n matrix using the Cholesky decomposition. The matrix must be real and symmetric. Only available if lapack is installed.

Returns: The inverse matrix.

Here an example:

#include <visp/vpMatrix.h>
int main()
{
  vpMatrix A(4,4);
  // Symmetric matrix
  A[0][0] = 1/1.; A[0][1] = 1/5.; A[0][2] = 1/6.; A[0][3] = 1/7.;
  A[1][0] = 1/5.; A[1][1] = 1/3.; A[1][2] = 1/3.; A[1][3] = 1/5.;
  A[2][0] = 1/6.; A[2][1] = 1/3.; A[2][2] = 1/2.; A[2][3] = 1/6.;
  A[3][0] = 1/7.; A[3][1] = 1/5.; A[3][2] = 1/6.; A[3][3] = 1/7.;
  // Compute the inverse
  vpMatrix A_1; // A^-1
  A_1 = A.inverseByCholesky();
  std::cout << "Inverse by Cholesky: \n" << A_1 << std::endl;
  std::cout << "A*A^-1: \n" << A * A_1 << std::endl;
}

See also: pseudoInverse()

Definition at line 122 of file vpMatrix_cholesky.cpp.

References vpMatrix::colNum, vpMatrix::inverseByCholeskyLapack(), vpMatrixException::matrixError, vpMatrix::rowNum, and vpERROR_TRACE.

vpMatrix vpMatrix::inverseByCholeskyLapack ( ) const

inherited

Definition at line 62 of file vpMatrix_cholesky.cpp.

References vpException::badValue, vpMatrix::data, vpMatrix::getCols(), and vpMatrix::getRows().

Referenced by vpMatrix::inverseByCholesky().

vpMatrix vpMatrix::inverseByLU ( ) const

inherited

Compute the inverse of a n-by-n matrix using the LU decomposition.

Returns: The inverse matrix.

Here an example:

#include <visp/vpMatrix.h>
int main()
{
  vpMatrix A(4,4);
  A[0][0] = 1/1.; A[0][1] = 1/2.; A[0][2] = 1/3.; A[0][3] = 1/4.;
  A[1][0] = 1/5.; A[1][1] = 1/3.; A[1][2] = 1/3.; A[1][3] = 1/5.;
  A[2][0] = 1/6.; A[2][1] = 1/4.; A[2][2] = 1/2.; A[2][3] = 1/6.;
  A[3][0] = 1/7.; A[3][1] = 1/5.; A[3][2] = 1/6.; A[3][3] = 1/7.;
  // Compute the inverse
  vpMatrix A_1; // A^-1
  A_1 = A.inverseByLU();
  std::cout << "Inverse by LU: \n" << A_1 << std::endl;
  std::cout << "A*A^-1: \n" << A * A_1 << std::endl;
}

See also: pseudoInverse()

Examples:: photometricVisualServoing.cpp.

Definition at line 236 of file vpMatrix_lu.cpp.

References vpMatrix::colNum, vpMatrix::getRows(), vpMatrixException::matrixError, vpMatrix::rowNum, and vpERROR_TRACE.

Referenced by vpMatrix::expm(), vpKalmanFilter::filtering(), vpTemplateTrackerWarpHomographySL3::findWarp(), vpTemplateTrackerWarpAffine::getParamInverse(), vpTemplateTrackerTriangle::init(), vpTemplateTrackerSSDInverseCompositional::initCompInverse(), vpTemplateTrackerZNCCForwardAdditional::initHessienDesired(), vpTemplateTrackerZNCCInverseCompositional::initHessienDesired(), vpTemplateTracker::setHDes(), vpTemplateTrackerSSDForwardCompositional::trackNoPyr(), and vpTemplateTrackerSSDForwardAdditional::trackNoPyr().

vpMatrix vpMatrix::inverseByQR ( ) const

inherited

Compute the inverse of a n-by-n matrix using the QR decomposition. Only available if lapack is installed.

Returns: The inverse matrix.

Here an example:

#include <visp/vpMatrix.h>
int main()
{
  vpMatrix A(4,4);
  A[0][0] = 1/1.; A[0][1] = 1/2.; A[0][2] = 1/3.; A[0][3] = 1/4.;
  A[1][0] = 1/5.; A[1][1] = 1/3.; A[1][2] = 1/3.; A[1][3] = 1/5.;
  A[2][0] = 1/6.; A[2][1] = 1/4.; A[2][2] = 1/2.; A[2][3] = 1/6.;
  A[3][0] = 1/7.; A[3][1] = 1/5.; A[3][2] = 1/6.; A[3][3] = 1/7.;
  // Compute the inverse
  vpMatrix A_1; // A^-1
  A_1 = A.inverseByQR();
  std::cout << "Inverse by QR: \n" << A_1 << std::endl;
  std::cout << "A*A^-1: \n" << A * A_1 << std::endl;
}

See also: pseudoInverse()

Definition at line 228 of file vpMatrix_qr.cpp.

References vpMatrix::colNum, vpMatrix::inverseByQRLapack(), vpMatrixException::matrixError, vpMatrix::rowNum, and vpERROR_TRACE.

vpMatrix vpMatrix::inverseByQRLapack ( ) const

inherited

Definition at line 76 of file vpMatrix_qr.cpp.

References vpException::badValue, vpMatrix::data, vpMatrix::getCols(), and vpMatrix::getRows().

Referenced by vpMatrix::inverseByQR().

vpMatrix vpMatrix::juxtaposeMatrices	(	const vpMatrix &	A,
		const vpMatrix &	B
	)

staticinherited

Juxtapose to matrices C = [ A B ].

$C = \left( \begin{array}{cc} A & B \end{array}\right)$

Parameters

A	: Left matrix.
B	: Right matrix.

Returns: Juxtaposed matrix C = [ A B ]

Warning: A and B must have the same number of column

Definition at line 2471 of file vpMatrix.cpp.

References vpCERROR.

void juxtaposeMatrices	(	const vpMatrix &	A,
		const vpMatrix &	B,
		vpMatrix &	C
	)

staticinherited

Juxtapose to matrices C = [ A B ].

$C = \left( \begin{array}{cc} A & B \end{array}\right)$

Parameters

A	: Left matrix.
B	: Right matrix.
C	: Juxtaposed matrix C = [ A B ]

Warning: A and B must have the same number of column

Definition at line 2500 of file vpMatrix.cpp.

References vpMatrix::getCols(), vpMatrix::getRows(), vpMatrixException::incorrectMatrixSizeError, vpMatrix::resize(), vpCERROR, and vpERROR_TRACE.

unsigned int vpMatrix::kernel	(	vpMatrix &	kerA,
		double	svThreshold = `1e-6`
	)

inherited

Function to compute the null space (the kernel) of the interaction matrix A which is not full rank. The null space ( the kernel ) of a matrix A is defined as Null(A) = Ker(M) ={KerA : A*KerA =0}.

Parameters

kerA	: The matrix to contain the null space (kernel) of A (A*KerA.t()=0)
svThreshold	: Specify the used threshold in the svd(...) function (a function to compute the singular value decomposition)

Returns: the rank of the matrix.

Examples:: servoViper850Point2DArtVelocity-jointAvoidance-basic.cpp.

Definition at line 3300 of file vpMatrix.cpp.

References vpMatrix::getCols(), vpMatrix::getRows(), vpMatrix::resize(), vpMatrix::row(), vpMatrix::sumSquare(), and vpMatrix::svd().

void vpMatrix::kill ( )

inherited

Destruction of the matrix (Memory de-allocation)

Definition at line 295 of file vpMatrix.cpp.

References vpMatrix::data, and vpMatrix::rowPtrs.

Referenced by vpMatrix::~vpMatrix().

void vpMatrix::kron	(	const vpMatrix &	m1,
		const vpMatrix &	m2,
		vpMatrix &	out
	)

staticinherited

Compute Kronecker product matrix.

Parameters

m1	: vpMatrix;
m2	: vpMatrix;
out	: The kronecker product : $m1 \otimes m2$

Definition at line 1492 of file vpMatrix.cpp.

References vpMatrix::colNum, vpMatrix::getCols(), vpMatrix::getRows(), vpMatrixException::incorrectMatrixSizeError, vpMatrix::rowNum, and vpERROR_TRACE.

Referenced by vpMatrix::kron().

vpMatrix vpMatrix::kron	(	const vpMatrix &	m1,
		const vpMatrix &	m2
	)

staticinherited

Compute Kronecker product matrix.

Parameters

m1	: vpMatrix;
m2	: vpMatrix;

Returns: The kronecker product : $m1 \otimes m2$

Definition at line 1536 of file vpMatrix.cpp.

References vpMatrix::getCols(), and vpMatrix::getRows().

void vpMatrix::kron	(	const vpMatrix &	m,
		vpMatrix &	out
	)

inherited

Compute Kronecker product matrix.

Parameters

m	: vpMatrix.
out	: If m1.kron(m2) out contains the kronecker product's result : $m1 \otimes m2$ .

Definition at line 1526 of file vpMatrix.cpp.

References vpMatrix::kron().

vpMatrix vpMatrix::kron ( const vpMatrix & m )

inherited

Compute Kronecker product matrix.

Parameters

m	: vpMatrix;

Returns: m1.kron(m2) The kronecker product : $m1 \otimes m2$

Definition at line 1567 of file vpMatrix.cpp.

References vpMatrix::kron().

static bool vpMatrix::loadMatrix	(	std::string	filename,
		vpMatrix &	M,
		const bool	binary = `false`,
		char *	Header = `NULL`
	)

inlinestaticinherited

Load a matrix from a file.

Parameters

filename	: absolute file name
M	: matrix to be loaded
binary	:If true the matrix is loaded from a binary file, else from a text file.
Header	: Header of the file is loaded in this parameter

Returns: Returns true if no problem appends.

Definition at line 262 of file vpMatrix.h.

Referenced by vpDot2::defineDots().

bool vpMatrix::loadMatrix	(	const char *	filename,
		vpMatrix &	M,
		const bool	binary = `false`,
		char *	header = `NULL`
	)

staticinherited

Load a matrix from a file.

Parameters

filename	: Absolute file name.
M	: Matrix to be loaded.
binary	: If true the matrix is loaded from a binary file, else from a text file.
header	: header of the file loaded in this parameter.

Returns: Returns true if no problem happened.

Definition at line 3694 of file vpMatrix.cpp.

References vpException::badValue, and vpMatrix::resize().

static bool vpMatrix::loadMatrixYAML	(	std::string	filename,
		vpMatrix &	M,
		char *	header = `NULL`
	)

inlinestaticinherited

Load a matrix from a YAML-formatted file.

Parameters

filename	: absolute file name.
M	: matrix to be loaded from the file.
header	: Header of the file is loaded in this parameter.

Returns: Returns true if no problem appends.

Definition at line 315 of file vpMatrix.h.

bool vpMatrix::loadMatrixYAML	(	const char *	filename,
		vpMatrix &	M,
		char *	header = `NULL`
	)

staticinherited

Load a matrix from a YAML-formatted file.

Parameters

filename	: absolute file name.
M	: matrix to be loaded from the file.
header	: header of the file is loaded in this parameter.

Returns: Returns true on success.

See also: saveMatrixYAML()

Definition at line 3791 of file vpMatrix.cpp.

References vpMatrix::resize().

std::ostream & vpMatrix::maplePrint ( std::ostream & os ) const

inherited

Print using MAPLE matrix input format.

Print using the following way so that this output can be directly copied into MAPLE: ([ [0.939846, 0.0300754, 0.340272, ], [0.0300788, 0.984961, -0.170136, ], [-0.340272, 0.170136, 0.924807, ], ])

Definition at line 2792 of file vpMatrix.cpp.

References vpMatrix::getCols(), and vpMatrix::getRows().

std::ostream & vpMatrix::matlabPrint ( std::ostream & os ) const

inherited

Print using matlab syntax, to be put in matlab later.

Print using the following form: [ a,b,c; d,e,f; g,h,i]

Definition at line 2763 of file vpMatrix.cpp.

References vpMatrix::getRows().

void vpMatrix::mult2Matrices	(	const vpMatrix &	A,
		const vpMatrix &	B,
		vpMatrix &	C
	)

staticinherited

Operation C = A * B.

The result is placed in the third parameter C and not returned. A new matrix won't be allocated for every use of the function (Speed gain if used many times with the same result matrix size).

See also: operator*()

Definition at line 420 of file vpMatrix.cpp.

References vpMatrix::colNum, vpMatrixException::incorrectMatrixSizeError, vpMatrix::resize(), vpMatrix::rowNum, vpMatrix::rowPtrs, and vpERROR_TRACE.

Referenced by vpMatrix::operator*().

void vpMatrix::multMatrixVector	(	const vpMatrix &	A,
		const vpColVector &	b,
		vpColVector &	c
	)

staticinherited

Operation c = A * b (c and b are vectors).

The result is placed in the second parameter C and not returned. A new matrix won't be allocated for every use of the function (Speed gain if used many times with the same result matrix size).

See also: operator*(const vpColVector &b) const

Definition at line 860 of file vpMatrix.cpp.

References vpMatrix::colNum, vpMatrix::getRows(), vpMatrixException::incorrectMatrixSizeError, vpColVector::resize(), vpMatrix::rowNum, vpMatrix::rowPtrs, and vpERROR_TRACE.

Referenced by vpRotationMatrix::operator*(), and vpMatrix::operator*().

void vpMatrix::negateMatrix	(	const vpMatrix &	A,
		vpMatrix &	C
	)

staticinherited

Operation C = -A.

The result is placed in the second parameter C and not returned. A new matrix won't be allocated for every use of the function (Speed gain if used many times with the same result matrix size).

See also: operator-(void)

Definition at line 758 of file vpMatrix.cpp.

References vpMatrix::colNum, vpMatrix::resize(), vpMatrix::rowNum, vpMatrix::rowPtrs, and vpERROR_TRACE.

Referenced by vpMatrix::operator-().

vpForceTwistMatrix vpForceTwistMatrix::operator* ( const vpForceTwistMatrix & F ) const

Operator that allows to multiply a skew transformation matrix by an other skew transformation matrix.

#include <visp/vpForceTwistMatrix.h>
int main()
{
  vpForceTwistMatrix aFb, bFc;
  // ... initialize the force/torque twist transformations aFb and bFc
  // Compute the force/torque transformation from frame a to c
  vpForceTwistMatrix aFc = aFb * bFc;
}

Definition at line 247 of file vpForceTwistMatrix.cpp.

References vpMatrix::rowPtrs.

vpMatrix vpForceTwistMatrix::operator* ( const vpMatrix & M ) const

Operator that allows to multiply a skew transformation matrix by a matrix.

Exceptions

vpMatrixException::incorrectMatrixSizeError If M is not a 6 rows dimension matrix.

Definition at line 269 of file vpForceTwistMatrix.cpp.

References vpMatrix::getCols(), vpMatrix::getRows(), vpMatrixException::incorrectMatrixSizeError, vpMatrix::rowPtrs, and vpERROR_TRACE.

vpColVector vpForceTwistMatrix::operator* ( const vpColVector & H ) const

Operator that allows to multiply a skew transformation matrix by a column vector.

Parameters

H	: Force/torque skew vector ${\bf H} = [f_x, f_y, f_z, \tau_x, \tau_y, \tau_z]$ .

For example, this operator can be used to convert a force/torque skew from sensor frame into the probe frame :

$^p{\bf H} = ^p{\bf F}_s \; ^s{\bf H}$

The example below shows how to handle that transformation.

#include <visp/vpConfig.h>
#include <visp/vpRobotViper850.h>
#include <visp/vpColVector.h>
#include <visp/vpForceTwistMatrix.h>
int main()
{
  // Get the force/torque measures from the sensor
  vpColVector sH(6); // Force/torque measures given by the sensor
#ifdef VISP_HAVE_VIPER850
  vpRobotViper850 robot;
  robot.getForceTorque(sH); // Get the force/torque measures 
#endif  
  // Set the transformation from sensor frame to the probe frame
  vpHomogeneousMatrix pMs;
  pMs[2][3] = -0.262; // tz only
  // Set the force/torque twist transformation
  vpForceTwistMatrix pFs(pMs); // Twist transformation matrix from probe to sensor frame
  // Compute the resulting force/torque in the probe frame
  vpColVector pH(6); // Force/torque in the probe frame
  pH = pFs * sH;
 
  return 0;
}

Exceptions

vpMatrixException::incorrectMatrixSizeError If $\bf H$ is not a 6 dimension vector.

Definition at line 341 of file vpForceTwistMatrix.cpp.

References vpMatrix::getRows(), vpMatrixException::incorrectMatrixSizeError, vpMatrix::rowPtrs, and vpERROR_TRACE.

vpMatrix vpMatrix::operator* ( const vpHomography & H ) const

inherited

Allows to multiply a matrix by an homography. Operation M = K * H (H is unchanged).

Definition at line 476 of file vpMatrix.cpp.

References vpMatrix::colNum, vpException::dimensionError, and vpMatrix::rowNum.

vpTranslationVector vpMatrix::operator* ( const vpTranslationVector & b ) const

inherited

Operation c = A * b (A is unchanged, c and b are translation vectors).

Definition at line 904 of file vpMatrix.cpp.

References vpMatrix::colNum, vpMatrixException::incorrectMatrixSizeError, vpMatrix::rowNum, vpMatrix::rowPtrs, and vpERROR_TRACE.

vpMatrix vpMatrix::operator* ( const double x ) const

inherited

Cij = Aij * x (A is unchanged)

Definition at line 979 of file vpMatrix.cpp.

References vpMatrix::colNum, vpMatrix::resize(), vpMatrix::rowNum, vpMatrix::rowPtrs, and vpERROR_TRACE.

vpMatrix & vpMatrix::operator*= ( const double x )

inherited

Multiply all the element of the matrix by x : Aij = Aij * x.

Definition at line 1107 of file vpMatrix.cpp.

References vpMatrix::colNum, vpMatrix::rowNum, and vpMatrix::rowPtrs.

vpMatrix vpMatrix::operator+ ( const vpMatrix & B ) const

inherited

Operation C = A + B (A is unchanged).

See also: add2Matrices() to avoid matrix allocation for each use.

Definition at line 593 of file vpMatrix.cpp.

References vpMatrix::add2Matrices().

vpMatrix & vpMatrix::operator+= ( const vpMatrix & B )

inherited

Operation A = A + B.

Definition at line 673 of file vpMatrix.cpp.

References vpMatrix::colNum, vpMatrix::getCols(), vpMatrix::getRows(), vpMatrixException::incorrectMatrixSizeError, vpMatrix::rowNum, vpMatrix::rowPtrs, and vpERROR_TRACE.

vpMatrix & vpMatrix::operator+= ( const double x )

inherited

Add x to all the element of the matrix : Aij = Aij + x.

Definition at line 1059 of file vpMatrix.cpp.

References vpMatrix::colNum, vpMatrix::rowNum, and vpMatrix::rowPtrs.

vpMatrix vpMatrix::operator- ( const vpMatrix & B ) const

inherited

Operation C = A - B (A is unchanged).

See also: sub2Matrices() to avoid matrix allocation for each use.

Definition at line 664 of file vpMatrix.cpp.

References vpMatrix::sub2Matrices().

vpMatrix vpMatrix::operator- ( void ) const

inherited

Operation C = -A (A is unchanged).

See also: negateMatrix() to avoid matrix allocation for each use.

Definition at line 800 of file vpMatrix.cpp.

References vpMatrix::negateMatrix().

vpMatrix & vpMatrix::operator-= ( const vpMatrix & B )

inherited

Operation A = A - B.

Definition at line 713 of file vpMatrix.cpp.

References vpMatrix::colNum, vpMatrix::getCols(), vpMatrix::getRows(), vpMatrixException::incorrectMatrixSizeError, vpMatrix::rowNum, vpMatrix::rowPtrs, and vpERROR_TRACE.

vpMatrix & vpMatrix::operator-= ( const double x )

inherited

Substract x to all the element of the matrix : Aij = Aij - x.

Definition at line 1083 of file vpMatrix.cpp.

References vpMatrix::colNum, vpMatrix::rowNum, and vpMatrix::rowPtrs.

vpMatrix vpMatrix::operator/ ( const double x ) const

inherited

Cij = Aij / x (A is unchanged)

Definition at line 1014 of file vpMatrix.cpp.

References vpMatrix::colNum, vpException::divideByZeroError, vpMatrix::resize(), vpMatrix::rowNum, vpMatrix::rowPtrs, vpCERROR, and vpERROR_TRACE.

vpMatrix & vpMatrix::operator/= ( double x )

inherited

Divide all the element of the matrix by x : Aij = Aij / x.

Definition at line 1122 of file vpMatrix.cpp.

References vpMatrix::colNum, vpException::divideByZeroError, vpMatrix::rowNum, and vpMatrix::rowPtrs.

vpMatrix & vpMatrix::operator<< ( double * x )

inherited

Assigment from an array of double.

Definition at line 395 of file vpMatrix.cpp.

References vpMatrix::colNum, vpMatrix::rowNum, and vpMatrix::rowPtrs.

vpForceTwistMatrix & vpForceTwistMatrix::operator= ( const vpForceTwistMatrix & M )

Copy operator.

Parameters

M	: Force/torque twist matrix to copy.

Definition at line 68 of file vpForceTwistMatrix.cpp.

References init(), and vpMatrix::rowPtrs.

double* vpMatrix::operator[] ( unsigned int i )

inlineinherited

write elements Aij (usage : A[i][j] = x )

Definition at line 218 of file vpMatrix.h.

double* vpMatrix::operator[] ( unsigned int i ) const

inlineinherited

read elements Aij (usage : x = A[i][j] )

Definition at line 220 of file vpMatrix.h.

int vpMatrix::print	(	std::ostream &	s,
		unsigned int	length,
		char const *	intro = `0`
	)

inherited

Pretty print a matrix. The data are tabulated. The common widths before and after the decimal point are set with respect to the parameter maxlen.

Parameters

s	Stream used for the printing.
length	The suggested width of each matrix element. The actual width grows in order to accomodate the whole integral part, and shrinks if the whole extent is not needed for all the numbers.
intro	The introduction which is printed before the matrix. Can be set to zero (or omitted), in which case the introduction is not printed.

Returns: Returns the common total width for all matrix elements

See also: std::ostream &operator <<(ostream &s,const vpMatrix &m)

Examples:: servoSimu3D_cdMc_CamVelocity.cpp, servoSimu3D_cMcd_CamVelocity.cpp, testMatrix.cpp, and testTwistMatrix.cpp.

Definition at line 2668 of file vpMatrix.cpp.

References vpMatrix::getCols(), vpMatrix::getRows(), and vpMath::maximum().

void vpMatrix::printSize ( )

inlineinherited

Definition at line 188 of file vpMatrix.h.

vpMatrix vpMatrix::pseudoInverse ( double svThreshold = 1e-6 ) const

inherited

Compute the pseudo inverse of the matrix using the SVD.

Compute and return the pseudo inverse of a n-by-m matrix : $ A^+ $ .

Parameters

svThreshold : Threshold used to test the singular values.

Returns: Pseudo inverse of the matrix.

Here an example to compute the inverse of a n-by-n matrix. If the matrix is n-by-n it is also possible to use inverseByLU().

#include <visp/vpMatrix.h>
int main()
{
vpMatrix A(4,4);
A[0][0] = 1/1.; A[0][1] = 1/2.; A[0][2] = 1/3.; A[0][3] = 1/4.;
A[1][0] = 1/5.; A[1][1] = 1/3.; A[1][2] = 1/3.; A[1][3] = 1/5.;
A[2][0] = 1/6.; A[2][1] = 1/4.; A[2][2] = 1/2.; A[2][3] = 1/6.;
A[3][0] = 1/7.; A[3][1] = 1/5.; A[3][2] = 1/6.; A[3][3] = 1/7.;
// Compute the inverse
vpMatrix A_1; // A^-1
A_1 = A.pseudoInverse();
std::cout << "Inverse by pseudo inverse: \n" << A_1 << std::endl;
std::cout << "A*A^-1: \n" << A * A_1 << std::endl;
}

See also: inverseByLU()

Definition at line 1861 of file vpMatrix.cpp.

Referenced by vpCalibration::calibrationTsai(), vpSimulatorAfma6::computeArticularVelocity(), vpSimulatorViper850::computeArticularVelocity(), vpServo::computeControlLaw(), vpMatrix::computeCovarianceMatrix(), vpMbEdgeKltTracker::computeVVS(), vpMbKltTracker::computeVVS(), vpMbEdgeTracker::computeVVS(), vpNurbs::globalCurveApprox(), vpNurbs::globalCurveInterp(), vpMeEllipse::initTracking(), vpHomography::inverse(), vpMeLine::leastSquare(), vpPose::poseDementhonNonPlan(), vpPose::poseFromRectangle(), vpPose::poseVirtualVS(), vpMatrix::pseudoInverse(), vpHomography::robust(), and vpMatrix::solveBySVD().

unsigned int vpMatrix::pseudoInverse	(	vpMatrix &	Ap,
		double	svThreshold = `1e-6`
	)		const

inherited

Compute the pseudo inverse of the matrix $Ap = A^+$ .

Compute the pseudo inverse of the matrix using the SVD. return the rank

Parameters

Ap	: The pseudo inverse .
svThreshold	: Threshold used to test the singular values.

Returns: Return the rank of the matrix A

Definition at line 1821 of file vpMatrix.cpp.

References vpMatrix::pseudoInverse().

unsigned int vpMatrix::pseudoInverse	(	vpMatrix &	Ap,
		vpColVector &	sv,
		double	svThreshold = `1e-6`
	)		const

inherited

Compute the pseudo inverse of the matrix $Ap = A^+$ .

Compute the pseudo inverse of the matrix using the SVD. return the rank and the singular value

Parameters

Ap	: The pseudo inverse .
sv	: Singular values.
svThreshold	: Threshold used to test the singular values.

Returns: Return the rank of the matrix A

Definition at line 1877 of file vpMatrix.cpp.

References vpMatrix::pseudoInverse().

unsigned int vpMatrix::pseudoInverse	(	vpMatrix &	Ap,
		vpColVector &	sv,
		double	svThreshold,
		vpMatrix &	imA,
		vpMatrix &	imAt
	)		const

inherited

Compute the pseudo inverse of the matrix $Ap = A^+$ along with Ker A, Ker $A^T$ , Im A and Im $A^T$ .

Compute the pseudo inverse of the matrix using the SVD. return the rank and the singular value, image

Pseudo inverse, kernel and image are computed using the SVD decomposition.

A is an m x n matrix, if m >=n the svd works on A other wise it works on $A^T$ .

Therefore if m>=n we have

${\bf A}_{m\times n} = {\bf U}_{m\times m} {\bf S}_{m\times n} {\bf V^\top}_{n\times n}$

${\bf A}_{m\times n} = \left[\begin{array}{ccc}\mbox{Im} {\bf A} & | & \mbox{Ker} {\bf A^\top} \end{array} \right] {\bf S} \left[ \begin{array}{c} (\mbox{Im} {\bf A^\top})^\top \\ (\mbox{Ker}{\bf A})^\top \end{array}\right]$

where Im(A) is an m x r matrix (r is the rank of A) and Im(A^T) is an r x n matrix

Parameters

Ap	: The pseudo inverse .
sv	: Singular values.
svThreshold	: Threshold used to test the singular values.
imAt	: Image A^T
imA	Image A

Returns: Return the rank of the matrix A

Definition at line 1916 of file vpMatrix.cpp.

References vpMatrix::getCols(), vpMatrix::getRows(), vpColVector::resize(), vpMatrix::resize(), vpMatrix::svd(), and vpMatrix::t().

unsigned int vpMatrix::pseudoInverse	(	vpMatrix &	Ap,
		vpColVector &	sv,
		double	svThreshold,
		vpMatrix &	imA,
		vpMatrix &	imAt,
		vpMatrix &	kerA
	)		const

inherited

Compute the pseudo inverse of the matrix $Ap = A^+$ along with Ker A, Ker $A^T$ , Im A and Im $A^T$ .

Compute the pseudo inverse of the matrix using the SVD. return the rank and the singular value, image, kernel.

Pseudo inverse, kernel and image are computed using the SVD decomposition.

A is an m x n matrix, if m >=n the svd works on A other wise it works on $A^T$ .

Therefore if m>=n we have

${\bf A}_{m\times n} = {\bf U}_{m\times m} {\bf S}_{m\times n} {\bf V^\top}_{n\times n}$

${\bf A}_{m\times n} = \left[\begin{array}{ccc}\mbox{Im} {\bf A} & | & \mbox{Ker} {\bf A^\top} \end{array} \right] {\bf S} \left[ \begin{array}{c} (\mbox{Im} {\bf A^\top})^\top \\ (\mbox{Ker}{\bf A})^\top \end{array}\right]$

where Im(A) is an m x r matrix (r is the rank of A) and Im(A^T) is an r x n matrix

Parameters

Ap	: The pseudo inverse .
sv	: Singular values.
svThreshold	: Threshold used to test the singular values.
imA	Image A
imAt	: Image A^T
kerA	: null space of A

Returns: Return the rank of the matrix A

Definition at line 2094 of file vpMatrix.cpp.

References vpMatrix::getCols(), vpMatrix::getRows(), vpColVector::resize(), vpMatrix::resize(), vpMatrix::row(), vpMatrix::sumSquare(), vpMatrix::svd(), and vpMatrix::t().

void vpMatrix::resize	(	const unsigned int	nrows,
		const unsigned int	ncols,
		const bool	flagNullify = `true`
	)

inherited

Set the size of the matrix and initialize all the values to zero.

Parameters

nrows	: number of rows
ncols	: number of column
flagNullify	: if true, then the matrix is re-initialized to 0 after resize. If false, the initial values from the common part of the matrix (common part between old and new version of the matrix) are kept. Default value is true.

Returns: OK or MEMORY_FAULT if memory cannot be allocated

Examples:: testMatrix.cpp, testMatrixInverse.cpp, and testSvd.cpp.

Definition at line 183 of file vpMatrix.cpp.

References vpMatrix::colNum, vpMatrix::data, vpMatrix::dsize, vpException::memoryAllocationError, vpMatrix::rowNum, vpMatrix::rowPtrs, vpMatrix::trsize, vpCDEBUG, vpDEBUG_TRACE, and vpERROR_TRACE.

vpRowVector vpMatrix::row ( const unsigned int j )

inherited

Row extraction.

Return the ith rows of the matrix.

Warning: notice row(1) is the 0th row.

Definition at line 2274 of file vpMatrix.cpp.

References vpMatrix::getCols().

Referenced by vpMatrix::kernel(), and vpMatrix::pseudoInverse().

static bool vpMatrix::saveMatrix	(	std::string	filename,
		const vpMatrix &	M,
		const bool	binary = `false`,
		const char *	Header = `""`
	)

inlinestaticinherited

Save a matrix to a file.

Parameters

filename	: absolute file name
M	: matrix to be saved
binary	:If true the matrix is save in a binary file, else a text file.
Header	: optional line that will be saved at the beginning of the file

Returns: Returns true if no problem appends.

Warning : If you save the matrix as in a text file the precision is less than if you save it in a binary file.

Definition at line 283 of file vpMatrix.h.

Referenced by vpDot2::defineDots().

bool vpMatrix::saveMatrix	(	const char *	filename,
		const vpMatrix &	M,
		const bool	binary = `false`,
		const char *	header = `""`
	)

staticinherited

Save a matrix to a file.

Parameters

filename	: Absolute file name.
M	: Matrix to be saved.
binary	: If true the matrix is saved in a binary file, else a text file.
header	: Optional line that will be saved at the beginning of the file.

Returns: Returns true if no problem happened.

Warning : If you save the matrix as in a text file the precision is less than if you save it in a binary file.

Definition at line 3523 of file vpMatrix.cpp.

References vpMatrix::getCols(), and vpMatrix::getRows().

static bool vpMatrix::saveMatrixYAML	(	std::string	filename,
		const vpMatrix &	M,
		const char *	header = `""`
	)

inlinestaticinherited

Save a matrix in a YAML-formatted file.

Parameters

filename	: absolute file name.
M	: matrix to be saved in the file.
header	: optional lines that will be saved at the beginning of the file. Should be YAML-formatted and will adapt to the indentation if any.

Returns: Returns true if success.

Definition at line 301 of file vpMatrix.h.

bool vpMatrix::saveMatrixYAML	(	const char *	filename,
		const vpMatrix &	M,
		const char *	header = `""`
	)

staticinherited

Save a matrix in a YAML-formatted file.

Parameters

filename	: absolute file name.
M	: matrix to be saved in the file.
header	: optional lines that will be saved at the beginning of the file. Should be YAML-formatted and will adapt to the indentation if any.

Returns: Returns true if success.

Here is an example of outputs.

vpMatrix M(3,4);
vpMatrix::saveMatrixYAML("matrix.yml", M, "example: a YAML-formatted header");
vpMatrix::saveMatrixYAML("matrixIndent.yml", M, "example:\n    - a YAML-formatted header\n    - with inner indentation");

Content of matrix.yml:

example: a YAML-formatted header
rows: 3
cols: 4
data:
  - [0, 0, 0, 0]
  - [0, 0, 0, 0]
  - [0, 0, 0, 0]

Content of matrixIndent.yml:

example:
    - a YAML-formatted header
    - with inner indentation
rows: 3
cols: 4
data:
    - [0, 0, 0, 0]
    - [0, 0, 0, 0]
    - [0, 0, 0, 0]

See also: loadMatrixYAML()

Definition at line 3623 of file vpMatrix.cpp.

References vpMatrix::getCols(), and vpMatrix::getRows().

void vpForceTwistMatrix::setIdentity ( )

Set the twist transformation matrix to identity.

Definition at line 222 of file vpForceTwistMatrix.cpp.

References init().

void vpMatrix::setIdentity ( const double & val = 1.0 )

inherited

By default set the matrix to identity. More generally set M[i][i] = val.

Definition at line 1159 of file vpMatrix.cpp.

References vpMatrix::colNum, vpMatrixException::matrixError, vpMatrix::rowNum, and vpERROR_TRACE.

Referenced by vpServo::computeControlLaw(), vpMatrix::expm(), vpTemplateTrackerWarpHomographySL3::getdW0(), vpTemplateTrackerWarpHomographySL3::getdWdp0(), vpFeatureThetaU::interaction(), vpMeLine::leastSquare(), vpPose::poseFromRectangle(), and vpServo::secondaryTask().

void vpMatrix::solveBySVD	(	const vpColVector &	b,
		vpColVector &	x
	)		const

inherited

Solve a linear system $ A X = B $ using Singular Value Decomposition (SVD).

Non destructive wrt. A and B.

Parameters

b	: Vector .
x	: Vector .

Here an example:

#include <visp/vpColVector.h>
#include <visp/vpMatrix.h>
int main()
{
vpMatrix A(3,3);
A[0][0] = 4.64; 
A[0][1] = 0.288; 
A[0][2] = -0.384; 
A[1][0] = 0.288; 
A[1][1] = 7.3296; 
A[1][2] = 2.2272; 
A[2][0] = -0.384; 
A[2][1] = 2.2272; 
A[2][2] = 6.0304; 
vpColVector X(3), B(3);
B[0] = 1;
B[1] = 2;
B[2] = 3;
A.solveBySVD(B, X);
// Obtained values of X
// X[0] = 0.2468; 
// X[1] = 0.120782; 
// X[2] = 0.468587; 
std::cout << "X:\n" << X << std::endl;
}

See also: solveBySVD(const vpColVector &)

Definition at line 1622 of file vpMatrix.cpp.

References vpMatrix::pseudoInverse().

Referenced by vpMatrix::solveBySVD().

vpColVector vpMatrix::solveBySVD ( const vpColVector & B ) const

inherited

Solve a linear system $ A X = B $ using Singular Value Decomposition (SVD).

Non destructive wrt. A and B.

Parameters

B	: Vector .

Returns: Vector .

Here an example:

#include <visp/vpColVector.h>
#include <visp/vpMatrix.h>
int main()
{
vpMatrix A(3,3);
A[0][0] = 4.64; 
A[0][1] = 0.288; 
A[0][2] = -0.384; 
A[1][0] = 0.288; 
A[1][1] = 7.3296; 
A[1][2] = 2.2272; 
A[2][0] = -0.384; 
A[2][1] = 2.2272; 
A[2][2] = 6.0304; 
vpColVector X(3), B(3);
B[0] = 1;
B[1] = 2;
B[2] = 3;
X = A.solveBySVD(B);
// Obtained values of X
// X[0] = 0.2468; 
// X[1] = 0.120782; 
// X[2] = 0.468587; 
std::cout << "X:\n" << X << std::endl;
}

See also: solveBySVD(const vpColVector &, vpColVector &)

Definition at line 1677 of file vpMatrix.cpp.

References vpMatrix::colNum, and vpMatrix::solveBySVD().

void vpMatrix::stackColumns ( vpColVector & out )

inherited

Stacks columns of a matrix in a vector.

Parameters

out	: a vpColVector.

Definition at line 1422 of file vpMatrix.cpp.

References vpMatrix::colNum, vpMatrix::data, vpColVector::resize(), vpMatrix::rowNum, vpMatrix::rowPtrs, vpCERROR, and vpERROR_TRACE.

vpColVector vpMatrix::stackColumns ( )

inherited

Stacks columns of a matrix in a vector.

Returns: a vpColVector.

Definition at line 1446 of file vpMatrix.cpp.

References vpMatrix::colNum, and vpMatrix::rowNum.

void vpMatrix::stackMatrices ( const vpMatrix & A )

inherited

Stack A at the end of the current matrix, or copy if the matrix has no dimensions : this = [ this A ]^T

Here an example for a robot velocity log :

vpMatrix Velocities;
vpColVector v(6);
for(unsigned int i = 0;i<100;i++)
{
  robot.getVelocity(vpRobot::ARTICULAR_FRAME, v);
  Velocities.stackMatrices(v.t());
}

Examples:: servoPioneerPoint2DDepthWithoutVpServo.cpp.

Definition at line 3003 of file vpMatrix.cpp.

References vpMatrix::rowNum.

vpMatrix vpMatrix::stackMatrices	(	const vpMatrix &	A,
		const vpMatrix &	B
	)

staticinherited

Stack two Matrices C = [ A B ]^T.

Stack matrices. "Stack" two matrices C = [ A B ]^T.

$C = \left( \begin{array}{c} A \\ B \end{array}\right)$

Parameters

A	: Upper matrix.
B	: Lower matrix.

Returns: Stacked matrix C = [ A B ]^T

Warning: A and B must have the same number of column.

Definition at line 2312 of file vpMatrix.cpp.

References vpMatrix::stackMatrices(), and vpCERROR.

void stackMatrices	(	const vpMatrix &	A,
		const vpMatrix &	B,
		vpMatrix &	C
	)

staticinherited

Stack two Matrices C = [ A B ]^T.

stackMatrices. "stack" two matrices C = [ A B ]^T

$C = \left( \begin{array}{c} A \\ B \end{array}\right)$

Parameters

A	: Upper matrix.
B	: Lower matrix.
C	: Stacked matrix C = [ A B ]^T

Warning: A and B must have the same number of column

Definition at line 2341 of file vpMatrix.cpp.

References vpMatrix::getCols(), vpMatrix::getRows(), vpMatrixException::incorrectMatrixSizeError, vpMatrix::resize(), vpCERROR, and vpERROR_TRACE.

void vpMatrix::stackRows ( vpRowVector & out )

inherited

Stacks rows of a matrix in a vector

Parameters

out	: a vpRowVector.

Definition at line 1457 of file vpMatrix.cpp.

References vpMatrix::colNum, vpMatrix::data, vpMatrix::dsize, vpRowVector::resize(), vpMatrix::rowNum, vpCERROR, and vpERROR_TRACE.

vpRowVector vpMatrix::stackRows ( )

inherited

Stacks rows of a matrix in a vector.

Returns: a vpRowVector.

Definition at line 1479 of file vpMatrix.cpp.

References vpMatrix::colNum, and vpMatrix::rowNum.

void vpMatrix::sub2Matrices	(	const vpMatrix &	A,
		const vpMatrix &	B,
		vpMatrix &	C
	)

staticinherited

Operation C = A - B.

The result is placed in the third parameter C and not returned. A new matrix won't be allocated for every use of the function (Speed gain if used many times with the same result matrix size).

See also: operator-()

Definition at line 611 of file vpMatrix.cpp.

References vpMatrix::colNum, vpMatrix::getCols(), vpMatrix::getRows(), vpMatrixException::incorrectMatrixSizeError, vpMatrix::resize(), vpMatrix::rowNum, vpMatrix::rowPtrs, and vpERROR_TRACE.

Referenced by vpMatrix::operator-().

double vpMatrix::sumSquare ( ) const

inherited

return sum of the Aij^2 (for all i, for all j)

Examples:: photometricVisualServoing.cpp, servoAfma62DhalfCamVelocity.cpp, servoAfma6SquareLines2DCamVelocity.cpp, servoMomentImage.cpp, tutorial-simu-pioneer-continuous-gain-adaptive.cpp, tutorial-simu-pioneer-continuous-gain-constant.cpp, tutorial-simu-pioneer-pan.cpp, and tutorial-simu-pioneer.cpp.

Definition at line 809 of file vpMatrix.cpp.

References vpMatrix::colNum, vpMatrix::rowNum, and vpMatrix::rowPtrs.

Referenced by vpPose::calculArbreDementhon(), vpCalibration::calibrationTsai(), vpPose::coplanar(), vpFeatureDepth::error(), vpFeatureThetaU::error(), vpFeatureTranslation::error(), vpMbTracker::extractCylinders(), vpFeatureThetaU::interaction(), vpMatrix::kernel(), vpRowVector::normalize(), vpColVector::normalize(), vpPose::poseDementhonNonPlan(), vpPose::poseDementhonPlan(), vpPose::poseFromRectangle(), vpPose::poseLagrangeNonPlan(), vpPose::poseLagrangePlan(), vpPose::poseVirtualVS(), vpPose::poseVirtualVSrobust(), vpMatrix::pseudoInverse(), vpServoData::save(), vpSimulatorAfma6::setPosition(), and vpSimulatorViper850::setPosition().

void vpMatrix::svd	(	vpColVector &	w,
		vpMatrix &	v
	)

inherited

Singular value decomposition (SVD).

$M = U \Sigma V^{\top}$

Warning: Destructive method wrt. to the matrix to decompose. You should make a COPY of that matrix if needed not to CHANGE.

Parameters

w	: Vector of singular values. $\Sigma = diag(w)$ .
v	: Matrix .

Returns: Matrix .

Warning: If the GNU Scientific Library (GSL) third party library is used to compute the SVD decomposition, the singular values $\Sigma_{i,i}$ are ordered in decreasing fashion in w. This is not the case, if the GSL is not detected by ViSP.

Here an example of SVD decomposition of a non square Matrix M.

#include <visp/vpColVector.h>
#include <visp/vpMatrix.h>
int main()
{
vpMatrix M(3,2);
M[0][0] = 1;
M[1][0] = 2;
M[2][0] = 0.5;
M[0][1] = 6;
M[1][1] = 8 ;
M[2][1] = 9 ;
vpMatrix v;
vpColVector w;
vpMatrix Mrec;
vpMatrix Sigma;
M.svd(w, v); 
// Here M is modified and is now equal to U
// Construct the diagonal matrix from the singular values
Sigma.diag(w);
// Reconstruct the initial matrix M using the decomposition
Mrec =  M * Sigma * v.t();
// Here, Mrec is obtained equal to the initial value of M
// Mrec[0][0] = 1;
// Mrec[1][0] = 2;
// Mrec[2][0] = 0.5;
// Mrec[0][1] = 6;
// Mrec[1][1] = 8 ;
// Mrec[2][1] = 9 ;
std::cout << "Reconstructed M matrix: \n" << Mrec << std::endl;
}

Examples:: servoMomentImage.cpp.

Definition at line 1751 of file vpMatrix.cpp.

References vpMatrix::getCols(), vpMatrix::getRows(), vpColVector::resize(), and vpMatrix::resize().

Referenced by vpHomography::computeDisplacement(), vpMatrix::cond(), vpHomography::DLT(), vpMatrix::kernel(), vpPose::poseDementhonPlan(), and vpMatrix::pseudoInverse().

vpMatrix vpMatrix::t ( ) const

inherited

Compute and return the transpose of the matrix.

Examples:: photometricVisualServoing.cpp, and servoViper850Point2DArtVelocity-jointAvoidance-basic.cpp.

Definition at line 1225 of file vpMatrix.cpp.

References vpMatrix::colNum, vpMatrix::resize(), vpMatrix::rowNum, vpCERROR, and vpERROR_TRACE.

Referenced by vpCalibration::calibrationTsai(), vpServo::computeControlLaw(), vpMatrix::computeCovarianceMatrix(), vpTemplateTracker::computeOptimalBrentGain(), vpMatrix::eigenValues(), vpKalmanFilter::filtering(), vpTemplateTrackerWarpHomographySL3::findWarp(), vpPose::poseDementhonNonPlan(), vpPose::poseDementhonPlan(), vpKalmanFilter::prediction(), and vpMatrix::pseudoInverse().

vpMatrix vpMatrix::transpose ( ) const

inherited

Compute and return the transpose of the matrix.

See also: t()

Definition at line 1255 of file vpMatrix.cpp.

Referenced by vpTemplateTrackerWarpSRT::getParamInverse().

void vpMatrix::transpose ( vpMatrix & At ) const

inherited

Compute At the transpose of the matrix.

Parameters

At	: Resulting transpose matrix.

See also: t()

Definition at line 1267 of file vpMatrix.cpp.

References vpMatrix::colNum, vpMatrix::resize(), vpMatrix::rowNum, vpMatrix::rowPtrs, vpCERROR, and vpERROR_TRACE.

Friends And Related Function Documentation

vpMatrix operator*	(	const double &	x,
		const vpMatrix &	B
	)

Definition at line 935 of file vpMatrix.cpp.

References vpMatrix::getCols(), vpMatrix::getRows(), vpMatrix::resize(), and vpERROR_TRACE.

void skew	(	const vpTranslationVector &	t,
		vpMatrix &	M
	)

$\mbox{if} \quad {\bf t} = \left( \begin{array}{c} t_x \\ t_y \\ t_z \end{array}\right), \quad \mbox{then} \qquad M = \left( \begin{array}{ccc} 0 & -t_z & t_y \\ t_z & 0 & -t_x \\ -t_y & t_x & 0 \end{array}\right)$

Parameters

t	: Translation vector in input used to compute the skew symmetric matrix M.
M	: Skew symmetric matrix of translation vector .

Examples:: servoSimuSphere.cpp.

Definition at line 296 of file vpTranslationVector.cpp.

References vpMatrix::resize().

void vpGEMM	(	const vpMatrix &	A,
		const vpMatrix &	B,
		const double &	alpha,
		const vpMatrix &	C,
		const double &	beta,
		vpMatrix &	D,
		const unsigned int &	ops = `0`
	)

For example, to compute alpha*A^T*B^T+beta*C we need to call :

vpGEMM(A,B,alpha,C,beta, VP_GEMM_A_T + VP_GEMM_B_T);

If C is not used, vpGEMM must be called using an empty matrix null :

vpGEMM(A,B,alpha,C, null,0);

Exceptions

vpMatrixException::incorrectMatrixSizeError if the sizes of the matrices do not allow the operations.

Parameters

A	: a Matrix
B	: a Matrix
alpha	: a scalar
C	: a Matrix
beta	: a scalar
D	: a Matrix
ops	: a scalar describing operation applied on the matrices

Examples:: testMatrix.cpp.

Definition at line 331 of file vpGEMM.h.

References vpMatrixException::incorrectMatrixSizeError, and vpERROR_TRACE.

enum vpGEMMmethod

Operations are :

VP_GEMM_A_T to use the transpose matrix of A instead of the matrix A
VP_GEMM_B_T to use the transpose matrix of B instead of the matrix B
VP_GEMM_C_T to use the transpose matrix of C instead of the matrix C

Definition at line 63 of file vpGEMM.h.

friend class vpMatrix

friend

Definition at line 106 of file vpForceTwistMatrix.h.

Member Data Documentation

unsigned int vpMatrix::colNum

protectedinherited

number of columns

Definition at line 114 of file vpMatrix.h.

double* vpMatrix::data

inherited

address of the first element of the data array

Definition at line 118 of file vpMatrix.h.

Referenced by vpMatrix::AtA(), vpSubColVector::checkParentStatus(), vpSubRowVector::checkParentStatus(), vpSubMatrix::checkParentStatus(), vpPose::computeResidual(), vpPose::computeTransformation(), vpColVector::dotProd(), vpMatrix::eigenValues(), vpMatrix::euclideanNorm(), vpMatrix::expm(), vpRobotViper650::getForceTorque(), vpRobotViper850::getForceTorque(), vpMatrix::getMaxValue(), vpMatrix::getMinValue(), vpRobotViper650::getPosition(), vpRobotViper850::getPosition(), vpRobotViper850::getVelocity(), vpRobotViper650::getVelocity(), vpSubColVector::init(), vpSubRowVector::init(), vpSubMatrix::init(), vpMatrix::init(), vpRobotViper650::init(), vpRobotViper850::init(), vpMatrix::inverseByCholeskyLapack(), vpMatrix::inverseByQRLapack(), vpColVector::invSort(), vpMatrix::kill(), vpColVector::mean(), vpColVector::median(), vpRowVector::operator*(), vpColVector::operator*(), vpTranslationVector::operator*(), vpColVector::operator+(), vpTranslationVector::operator-(), vpColVector::operator-(), vpSubColVector::operator=(), vpSubRowVector::operator=(), vpRowVector::operator=(), vpColVector::operator=(), vpTranslationVector::operator=(), vpMatrix::operator=(), vpRowVector::operator[](), vpColVector::operator[](), vpPose::ransac(), vpRowVector::reshape(), vpColVector::reshape(), vpMatrix::resize(), vpRobotAfma4::setPosition(), vpRobotViper650::setPosition(), vpRobotViper850::setPosition(), vpRobotAfma4::setVelocity(), vpRobotAfma6::setVelocity(), vpRobotViper650::setVelocity(), vpRobotViper850::setVelocity(), vpColVector::sort(), vpMatrix::stackColumns(), vpMatrix::stackRows(), vpRowVector::t(), vpColVector::t(), vpColVector::vpColVector(), vpMatrix::vpMatrix(), vpSubColVector::~vpSubColVector(), vpSubMatrix::~vpSubMatrix(), and vpSubRowVector::~vpSubRowVector().

unsigned int vpMatrix::dsize

protectedinherited

Current size (rowNum * colNum)

Definition at line 124 of file vpMatrix.h.

Referenced by vpMatrix::euclideanNorm(), vpMatrix::getMaxValue(), vpMatrix::getMinValue(), vpSubColVector::init(), vpSubRowVector::init(), vpSubMatrix::init(), vpMatrix::init(), vpTranslationVector::operator*(), vpTranslationVector::operator-(), vpMatrix::operator=(), vpRowVector::reshape(), vpColVector::reshape(), vpMatrix::resize(), and vpMatrix::stackRows().

unsigned int vpMatrix::rowNum

protectedinherited

number of rows

Definition at line 112 of file vpMatrix.h.

double** vpMatrix::rowPtrs

protectedinherited

address of the first element of each rows

Definition at line 121 of file vpMatrix.h.

unsigned int vpMatrix::trsize

protectedinherited

Total row space.

Definition at line 126 of file vpMatrix.h.

Referenced by vpSubColVector::init(), vpSubRowVector::init(), vpSubMatrix::init(), vpMatrix::init(), and vpMatrix::resize().

Public Types

Public Member Functions

Static Public Member Functions

Public Attributes

Protected Attributes

Friends

Related Functions

Detailed Description

Member Enumeration Documentation

Constructor & Destructor Documentation

Member Function Documentation

Friends And Related Function Documentation

Member Data Documentation