src/main/java/org/apache/commons/math/linear/SingularValueDecomposition.java - platform/external/apache-commons-math - Git at Google

 /*
  * Licensed to the Apache Software Foundation (ASF) under one or more
  * contributor license agreements.  See the NOTICE file distributed with
  * this work for additional information regarding copyright ownership.
  * The ASF licenses this file to You under the Apache License, Version 2.0
  * (the "License"); you may not use this file except in compliance with
  * the License.  You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 package org.apache.commons.math.linear;


 /**
  * An interface to classes that implement an algorithm to calculate the
  * Singular Value Decomposition of a real matrix.
  * <p>
  * The Singular Value Decomposition of matrix A is a set of three matrices: U,
  * &Sigma; and V such that A = U &times; &Sigma; &times; V<sup>T</sup>. Let A be
  * a m &times; n matrix, then U is a m &times; p orthogonal matrix, &Sigma; is a
  * p &times; p diagonal matrix with positive or null elements, V is a p &times;
  * n orthogonal matrix (hence V<sup>T</sup> is also orthogonal) where
  * p=min(m,n).
  * </p>
  * <p>This interface is similar to the class with similar name from the
  * <a href="http://math.nist.gov/javanumerics/jama/">JAMA</a> library, with the
  * following changes:</p>
  * <ul>
  *   <li>the <code>norm2</code> method which has been renamed as {@link #getNorm()
  *   getNorm},</li>
  *   <li>the <code>cond</code> method which has been renamed as {@link
  *   #getConditionNumber() getConditionNumber},</li>
  *   <li>the <code>rank</code> method which has been renamed as {@link #getRank()
  *   getRank},</li>
  *   <li>a {@link #getUT() getUT} method has been added,</li>
  *   <li>a {@link #getVT() getVT} method has been added,</li>
  *   <li>a {@link #getSolver() getSolver} method has been added,</li>
  *   <li>a {@link #getCovariance(double) getCovariance} method has been added.</li>
  * </ul>
  * @see <a href="http://mathworld.wolfram.com/SingularValueDecomposition.html">MathWorld</a>
  * @see <a href="http://en.wikipedia.org/wiki/Singular_value_decomposition">Wikipedia</a>
  * @version $Revision: 928081 $ $Date: 2010-03-26 23:36:38 +0100 (ven. 26 mars 2010) $
  * @since 2.0
  */
 public interface SingularValueDecomposition {

     /**
      * Returns the matrix U of the decomposition.
      * <p>U is an orthogonal matrix, i.e. its transpose is also its inverse.</p>
      * @return the U matrix
      * @see #getUT()
      */
     RealMatrix getU();

     /**
      * Returns the transpose of the matrix U of the decomposition.
      * <p>U is an orthogonal matrix, i.e. its transpose is also its inverse.</p>
      * @return the U matrix (or null if decomposed matrix is singular)
      * @see #getU()
      */
     RealMatrix getUT();

     /**
      * Returns the diagonal matrix &Sigma; of the decomposition.
      * <p>&Sigma; is a diagonal matrix. The singular values are provided in
      * non-increasing order, for compatibility with Jama.</p>
      * @return the &Sigma; matrix
      */
     RealMatrix getS();

     /**
      * Returns the diagonal elements of the matrix &Sigma; of the decomposition.
      * <p>The singular values are provided in non-increasing order, for
      * compatibility with Jama.</p>
      * @return the diagonal elements of the &Sigma; matrix
      */
     double[] getSingularValues();

     /**
      * Returns the matrix V of the decomposition.
      * <p>V is an orthogonal matrix, i.e. its transpose is also its inverse.</p>
      * @return the V matrix (or null if decomposed matrix is singular)
      * @see #getVT()
      */
     RealMatrix getV();

     /**
      * Returns the transpose of the matrix V of the decomposition.
      * <p>V is an orthogonal matrix, i.e. its transpose is also its inverse.</p>
      * @return the V matrix (or null if decomposed matrix is singular)
      * @see #getV()
      */
     RealMatrix getVT();

     /**
      * Returns the n &times; n covariance matrix.
      * <p>The covariance matrix is V &times; J &times; V<sup>T</sup>
      * where J is the diagonal matrix of the inverse of the squares of
      * the singular values.</p>
      * @param minSingularValue value below which singular values are ignored
      * (a 0 or negative value implies all singular value will be used)
      * @return covariance matrix
      * @exception IllegalArgumentException if minSingularValue is larger than
      * the largest singular value, meaning all singular values are ignored
      */
     RealMatrix getCovariance(double minSingularValue) throws IllegalArgumentException;

     /**
      * Returns the L<sub>2</sub> norm of the matrix.
      * <p>The L<sub>2</sub> norm is max(|A &times; u|<sub>2</sub> /
      * |u|<sub>2</sub>), where |.|<sub>2</sub> denotes the vectorial 2-norm
      * (i.e. the traditional euclidian norm).</p>
      * @return norm
      */
     double getNorm();

     /**
      * Return the condition number of the matrix.
      * @return condition number of the matrix
      */
     double getConditionNumber();

     /**
      * Return the effective numerical matrix rank.
      * <p>The effective numerical rank is the number of non-negligible
      * singular values. The threshold used to identify non-negligible
      * terms is max(m,n) &times; ulp(s<sub>1</sub>) where ulp(s<sub>1</sub>)
      * is the least significant bit of the largest singular value.</p>
      * @return effective numerical matrix rank
      */
     int getRank();

     /**
      * Get a solver for finding the A &times; X = B solution in least square sense.
      * @return a solver
      */
     DecompositionSolver getSolver();

 }
	/*
	* Licensed to the Apache Software Foundation (ASF) under one or more
	* contributor license agreements. See the NOTICE file distributed with
	* this work for additional information regarding copyright ownership.
	* The ASF licenses this file to You under the Apache License, Version 2.0
	* (the "License"); you may not use this file except in compliance with
	* the License. You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	package org.apache.commons.math.linear;



	/**
	* An interface to classes that implement an algorithm to calculate the
	* Singular Value Decomposition of a real matrix.
	* <p>
	* The Singular Value Decomposition of matrix A is a set of three matrices: U,
	* Σ and V such that A = U × Σ × V<sup>T</sup>. Let A be
	* a m × n matrix, then U is a m × p orthogonal matrix, Σ is a
	* p × p diagonal matrix with positive or null elements, V is a p ×
	* n orthogonal matrix (hence V<sup>T</sup> is also orthogonal) where
	* p=min(m,n).
	* </p>
	* <p>This interface is similar to the class with similar name from the
	* <a href="http://math.nist.gov/javanumerics/jama/">JAMA</a> library, with the
	* following changes:</p>
	* <ul>
	* <li>the <code>norm2</code> method which has been renamed as {@link #getNorm()
	* getNorm},</li>
	* <li>the <code>cond</code> method which has been renamed as {@link
	* #getConditionNumber() getConditionNumber},</li>
	* <li>the <code>rank</code> method which has been renamed as {@link #getRank()
	* getRank},</li>
	* <li>a {@link #getUT() getUT} method has been added,</li>
	* <li>a {@link #getVT() getVT} method has been added,</li>
	* <li>a {@link #getSolver() getSolver} method has been added,</li>
	* <li>a {@link #getCovariance(double) getCovariance} method has been added.</li>
	* </ul>
	* @see <a href="http://mathworld.wolfram.com/SingularValueDecomposition.html">MathWorld</a>
	* @see <a href="http://en.wikipedia.org/wiki/Singular_value_decomposition">Wikipedia</a>
	* @version $Revision: 928081 $ $Date: 2010-03-26 23:36:38 +0100 (ven. 26 mars 2010) $
	* @since 2.0
	*/
	public interface SingularValueDecomposition {

	/**
	* Returns the matrix U of the decomposition.
	* <p>U is an orthogonal matrix, i.e. its transpose is also its inverse.</p>
	* @return the U matrix
	* @see #getUT()
	*/
	RealMatrix getU();

	/**
	* Returns the transpose of the matrix U of the decomposition.
	* <p>U is an orthogonal matrix, i.e. its transpose is also its inverse.</p>
	* @return the U matrix (or null if decomposed matrix is singular)
	* @see #getU()
	*/
	RealMatrix getUT();

	/**
	* Returns the diagonal matrix Σ of the decomposition.
	* <p>Σ is a diagonal matrix. The singular values are provided in
	* non-increasing order, for compatibility with Jama.</p>
	* @return the Σ matrix
	*/
	RealMatrix getS();

	/**
	* Returns the diagonal elements of the matrix Σ of the decomposition.
	* <p>The singular values are provided in non-increasing order, for
	* compatibility with Jama.</p>
	* @return the diagonal elements of the Σ matrix
	*/
	double[] getSingularValues();

	/**
	* Returns the matrix V of the decomposition.
	* <p>V is an orthogonal matrix, i.e. its transpose is also its inverse.</p>
	* @return the V matrix (or null if decomposed matrix is singular)
	* @see #getVT()
	*/
	RealMatrix getV();

	/**
	* Returns the transpose of the matrix V of the decomposition.
	* <p>V is an orthogonal matrix, i.e. its transpose is also its inverse.</p>
	* @return the V matrix (or null if decomposed matrix is singular)
	* @see #getV()
	*/
	RealMatrix getVT();

	/**
	* Returns the n × n covariance matrix.
	* <p>The covariance matrix is V × J × V<sup>T</sup>
	* where J is the diagonal matrix of the inverse of the squares of
	* the singular values.</p>
	* @param minSingularValue value below which singular values are ignored
	* (a 0 or negative value implies all singular value will be used)
	* @return covariance matrix
	* @exception IllegalArgumentException if minSingularValue is larger than
	* the largest singular value, meaning all singular values are ignored
	*/
	RealMatrix getCovariance(double minSingularValue) throws IllegalArgumentException;

	/**
	* Returns the L<sub>2</sub> norm of the matrix.
	* <p>The L<sub>2</sub> norm is max(\|A × u\|<sub>2</sub> /
	* \|u\|<sub>2</sub>), where \|.\|<sub>2</sub> denotes the vectorial 2-norm
	* (i.e. the traditional euclidian norm).</p>
	* @return norm
	*/
	double getNorm();

	/**
	* Return the condition number of the matrix.
	* @return condition number of the matrix
	*/
	double getConditionNumber();

	/**
	* Return the effective numerical matrix rank.
	* <p>The effective numerical rank is the number of non-negligible
	* singular values. The threshold used to identify non-negligible
	* terms is max(m,n) × ulp(s<sub>1</sub>) where ulp(s<sub>1</sub>)
	* is the least significant bit of the largest singular value.</p>
	* @return effective numerical matrix rank
	*/
	int getRank();

	/**
	* Get a solver for finding the A × X = B solution in least square sense.
	* @return a solver
	*/
	DecompositionSolver getSolver();

	}