// This file is part of Eigen, a lightweight C++ template library // for linear algebra. // // Copyright (C) 2009 Jitse Niesen // Copyright (C) 2012 Chen-Pang He // // This Source Code Form is subject to the terms of the Mozilla // Public License v. 2.0. If a copy of the MPL was not distributed // with this file, You can obtain one at http://mozilla.org/MPL/2.0/. #ifndef EIGEN_MATRIX_FUNCTIONS #define EIGEN_MATRIX_FUNCTIONS #include #include #include #include #include #include #include /** * \defgroup MatrixFunctions_Module Matrix functions module * \brief This module aims to provide various methods for the computation of * matrix functions. * * To use this module, add * \code * #include * \endcode * at the start of your source file. * * This module defines the following MatrixBase methods. * - \ref matrixbase_cos "MatrixBase::cos()", for computing the matrix cosine * - \ref matrixbase_cosh "MatrixBase::cosh()", for computing the matrix hyperbolic cosine * - \ref matrixbase_exp "MatrixBase::exp()", for computing the matrix exponential * - \ref matrixbase_log "MatrixBase::log()", for computing the matrix logarithm * - \ref matrixbase_pow "MatrixBase::pow()", for computing the matrix power * - \ref matrixbase_matrixfunction "MatrixBase::matrixFunction()", for computing general matrix functions * - \ref matrixbase_sin "MatrixBase::sin()", for computing the matrix sine * - \ref matrixbase_sinh "MatrixBase::sinh()", for computing the matrix hyperbolic sine * - \ref matrixbase_sqrt "MatrixBase::sqrt()", for computing the matrix square root * * These methods are the main entry points to this module. * * %Matrix functions are defined as follows. Suppose that \f$ f \f$ * is an entire function (that is, a function on the complex plane * that is everywhere complex differentiable). Then its Taylor * series * \f[ f(0) + f'(0) x + \frac{f''(0)}{2} x^2 + \frac{f'''(0)}{3!} x^3 + \cdots \f] * converges to \f$ f(x) \f$. In this case, we can define the matrix * function by the same series: * \f[ f(M) = f(0) + f'(0) M + \frac{f''(0)}{2} M^2 + \frac{f'''(0)}{3!} M^3 + \cdots \f] * */ #include "src/MatrixFunctions/MatrixExponential.h" #include "src/MatrixFunctions/MatrixFunction.h" #include "src/MatrixFunctions/MatrixSquareRoot.h" #include "src/MatrixFunctions/MatrixLogarithm.h" #include "src/MatrixFunctions/MatrixPower.h" /** \page matrixbaseextra_page \ingroup MatrixFunctions_Module \section matrixbaseextra MatrixBase methods defined in the MatrixFunctions module The remainder of the page documents the following MatrixBase methods which are defined in the MatrixFunctions module. \subsection matrixbase_cos MatrixBase::cos() Compute the matrix cosine. \code const MatrixFunctionReturnValue MatrixBase::cos() const \endcode \param[in] M a square matrix. \returns expression representing \f$ \cos(M) \f$. This function calls \ref matrixbase_matrixfunction "matrixFunction()" with StdStemFunctions::cos(). \sa \ref matrixbase_sin "sin()" for an example. \subsection matrixbase_cosh MatrixBase::cosh() Compute the matrix hyberbolic cosine. \code const MatrixFunctionReturnValue MatrixBase::cosh() const \endcode \param[in] M a square matrix. \returns expression representing \f$ \cosh(M) \f$ This function calls \ref matrixbase_matrixfunction "matrixFunction()" with StdStemFunctions::cosh(). \sa \ref matrixbase_sinh "sinh()" for an example. \subsection matrixbase_exp MatrixBase::exp() Compute the matrix exponential. \code const MatrixExponentialReturnValue MatrixBase::exp() const \endcode \param[in] M matrix whose exponential is to be computed. \returns expression representing the matrix exponential of \p M. The matrix exponential of \f$ M \f$ is defined by \f[ \exp(M) = \sum_{k=0}^\infty \frac{M^k}{k!}. \f] The matrix exponential can be used to solve linear ordinary differential equations: the solution of \f$ y' = My \f$ with the initial condition \f$ y(0) = y_0 \f$ is given by \f$ y(t) = \exp(M) y_0 \f$. The cost of the computation is approximately \f$ 20 n^3 \f$ for matrices of size \f$ n \f$. The number 20 depends weakly on the norm of the matrix. The matrix exponential is computed using the scaling-and-squaring method combined with Padé approximation. The matrix is first rescaled, then the exponential of the reduced matrix is computed approximant, and then the rescaling is undone by repeated squaring. The degree of the Padé approximant is chosen such that the approximation error is less than the round-off error. However, errors may accumulate during the squaring phase. Details of the algorithm can be found in: Nicholas J. Higham, "The scaling and squaring method for the matrix exponential revisited," SIAM J. %Matrix Anal. Applic., 26:1179–1193, 2005. Example: The following program checks that \f[ \exp \left[ \begin{array}{ccc} 0 & \frac14\pi & 0 \\ -\frac14\pi & 0 & 0 \\ 0 & 0 & 0 \end{array} \right] = \left[ \begin{array}{ccc} \frac12\sqrt2 & -\frac12\sqrt2 & 0 \\ \frac12\sqrt2 & \frac12\sqrt2 & 0 \\ 0 & 0 & 1 \end{array} \right]. \f] This corresponds to a rotation of \f$ \frac14\pi \f$ radians around the z-axis. \include MatrixExponential.cpp Output: \verbinclude MatrixExponential.out \note \p M has to be a matrix of \c float, \c double, \c long double \c complex, \c complex, or \c complex . \subsection matrixbase_log MatrixBase::log() Compute the matrix logarithm. \code const MatrixLogarithmReturnValue MatrixBase::log() const \endcode \param[in] M invertible matrix whose logarithm is to be computed. \returns expression representing the matrix logarithm root of \p M. The matrix logarithm of \f$ M \f$ is a matrix \f$ X \f$ such that \f$ \exp(X) = M \f$ where exp denotes the matrix exponential. As for the scalar logarithm, the equation \f$ \exp(X) = M \f$ may have multiple solutions; this function returns a matrix whose eigenvalues have imaginary part in the interval \f$ (-\pi,\pi] \f$. In the real case, the matrix \f$ M \f$ should be invertible and it should have no eigenvalues which are real and negative (pairs of complex conjugate eigenvalues are allowed). In the complex case, it only needs to be invertible. This function computes the matrix logarithm using the Schur-Parlett algorithm as implemented by MatrixBase::matrixFunction(). The logarithm of an atomic block is computed by MatrixLogarithmAtomic, which uses direct computation for 1-by-1 and 2-by-2 blocks and an inverse scaling-and-squaring algorithm for bigger blocks, with the square roots computed by MatrixBase::sqrt(). Details of the algorithm can be found in Section 11.6.2 of: Nicholas J. Higham, Functions of Matrices: Theory and Computation, SIAM 2008. ISBN 978-0-898716-46-7. Example: The following program checks that \f[ \log \left[ \begin{array}{ccc} \frac12\sqrt2 & -\frac12\sqrt2 & 0 \\ \frac12\sqrt2 & \frac12\sqrt2 & 0 \\ 0 & 0 & 1 \end{array} \right] = \left[ \begin{array}{ccc} 0 & \frac14\pi & 0 \\ -\frac14\pi & 0 & 0 \\ 0 & 0 & 0 \end{array} \right]. \f] This corresponds to a rotation of \f$ \frac14\pi \f$ radians around the z-axis. This is the inverse of the example used in the documentation of \ref matrixbase_exp "exp()". \include MatrixLogarithm.cpp Output: \verbinclude MatrixLogarithm.out \note \p M has to be a matrix of \c float, \c double, long double, \c complex, \c complex, or \c complex . \sa MatrixBase::exp(), MatrixBase::matrixFunction(), class MatrixLogarithmAtomic, MatrixBase::sqrt(). \subsection matrixbase_pow MatrixBase::pow() Compute the matrix raised to arbitrary real power. \code const MatrixPowerReturnValue MatrixBase::pow(RealScalar p) const \endcode \param[in] M base of the matrix power, should be a square matrix. \param[in] p exponent of the matrix power, should be real. The matrix power \f$ M^p \f$ is defined as \f$ \exp(p \log(M)) \f$, where exp denotes the matrix exponential, and log denotes the matrix logarithm. The matrix \f$ M \f$ should meet the conditions to be an argument of matrix logarithm. If \p p is not of the real scalar type of \p M, it is casted into the real scalar type of \p M. This function computes the matrix power using the Schur-Padé algorithm as implemented by class MatrixPower. The exponent is split into integral part and fractional part, where the fractional part is in the interval \f$ (-1, 1) \f$. The main diagonal and the first super-diagonal is directly computed. Details of the algorithm can be found in: Nicholas J. Higham and Lijing Lin, "A Schur-Padé algorithm for fractional powers of a matrix," SIAM J. %Matrix Anal. Applic., 32(3):1056–1078, 2011. Example: The following program checks that \f[ \left[ \begin{array}{ccc} \cos1 & -\sin1 & 0 \\ \sin1 & \cos1 & 0 \\ 0 & 0 & 1 \end{array} \right]^{\frac14\pi} = \left[ \begin{array}{ccc} \frac12\sqrt2 & -\frac12\sqrt2 & 0 \\ \frac12\sqrt2 & \frac12\sqrt2 & 0 \\ 0 & 0 & 1 \end{array} \right]. \f] This corresponds to \f$ \frac14\pi \f$ rotations of 1 radian around the z-axis. \include MatrixPower.cpp Output: \verbinclude MatrixPower.out MatrixBase::pow() is user-friendly. However, there are some circumstances under which you should use class MatrixPower directly. MatrixPower can save the result of Schur decomposition, so it's better for computing various powers for the same matrix. Example: \include MatrixPower_optimal.cpp Output: \verbinclude MatrixPower_optimal.out \note \p M has to be a matrix of \c float, \c double, long double, \c complex, \c complex, or \c complex . \sa MatrixBase::exp(), MatrixBase::log(), class MatrixPower. \subsection matrixbase_matrixfunction MatrixBase::matrixFunction() Compute a matrix function. \code const MatrixFunctionReturnValue MatrixBase::matrixFunction(typename internal::stem_function::Scalar>::type f) const \endcode \param[in] M argument of matrix function, should be a square matrix. \param[in] f an entire function; \c f(x,n) should compute the n-th derivative of f at x. \returns expression representing \p f applied to \p M. Suppose that \p M is a matrix whose entries have type \c Scalar. Then, the second argument, \p f, should be a function with prototype \code ComplexScalar f(ComplexScalar, int) \endcode where \c ComplexScalar = \c std::complex if \c Scalar is real (e.g., \c float or \c double) and \c ComplexScalar = \c Scalar if \c Scalar is complex. The return value of \c f(x,n) should be \f$ f^{(n)}(x) \f$, the n-th derivative of f at x. This routine uses the algorithm described in: Philip Davies and Nicholas J. Higham, "A Schur-Parlett algorithm for computing matrix functions", SIAM J. %Matrix Anal. Applic., 25:464–485, 2003. The actual work is done by the MatrixFunction class. Example: The following program checks that \f[ \exp \left[ \begin{array}{ccc} 0 & \frac14\pi & 0 \\ -\frac14\pi & 0 & 0 \\ 0 & 0 & 0 \end{array} \right] = \left[ \begin{array}{ccc} \frac12\sqrt2 & -\frac12\sqrt2 & 0 \\ \frac12\sqrt2 & \frac12\sqrt2 & 0 \\ 0 & 0 & 1 \end{array} \right]. \f] This corresponds to a rotation of \f$ \frac14\pi \f$ radians around the z-axis. This is the same example as used in the documentation of \ref matrixbase_exp "exp()". \include MatrixFunction.cpp Output: \verbinclude MatrixFunction.out Note that the function \c expfn is defined for complex numbers \c x, even though the matrix \c A is over the reals. Instead of \c expfn, we could also have used StdStemFunctions::exp: \code A.matrixFunction(StdStemFunctions >::exp, &B); \endcode \subsection matrixbase_sin MatrixBase::sin() Compute the matrix sine. \code const MatrixFunctionReturnValue MatrixBase::sin() const \endcode \param[in] M a square matrix. \returns expression representing \f$ \sin(M) \f$. This function calls \ref matrixbase_matrixfunction "matrixFunction()" with StdStemFunctions::sin(). Example: \include MatrixSine.cpp Output: \verbinclude MatrixSine.out \subsection matrixbase_sinh MatrixBase::sinh() Compute the matrix hyperbolic sine. \code MatrixFunctionReturnValue MatrixBase::sinh() const \endcode \param[in] M a square matrix. \returns expression representing \f$ \sinh(M) \f$ This function calls \ref matrixbase_matrixfunction "matrixFunction()" with StdStemFunctions::sinh(). Example: \include MatrixSinh.cpp Output: \verbinclude MatrixSinh.out \subsection matrixbase_sqrt MatrixBase::sqrt() Compute the matrix square root. \code const MatrixSquareRootReturnValue MatrixBase::sqrt() const \endcode \param[in] M invertible matrix whose square root is to be computed. \returns expression representing the matrix square root of \p M. The matrix square root of \f$ M \f$ is the matrix \f$ M^{1/2} \f$ whose square is the original matrix; so if \f$ S = M^{1/2} \f$ then \f$ S^2 = M \f$. In the real case, the matrix \f$ M \f$ should be invertible and it should have no eigenvalues which are real and negative (pairs of complex conjugate eigenvalues are allowed). In that case, the matrix has a square root which is also real, and this is the square root computed by this function. The matrix square root is computed by first reducing the matrix to quasi-triangular form with the real Schur decomposition. The square root of the quasi-triangular matrix can then be computed directly. The cost is approximately \f$ 25 n^3 \f$ real flops for the real Schur decomposition and \f$ 3\frac13 n^3 \f$ real flops for the remainder (though the computation time in practice is likely more than this indicates). Details of the algorithm can be found in: Nicholas J. Highan, "Computing real square roots of a real matrix", Linear Algebra Appl., 88/89:405–430, 1987. If the matrix is positive-definite symmetric, then the square root is also positive-definite symmetric. In this case, it is best to use SelfAdjointEigenSolver::operatorSqrt() to compute it. In the complex case, the matrix \f$ M \f$ should be invertible; this is a restriction of the algorithm. The square root computed by this algorithm is the one whose eigenvalues have an argument in the interval \f$ (-\frac12\pi, \frac12\pi] \f$. This is the usual branch cut. The computation is the same as in the real case, except that the complex Schur decomposition is used to reduce the matrix to a triangular matrix. The theoretical cost is the same. Details are in: Åke Björck and Sven Hammarling, "A Schur method for the square root of a matrix", Linear Algebra Appl., 52/53:127–140, 1983. Example: The following program checks that the square root of \f[ \left[ \begin{array}{cc} \cos(\frac13\pi) & -\sin(\frac13\pi) \\ \sin(\frac13\pi) & \cos(\frac13\pi) \end{array} \right], \f] corresponding to a rotation over 60 degrees, is a rotation over 30 degrees: \f[ \left[ \begin{array}{cc} \cos(\frac16\pi) & -\sin(\frac16\pi) \\ \sin(\frac16\pi) & \cos(\frac16\pi) \end{array} \right]. \f] \include MatrixSquareRoot.cpp Output: \verbinclude MatrixSquareRoot.out \sa class RealSchur, class ComplexSchur, class MatrixSquareRoot, SelfAdjointEigenSolver::operatorSqrt(). */ #endif // EIGEN_MATRIX_FUNCTIONS