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502 lines
17 KiB
Plaintext
502 lines
17 KiB
Plaintext
// This file is part of Eigen, a lightweight C++ template library
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// for linear algebra.
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//
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// Copyright (C) 2009 Jitse Niesen <jitse@maths.leeds.ac.uk>
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// Copyright (C) 2012 Chen-Pang He <jdh8@ms63.hinet.net>
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//
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// This Source Code Form is subject to the terms of the Mozilla
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// Public License v. 2.0. If a copy of the MPL was not distributed
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// with this file, You can obtain one at http://mozilla.org/MPL/2.0/.
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#ifndef EIGEN_MATRIX_FUNCTIONS
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#define EIGEN_MATRIX_FUNCTIONS
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#include <cfloat>
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#include <list>
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#include <Eigen/Core>
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#include <Eigen/LU>
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#include <Eigen/Eigenvalues>
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/**
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* \defgroup MatrixFunctions_Module Matrix functions module
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* \brief This module aims to provide various methods for the computation of
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* matrix functions.
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*
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* To use this module, add
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* \code
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* #include <unsupported/Eigen/MatrixFunctions>
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* \endcode
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* at the start of your source file.
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*
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* This module defines the following MatrixBase methods.
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* - \ref matrixbase_cos "MatrixBase::cos()", for computing the matrix cosine
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* - \ref matrixbase_cosh "MatrixBase::cosh()", for computing the matrix hyperbolic cosine
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* - \ref matrixbase_exp "MatrixBase::exp()", for computing the matrix exponential
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* - \ref matrixbase_log "MatrixBase::log()", for computing the matrix logarithm
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* - \ref matrixbase_pow "MatrixBase::pow()", for computing the matrix power
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* - \ref matrixbase_matrixfunction "MatrixBase::matrixFunction()", for computing general matrix functions
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* - \ref matrixbase_sin "MatrixBase::sin()", for computing the matrix sine
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* - \ref matrixbase_sinh "MatrixBase::sinh()", for computing the matrix hyperbolic sine
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* - \ref matrixbase_sqrt "MatrixBase::sqrt()", for computing the matrix square root
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*
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* These methods are the main entry points to this module.
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*
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* %Matrix functions are defined as follows. Suppose that \f$ f \f$
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* is an entire function (that is, a function on the complex plane
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* that is everywhere complex differentiable). Then its Taylor
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* series
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* \f[ f(0) + f'(0) x + \frac{f''(0)}{2} x^2 + \frac{f'''(0)}{3!} x^3 + \cdots \f]
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* converges to \f$ f(x) \f$. In this case, we can define the matrix
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* function by the same series:
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* \f[ f(M) = f(0) + f'(0) M + \frac{f''(0)}{2} M^2 + \frac{f'''(0)}{3!} M^3 + \cdots \f]
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*
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*/
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#include "src/MatrixFunctions/MatrixExponential.h"
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#include "src/MatrixFunctions/MatrixFunction.h"
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#include "src/MatrixFunctions/MatrixSquareRoot.h"
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#include "src/MatrixFunctions/MatrixLogarithm.h"
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#include "src/MatrixFunctions/MatrixPower.h"
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/**
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\page matrixbaseextra_page
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\ingroup MatrixFunctions_Module
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\section matrixbaseextra MatrixBase methods defined in the MatrixFunctions module
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The remainder of the page documents the following MatrixBase methods
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which are defined in the MatrixFunctions module.
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\subsection matrixbase_cos MatrixBase::cos()
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Compute the matrix cosine.
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\code
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const MatrixFunctionReturnValue<Derived> MatrixBase<Derived>::cos() const
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\endcode
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\param[in] M a square matrix.
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\returns expression representing \f$ \cos(M) \f$.
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This function computes the matrix cosine. Use ArrayBase::cos() for computing the entry-wise cosine.
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The implementation calls \ref matrixbase_matrixfunction "matrixFunction()" with StdStemFunctions::cos().
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\sa \ref matrixbase_sin "sin()" for an example.
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\subsection matrixbase_cosh MatrixBase::cosh()
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Compute the matrix hyberbolic cosine.
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\code
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const MatrixFunctionReturnValue<Derived> MatrixBase<Derived>::cosh() const
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\endcode
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\param[in] M a square matrix.
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\returns expression representing \f$ \cosh(M) \f$
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This function calls \ref matrixbase_matrixfunction "matrixFunction()" with StdStemFunctions::cosh().
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\sa \ref matrixbase_sinh "sinh()" for an example.
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\subsection matrixbase_exp MatrixBase::exp()
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Compute the matrix exponential.
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\code
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const MatrixExponentialReturnValue<Derived> MatrixBase<Derived>::exp() const
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\endcode
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\param[in] M matrix whose exponential is to be computed.
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\returns expression representing the matrix exponential of \p M.
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The matrix exponential of \f$ M \f$ is defined by
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\f[ \exp(M) = \sum_{k=0}^\infty \frac{M^k}{k!}. \f]
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The matrix exponential can be used to solve linear ordinary
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differential equations: the solution of \f$ y' = My \f$ with the
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initial condition \f$ y(0) = y_0 \f$ is given by
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\f$ y(t) = \exp(M) y_0 \f$.
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The matrix exponential is different from applying the exp function to all the entries in the matrix.
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Use ArrayBase::exp() if you want to do the latter.
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The cost of the computation is approximately \f$ 20 n^3 \f$ for
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matrices of size \f$ n \f$. The number 20 depends weakly on the
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norm of the matrix.
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The matrix exponential is computed using the scaling-and-squaring
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method combined with Padé approximation. The matrix is first
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rescaled, then the exponential of the reduced matrix is computed
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approximant, and then the rescaling is undone by repeated
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squaring. The degree of the Padé approximant is chosen such
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that the approximation error is less than the round-off
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error. However, errors may accumulate during the squaring phase.
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Details of the algorithm can be found in: Nicholas J. Higham, "The
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scaling and squaring method for the matrix exponential revisited,"
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<em>SIAM J. %Matrix Anal. Applic.</em>, <b>26</b>:1179–1193,
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2005.
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Example: The following program checks that
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\f[ \exp \left[ \begin{array}{ccc}
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0 & \frac14\pi & 0 \\
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-\frac14\pi & 0 & 0 \\
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0 & 0 & 0
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\end{array} \right] = \left[ \begin{array}{ccc}
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\frac12\sqrt2 & -\frac12\sqrt2 & 0 \\
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\frac12\sqrt2 & \frac12\sqrt2 & 0 \\
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0 & 0 & 1
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\end{array} \right]. \f]
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This corresponds to a rotation of \f$ \frac14\pi \f$ radians around
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the z-axis.
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\include MatrixExponential.cpp
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Output: \verbinclude MatrixExponential.out
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\note \p M has to be a matrix of \c float, \c double, \c long double
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\c complex<float>, \c complex<double>, or \c complex<long double> .
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\subsection matrixbase_log MatrixBase::log()
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Compute the matrix logarithm.
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\code
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const MatrixLogarithmReturnValue<Derived> MatrixBase<Derived>::log() const
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\endcode
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\param[in] M invertible matrix whose logarithm is to be computed.
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\returns expression representing the matrix logarithm root of \p M.
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The matrix logarithm of \f$ M \f$ is a matrix \f$ X \f$ such that
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\f$ \exp(X) = M \f$ where exp denotes the matrix exponential. As for
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the scalar logarithm, the equation \f$ \exp(X) = M \f$ may have
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multiple solutions; this function returns a matrix whose eigenvalues
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have imaginary part in the interval \f$ (-\pi,\pi] \f$.
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The matrix logarithm is different from applying the log function to all the entries in the matrix.
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Use ArrayBase::log() if you want to do the latter.
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In the real case, the matrix \f$ M \f$ should be invertible and
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it should have no eigenvalues which are real and negative (pairs of
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complex conjugate eigenvalues are allowed). In the complex case, it
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only needs to be invertible.
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This function computes the matrix logarithm using the Schur-Parlett
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algorithm as implemented by MatrixBase::matrixFunction(). The
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logarithm of an atomic block is computed by MatrixLogarithmAtomic,
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which uses direct computation for 1-by-1 and 2-by-2 blocks and an
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inverse scaling-and-squaring algorithm for bigger blocks, with the
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square roots computed by MatrixBase::sqrt().
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Details of the algorithm can be found in Section 11.6.2 of:
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Nicholas J. Higham,
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<em>Functions of Matrices: Theory and Computation</em>,
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SIAM 2008. ISBN 978-0-898716-46-7.
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Example: The following program checks that
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\f[ \log \left[ \begin{array}{ccc}
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\frac12\sqrt2 & -\frac12\sqrt2 & 0 \\
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\frac12\sqrt2 & \frac12\sqrt2 & 0 \\
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0 & 0 & 1
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\end{array} \right] = \left[ \begin{array}{ccc}
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0 & \frac14\pi & 0 \\
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-\frac14\pi & 0 & 0 \\
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0 & 0 & 0
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\end{array} \right]. \f]
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This corresponds to a rotation of \f$ \frac14\pi \f$ radians around
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the z-axis. This is the inverse of the example used in the
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documentation of \ref matrixbase_exp "exp()".
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\include MatrixLogarithm.cpp
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Output: \verbinclude MatrixLogarithm.out
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\note \p M has to be a matrix of \c float, \c double, <tt>long
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double</tt>, \c complex<float>, \c complex<double>, or \c complex<long
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double> .
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\sa MatrixBase::exp(), MatrixBase::matrixFunction(),
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class MatrixLogarithmAtomic, MatrixBase::sqrt().
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\subsection matrixbase_pow MatrixBase::pow()
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Compute the matrix raised to arbitrary real power.
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\code
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const MatrixPowerReturnValue<Derived> MatrixBase<Derived>::pow(RealScalar p) const
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\endcode
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\param[in] M base of the matrix power, should be a square matrix.
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\param[in] p exponent of the matrix power.
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The matrix power \f$ M^p \f$ is defined as \f$ \exp(p \log(M)) \f$,
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where exp denotes the matrix exponential, and log denotes the matrix
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logarithm. This is different from raising all the entries in the matrix
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to the p-th power. Use ArrayBase::pow() if you want to do the latter.
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If \p p is complex, the scalar type of \p M should be the type of \p
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p . \f$ M^p \f$ simply evaluates into \f$ \exp(p \log(M)) \f$.
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Therefore, the matrix \f$ M \f$ should meet the conditions to be an
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argument of matrix logarithm.
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If \p p is real, it is casted into the real scalar type of \p M. Then
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this function computes the matrix power using the Schur-Padé
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algorithm as implemented by class MatrixPower. The exponent is split
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into integral part and fractional part, where the fractional part is
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in the interval \f$ (-1, 1) \f$. The main diagonal and the first
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super-diagonal is directly computed.
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If \p M is singular with a semisimple zero eigenvalue and \p p is
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positive, the Schur factor \f$ T \f$ is reordered with Givens
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rotations, i.e.
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\f[ T = \left[ \begin{array}{cc}
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T_1 & T_2 \\
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0 & 0
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\end{array} \right] \f]
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where \f$ T_1 \f$ is invertible. Then \f$ T^p \f$ is given by
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\f[ T^p = \left[ \begin{array}{cc}
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T_1^p & T_1^{-1} T_1^p T_2 \\
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0 & 0
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\end{array}. \right] \f]
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\warning Fractional power of a matrix with a non-semisimple zero
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eigenvalue is not well-defined. We introduce an assertion failure
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against inaccurate result, e.g. \code
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#include <unsupported/Eigen/MatrixFunctions>
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#include <iostream>
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int main()
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{
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Eigen::Matrix4d A;
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A << 0, 0, 2, 3,
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0, 0, 4, 5,
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0, 0, 6, 7,
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0, 0, 8, 9;
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std::cout << A.pow(0.37) << std::endl;
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// The 1 makes eigenvalue 0 non-semisimple.
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A.coeffRef(0, 1) = 1;
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// This fails if EIGEN_NO_DEBUG is undefined.
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std::cout << A.pow(0.37) << std::endl;
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return 0;
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}
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\endcode
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Details of the algorithm can be found in: Nicholas J. Higham and
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Lijing Lin, "A Schur-Padé algorithm for fractional powers of a
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matrix," <em>SIAM J. %Matrix Anal. Applic.</em>,
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<b>32(3)</b>:1056–1078, 2011.
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Example: The following program checks that
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\f[ \left[ \begin{array}{ccc}
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\cos1 & -\sin1 & 0 \\
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\sin1 & \cos1 & 0 \\
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0 & 0 & 1
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\end{array} \right]^{\frac14\pi} = \left[ \begin{array}{ccc}
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\frac12\sqrt2 & -\frac12\sqrt2 & 0 \\
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\frac12\sqrt2 & \frac12\sqrt2 & 0 \\
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0 & 0 & 1
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\end{array} \right]. \f]
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This corresponds to \f$ \frac14\pi \f$ rotations of 1 radian around
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the z-axis.
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\include MatrixPower.cpp
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Output: \verbinclude MatrixPower.out
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MatrixBase::pow() is user-friendly. However, there are some
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circumstances under which you should use class MatrixPower directly.
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MatrixPower can save the result of Schur decomposition, so it's
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better for computing various powers for the same matrix.
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Example:
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\include MatrixPower_optimal.cpp
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Output: \verbinclude MatrixPower_optimal.out
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\note \p M has to be a matrix of \c float, \c double, <tt>long
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double</tt>, \c complex<float>, \c complex<double>, or \c complex<long
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double> .
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\sa MatrixBase::exp(), MatrixBase::log(), class MatrixPower.
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\subsection matrixbase_matrixfunction MatrixBase::matrixFunction()
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Compute a matrix function.
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\code
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const MatrixFunctionReturnValue<Derived> MatrixBase<Derived>::matrixFunction(typename internal::stem_function<typename internal::traits<Derived>::Scalar>::type f) const
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\endcode
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\param[in] M argument of matrix function, should be a square matrix.
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\param[in] f an entire function; \c f(x,n) should compute the n-th
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derivative of f at x.
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\returns expression representing \p f applied to \p M.
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Suppose that \p M is a matrix whose entries have type \c Scalar.
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Then, the second argument, \p f, should be a function with prototype
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\code
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ComplexScalar f(ComplexScalar, int)
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\endcode
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where \c ComplexScalar = \c std::complex<Scalar> if \c Scalar is
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real (e.g., \c float or \c double) and \c ComplexScalar =
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\c Scalar if \c Scalar is complex. The return value of \c f(x,n)
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should be \f$ f^{(n)}(x) \f$, the n-th derivative of f at x.
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This routine uses the algorithm described in:
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Philip Davies and Nicholas J. Higham,
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"A Schur-Parlett algorithm for computing matrix functions",
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<em>SIAM J. %Matrix Anal. Applic.</em>, <b>25</b>:464–485, 2003.
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The actual work is done by the MatrixFunction class.
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Example: The following program checks that
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\f[ \exp \left[ \begin{array}{ccc}
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0 & \frac14\pi & 0 \\
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-\frac14\pi & 0 & 0 \\
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0 & 0 & 0
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\end{array} \right] = \left[ \begin{array}{ccc}
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\frac12\sqrt2 & -\frac12\sqrt2 & 0 \\
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\frac12\sqrt2 & \frac12\sqrt2 & 0 \\
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0 & 0 & 1
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\end{array} \right]. \f]
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This corresponds to a rotation of \f$ \frac14\pi \f$ radians around
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the z-axis. This is the same example as used in the documentation
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of \ref matrixbase_exp "exp()".
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\include MatrixFunction.cpp
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Output: \verbinclude MatrixFunction.out
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Note that the function \c expfn is defined for complex numbers
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\c x, even though the matrix \c A is over the reals. Instead of
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\c expfn, we could also have used StdStemFunctions::exp:
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\code
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A.matrixFunction(StdStemFunctions<std::complex<double> >::exp, &B);
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\endcode
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\subsection matrixbase_sin MatrixBase::sin()
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Compute the matrix sine.
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\code
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const MatrixFunctionReturnValue<Derived> MatrixBase<Derived>::sin() const
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\endcode
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\param[in] M a square matrix.
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\returns expression representing \f$ \sin(M) \f$.
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This function computes the matrix sine. Use ArrayBase::sin() for computing the entry-wise sine.
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The implementation calls \ref matrixbase_matrixfunction "matrixFunction()" with StdStemFunctions::sin().
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Example: \include MatrixSine.cpp
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Output: \verbinclude MatrixSine.out
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\subsection matrixbase_sinh MatrixBase::sinh()
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Compute the matrix hyperbolic sine.
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\code
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MatrixFunctionReturnValue<Derived> MatrixBase<Derived>::sinh() const
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\endcode
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\param[in] M a square matrix.
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\returns expression representing \f$ \sinh(M) \f$
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This function calls \ref matrixbase_matrixfunction "matrixFunction()" with StdStemFunctions::sinh().
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Example: \include MatrixSinh.cpp
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Output: \verbinclude MatrixSinh.out
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\subsection matrixbase_sqrt MatrixBase::sqrt()
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Compute the matrix square root.
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\code
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const MatrixSquareRootReturnValue<Derived> MatrixBase<Derived>::sqrt() const
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\endcode
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\param[in] M invertible matrix whose square root is to be computed.
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\returns expression representing the matrix square root of \p M.
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The matrix square root of \f$ M \f$ is the matrix \f$ M^{1/2} \f$
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whose square is the original matrix; so if \f$ S = M^{1/2} \f$ then
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\f$ S^2 = M \f$. This is different from taking the square root of all
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the entries in the matrix; use ArrayBase::sqrt() if you want to do the
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latter.
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In the <b>real case</b>, the matrix \f$ M \f$ should be invertible and
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it should have no eigenvalues which are real and negative (pairs of
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complex conjugate eigenvalues are allowed). In that case, the matrix
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has a square root which is also real, and this is the square root
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computed by this function.
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The matrix square root is computed by first reducing the matrix to
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quasi-triangular form with the real Schur decomposition. The square
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root of the quasi-triangular matrix can then be computed directly. The
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cost is approximately \f$ 25 n^3 \f$ real flops for the real Schur
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decomposition and \f$ 3\frac13 n^3 \f$ real flops for the remainder
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(though the computation time in practice is likely more than this
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indicates).
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Details of the algorithm can be found in: Nicholas J. Highan,
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"Computing real square roots of a real matrix", <em>Linear Algebra
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Appl.</em>, 88/89:405–430, 1987.
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If the matrix is <b>positive-definite symmetric</b>, then the square
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root is also positive-definite symmetric. In this case, it is best to
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use SelfAdjointEigenSolver::operatorSqrt() to compute it.
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In the <b>complex case</b>, the matrix \f$ M \f$ should be invertible;
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this is a restriction of the algorithm. The square root computed by
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this algorithm is the one whose eigenvalues have an argument in the
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interval \f$ (-\frac12\pi, \frac12\pi] \f$. This is the usual branch
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cut.
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The computation is the same as in the real case, except that the
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complex Schur decomposition is used to reduce the matrix to a
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triangular matrix. The theoretical cost is the same. Details are in:
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Åke Björck and Sven Hammarling, "A Schur method for the
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square root of a matrix", <em>Linear Algebra Appl.</em>,
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52/53:127–140, 1983.
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Example: The following program checks that the square root of
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\f[ \left[ \begin{array}{cc}
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\cos(\frac13\pi) & -\sin(\frac13\pi) \\
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\sin(\frac13\pi) & \cos(\frac13\pi)
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\end{array} \right], \f]
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corresponding to a rotation over 60 degrees, is a rotation over 30 degrees:
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\f[ \left[ \begin{array}{cc}
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\cos(\frac16\pi) & -\sin(\frac16\pi) \\
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\sin(\frac16\pi) & \cos(\frac16\pi)
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\end{array} \right]. \f]
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\include MatrixSquareRoot.cpp
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Output: \verbinclude MatrixSquareRoot.out
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\sa class RealSchur, class ComplexSchur, class MatrixSquareRoot,
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SelfAdjointEigenSolver::operatorSqrt().
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*/
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#endif // EIGEN_MATRIX_FUNCTIONS
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