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189 lines
6.6 KiB
Plaintext
189 lines
6.6 KiB
Plaintext
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namespace Eigen {
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/** \page TutorialAdvancedLinearAlgebra Tutorial 3/3 - Advanced linear algebra
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\ingroup Tutorial
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<div class="eimainmenu">\ref index "Overview"
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| \ref TutorialCore "Core features"
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| \ref TutorialGeometry "Geometry"
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| \b Advanced \b linear \b algebra
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| \ref TutorialSparse "Sparse matrix"
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</div>
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\b Table \b of \b contents
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- \ref TutorialAdvSolvers
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- \ref TutorialAdvLU
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- \ref TutorialAdvCholesky
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- \ref TutorialAdvQR
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- \ref TutorialAdvEigenProblems
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\section TutorialAdvSolvers Solving linear problems
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This part of the tutorial focuses on solving linear problem of the form \f$ A \mathbf{x} = b \f$,
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where both \f$ A \f$ and \f$ b \f$ are known, and \f$ x \f$ is the unknown. Moreover, \f$ A \f$
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assumed to be a squared matrix. Of course, the methods described here can be used whenever an expression
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involve the product of an inverse matrix with a vector or another matrix: \f$ A^{-1} B \f$.
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Eigen offers various algorithms to this problem, and its choice mainly depends on the nature of
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the matrix \f$ A \f$, such as its shape, size and numerical properties.
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\subsection TutorialAdvSolvers_Triangular Triangular solver
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If the matrix \f$ A \f$ is triangular (upper or lower) and invertible (the coefficients of the diagonal
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are all not zero), then the problem can be solved directly using MatrixBase::solveTriangular(), or better,
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MatrixBase::solveTriangularInPlace(). Here is an example:
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<table class="tutorial_code"><tr><td>
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\include MatrixBase_marked.cpp
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</td>
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<td>
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output:
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\include MatrixBase_marked.out
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</td></tr></table>
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See MatrixBase::solveTriangular() for more details.
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\subsection TutorialAdvSolvers_Inverse Direct inversion (for small matrices)
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If the matrix \f$ A \f$ is small (\f$ \leq 4 \f$) and invertible, then a good approach is to directly compute
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the inverse of the matrix \f$ A \f$, and then obtain the solution \f$ x \f$ by \f$ \mathbf{x} = A^{-1} b \f$. With Eigen,
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this can be implemented like this:
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\code
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#include <Eigen/LU>
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Matrix4f A = Matrix4f::Random();
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Vector4f b = Vector4f::Random();
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Vector4f x = A.inverse() * b;
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\endcode
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Note that the function inverse() is defined in the LU module.
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See MatrixBase::inverse() for more details.
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\subsection TutorialAdvSolvers_Symmetric Cholesky (for positive definite matrices)
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If the matrix \f$ A \f$ is \b positive \b definite, then
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the best method is to use a Cholesky decomposition.
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Such positive definite matrices often arise when solving overdetermined problems in a least square sense (see below).
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Eigen offers two different Cholesky decompositions: a \f$ LL^T \f$ decomposition where L is a lower triangular matrix,
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and a \f$ LDL^T \f$ decomposition where L is lower triangular with unit diagonal and D is a diagonal matrix.
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The latter avoids square roots and is therefore slightly more stable than the former one.
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\code
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#include <Eigen/Cholesky>
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MatrixXf D = MatrixXf::Random(8,4);
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MatrixXf A = D.transpose() * D;
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VectorXf b = A * VectorXf::Random(4);
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VectorXf x;
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A.llt().solve(b,&x); // using a LLT factorization
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A.ldlt().solve(b,&x); // using a LDLT factorization
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\endcode
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when the value of the right hand side \f$ b \f$ is not needed anymore, then it is faster to use
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the \em in \em place API, e.g.:
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\code
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A.llt().solveInPlace(b);
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\endcode
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In that case the value of \f$ b \f$ is replaced by the result \f$ x \f$.
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If the linear problem has to solved for various right hand side \f$ b_i \f$, but same matrix \f$ A \f$,
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then it is highly recommended to perform the decomposition of \$ A \$ only once, e.g.:
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\code
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// ...
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LLT<MatrixXf> lltOfA(A);
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lltOfA.solveInPlace(b0);
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lltOfA.solveInPlace(b1);
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// ...
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\endcode
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\sa Cholesky_Module, LLT::solve(), LLT::solveInPlace(), LDLT::solve(), LDLT::solveInPlace(), class LLT, class LDLT.
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\subsection TutorialAdvSolvers_LU LU decomposition (for most cases)
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If the matrix \f$ A \f$ does not fit in any of the previous categories, or if you are unsure about the numerical
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stability of your problem, then you can use the LU solver based on a decomposition of the same name : see the section \ref TutorialAdvLU below. Actually, Eigen's LU module does not implement a standard LU decomposition, but rather a so-called LU decomposition
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with full pivoting and rank update which has much better numerical stability.
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The API of the LU solver is the same than the Cholesky one, except that there is no \em in \em place variant:
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\code
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#include <Eigen/LU>
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MatrixXf A = MatrixXf::Random(20,20);
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VectorXf b = VectorXf::Random(20);
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VectorXf x;
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A.lu().solve(b, &x);
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\endcode
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Again, the LU decomposition can be stored to be reused or to perform other kernel operations:
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\code
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// ...
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LU<MatrixXf> luOfA(A);
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luOfA.solve(b, &x);
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// ...
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\endcode
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See the section \ref TutorialAdvLU below.
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\sa class LU, LU::solve(), LU_Module
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\subsection TutorialAdvSolvers_SVD SVD solver (for singular matrices and special cases)
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Finally, Eigen also offer a solver based on a singular value decomposition (SVD). Again, the API is the
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same than with Cholesky or LU:
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\code
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#include <Eigen/SVD>
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MatrixXf A = MatrixXf::Random(20,20);
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VectorXf b = VectorXf::Random(20);
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VectorXf x;
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A.svd().solve(b, &x);
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SVD<MatrixXf> svdOfA(A);
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svdOfA.solve(b, &x);
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\endcode
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\sa class SVD, SVD::solve(), SVD_Module
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<a href="#" class="top">top</a>\section TutorialAdvLU LU
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Eigen provides a rank-revealing LU decomposition with full pivoting, which has very good numerical stability.
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You can obtain the LU decomposition of a matrix by calling \link MatrixBase::lu() lu() \endlink, which is the easiest way if you're going to use the LU decomposition only once, as in
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\code
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#include <Eigen/LU>
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MatrixXf A = MatrixXf::Random(20,20);
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VectorXf b = VectorXf::Random(20);
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VectorXf x;
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A.lu().solve(b, &x);
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\endcode
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Alternatively, you can construct a named LU decomposition, which allows you to reuse it for more than one operation:
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\code
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#include <Eigen/LU>
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MatrixXf A = MatrixXf::Random(20,20);
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Eigen::LU<MatrixXf> lu(A);
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cout << "The rank of A is" << lu.rank() << endl;
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if(lu.isInvertible()) {
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cout << "A is invertible, its inverse is:" << endl << lu.inverse() << endl;
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}
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else {
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cout << "Here's a matrix whose columns form a basis of the kernel a.k.a. nullspace of A:"
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<< endl << lu.kernel() << endl;
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}
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\endcode
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\sa LU_Module, LU::solve(), class LU
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<a href="#" class="top">top</a>\section TutorialAdvCholesky Cholesky
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todo
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\sa Cholesky_Module, LLT::solve(), LLT::solveInPlace(), LDLT::solve(), LDLT::solveInPlace(), class LLT, class LDLT
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<a href="#" class="top">top</a>\section TutorialAdvQR QR
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todo
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\sa QR_Module, class QR
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<a href="#" class="top">top</a>\section TutorialAdvEigenProblems Eigen value problems
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todo
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\sa class SelfAdjointEigenSolver, class EigenSolver
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*/
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}
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