Decomposition algorithms decompose an A matrix has a product of several specific matrices from * which they can solve A × X = B in least squares sense: they find X such that ||A × X * - B|| is minimal. * *
Some solvers like {@link LUDecomposition} can only find the solution for square matrices and * when the solution is an exact linear solution, i.e. when ||A × X - B|| is exactly 0. Other * solvers can also find solutions with non-square matrix A and with non-null minimal norm. If an * exact linear solution exists it is also the minimal norm solution. * * @since 2.0 */ public interface DecompositionSolver { /** * Solve the linear equation A × X = B for matrices A. * *
The A matrix is implicit, it is provided by the underlying decomposition algorithm. * * @param b right-hand side of the equation A × X = B * @return a vector X that minimizes the two norm of A × X - B * @throws org.apache.commons.math3.exception.DimensionMismatchException if the matrices * dimensions do not match. * @throws SingularMatrixException if the decomposed matrix is singular. */ RealVector solve(final RealVector b) throws SingularMatrixException; /** * Solve the linear equation A × X = B for matrices A. * *
The A matrix is implicit, it is provided by the underlying decomposition algorithm. * * @param b right-hand side of the equation A × X = B * @return a matrix X that minimizes the two norm of A × X - B * @throws org.apache.commons.math3.exception.DimensionMismatchException if the matrices * dimensions do not match. * @throws SingularMatrixException if the decomposed matrix is singular. */ RealMatrix solve(final RealMatrix b) throws SingularMatrixException; /** * Check if the decomposed matrix is non-singular. * * @return true if the decomposed matrix is non-singular. */ boolean isNonSingular(); /** * Get the pseudo-inverse of * the decomposed matrix. * *
This is equal to the inverse of the decomposed matrix, if such an inverse exists. * *
If no such inverse exists, then the result has properties that resemble that of an * inverse. * *
In particular, in this case, if the decomposed matrix is A, then the system of equations * \( A x = b \) may have no solutions, or many. If it has no solutions, then the pseudo-inverse * \( A^+ \) gives the "closest" solution \( z = A^+ b \), meaning \( \left \| A z - b \right * \|_2 \) is minimized. If there are many solutions, then \( z = A^+ b \) is the smallest * solution, meaning \( \left \| z \right \|_2 \) is minimized. * *
Note however that some decompositions cannot compute a pseudo-inverse for all matrices. * For example, the {@link LUDecomposition} is not defined for non-square matrices to begin * with. The {@link QRDecomposition} can operate on non-square matrices, but will throw {@link * SingularMatrixException} if the decomposed matrix is singular. Refer to the javadoc of * specific decomposition implementations for more details. * * @return pseudo-inverse matrix (which is the inverse, if it exists), if the decomposition can * pseudo-invert the decomposed matrix * @throws SingularMatrixException if the decomposed matrix is singular and the decomposition * can not compute a pseudo-inverse */ RealMatrix getInverse() throws SingularMatrixException; }