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https://github.com/mljs/matrix

Matrix manipulation and computation library
https://github.com/mljs/matrix
javascript machine-learning matrix ml
Last synced: 3 days ago
JSON representation
Matrix manipulation and computation library
Host: GitHub
URL: https://github.com/mljs/matrix
Owner: mljs
License: mit
Created: 2014-10-21T08:33:17.000Z (over 9 years ago)
Default Branch: main
Last Pushed: 2024-06-10T15:22:21.000Z (12 days ago)
Last Synced: 2024-06-18T12:34:03.290Z (5 days ago)
Topics: javascript, machine-learning, matrix, ml
Language: JavaScript
Homepage: https://mljs.github.io/matrix/
Size: 4.68 MB
Stars: 346
Watchers: 16
Forks: 54
Open Issues: 18
Metadata Files:
- Readme: README.md
- Changelog: CHANGELOG.md
- License: LICENSE
Lists

awesome - ml-matrix
awesome-github-star - matrix
README

        # ml-matrix

Matrix manipulation and computation library.



  

    

  

  


    Maintained by Zakodium

  


[![NPM version][npm-image]][npm-url]

[![build status][ci-image]][ci-url]

[![DOI](https://zenodo.org/badge/DOI/10.5281/zenodo.5644534.svg)](https://doi.org/10.5281/zenodo.5644534)

[![npm download][download-image]][download-url]

## Installation

`$ npm install ml-matrix`

## Usage

### As an ES module

```js

import { Matrix } from 'ml-matrix';

const matrix = Matrix.ones(5, 5);

```

### As a CommonJS module

```js

const { Matrix } = require('ml-matrix');

const matrix = Matrix.ones(5, 5);

```

## [API Documentation](https://mljs.github.io/matrix/)

## Examples

### Standard operations

```js

const { Matrix } = require('ml-matrix');

var A = new Matrix([

  [1, 1],

  [2, 2],

]);

var B = new Matrix([

  [3, 3],

  [1, 1],

]);

var C = new Matrix([

  [3, 3],

  [1, 1],

]);

```

#### Operations

```js

const addition       = Matrix.add(A, B);   // addition       = Matrix [[4, 4], [3, 3], rows: 2, columns: 2]

const subtraction    = Matrix.sub(A, B);   // subtraction    = Matrix [[-2, -2], [1, 1], rows: 2, columns: 2]

const multiplication = A.mmul(B);          // multiplication = Matrix [[4, 4], [8, 8], rows: 2, columns: 2]

const mulByNumber    = Matrix.mul(A, 10);  // mulByNumber    = Matrix [[10, 10], [20, 20], rows: 2, columns: 2]

const divByNumber    = Matrix.div(A, 10);  // divByNumber    = Matrix [[0.1, 0.1], [0.2, 0.2], rows: 2, columns: 2]

const modulo         = Matrix.mod(B, 2);   // modulo         = Matrix [[1, 1], [1, 1], rows: 2, columns: 2]

const maxMatrix      = Matrix.max(A, B);   // max            = Matrix [[3, 3], [2, 2], rows: 2, columns: 2]

const minMatrix      = Matrix.min(A, B);   // max            = Matrix [[1, 1], [1, 1], rows: 2, columns: 2]

```

#### Inplace Operations

```js

C.add(A);   // => C = C + A

C.sub(A);   // => C = C - A

C.mul(10);  // => C = 10 * C

C.div(10);  // => C = C / 10

C.mod(2);   // => C = C % 2

```

#### Math Operations

```js

// Standard Math operations: (abs, cos, round, etc.)

var A = new Matrix([

  [ 1,  1],

  [-1, -1],

]);

var exponential = Matrix.exp(A);  // exponential = Matrix [[Math.exp(1), Math.exp(1)], [Math.exp(-1), Math.exp(-1)], rows: 2, columns: 2].

var cosinus     = Matrix.cos(A);  // cosinus     = Matrix [[Math.cos(1), Math.cos(1)], [Math.cos(-1), Math.cos(-1)], rows: 2, columns: 2].

var absolute    = Matrix.abs(A);  // absolute    = Matrix [[1, 1], [1, 1], rows: 2, columns: 2].

// Note: you can do it inplace too as A.abs()

```

Available Methods:

```js

abs, acos, acosh, asin, asinh, atan, atanh, cbrt, ceil, clz32, cos, cosh, exp, expm1, floor, fround, log, log1p, log10, log2, round, sign, sin, sinh, sqrt, tan, tanh, trunc

```

#### Manipulation of the matrix

```js

// remember: A = Matrix [[1, 1], [-1, -1], rows: 2, columns: 2]

var numberRows     = A.rows;             // A has 2 rows

var numberCols     = A.columns;          // A has 2 columns

var firstValue     = A.get(0, 0);        // get(rows, columns)

var numberElements = A.size;             // 2 * 2 = 4 elements

var isRow          = A.isRowVector();    // false because A has more than 1 row

var isColumn       = A.isColumnVector(); // false because A has more than 1 column

var isSquare       = A.isSquare();       // true, because A is 2 * 2 matrix

var isSym          = A.isSymmetric();    // false, because A is not symmetric

A.set(1, 0, 10);                         // A = Matrix [[1, 1], [10, -1], rows: 2, columns: 2]. We have changed the second row and the first column

var diag           = A.diag();           // diag = [1, -1] (values in the diagonal)

var m              = A.mean();           // m = 2.75

var product        = A.prod();           // product = -10 (product of all values of the matrix)

var norm           = A.norm();           // norm = 10.14889156509222 (Frobenius norm of the matrix)

var transpose      = A.transpose();      // transpose = Matrix [[1, 10], [1, -1], rows: 2, columns: 2]

```

#### Instantiation of matrix

```js

var z = Matrix.zeros(3, 2); // z = Matrix [[0, 0], [0, 0], [0, 0], rows: 3, columns: 2]

var z = Matrix.ones(2, 3);  // z = Matrix [[1, 1, 1], [1, 1, 1], rows: 2, columns: 3]

var z = Matrix.eye(3, 4);   // z = Matrix [[1, 0, 0, 0], [0, 1, 0, 0], [0, 0, 1, 0], rows: 3, columns: 4]. there are 1 only in the diagonal

```

### Maths

```js

const {

  Matrix,

  inverse,

  solve,

  linearDependencies,

  QrDecomposition,

  LuDecomposition,

  CholeskyDecomposition,

  EigenvalueDecomposition,

} = require('ml-matrix');

```

#### Inverse and Pseudo-inverse

```js

var A = new Matrix([

  [2, 3, 5],

  [4, 1, 6],

  [1, 3, 0],

]);

var inverseA = inverse(A);

var B = A.mmul(inverseA); // B = A * inverse(A), so B ~= Identity

// if A is singular, you can use SVD :

var A = new Matrix([

  [1, 2, 3],

  [4, 5, 6],

  [7, 8, 9],

]); 

// A is singular, so the standard computation of inverse won't work (you can test if you don't trust me^^)

var inverseA = inverse(A, (useSVD = true)); // inverseA is only an approximation of the inverse, by using the Singular Values Decomposition

var B = A.mmul(inverseA); // B = A * inverse(A), but inverse(A) is only an approximation, so B doesn't really be identity.

```

```js

// if you want the pseudo-inverse of a matrix :

var A = new Matrix([

  [1, 2],

  [3, 4],

  [5, 6],

]);

var pseudoInverseA = A.pseudoInverse();

var B = A.mmul(pseudoInverseA).mmul(A); // with pseudo inverse, A*pseudo-inverse(A)*A ~= A. It's the case here

```

#### Least square

Least square is the following problem: We search for `x`, such that `A.x = B` (`A`, `x` and `B` are matrix or vectors).

Below, how to solve least square with our function

```js

// If A is non singular :

var A = new Matrix([

  [3,    1],

  [4.25, 1],

  [5.5,  1],

  [8,    1],

]);

var B = Matrix.columnVector([4.5, 4.25, 5.5, 5.5]);

var x = solve(A, B);

var error = Matrix.sub(B, A.mmul(x)); // The error enables to evaluate the solution x found.

```

```js

// If A is non singular :

var A = new Matrix([

  [1, 2, 3],

  [4, 5, 6],

  [7, 8, 9],

]);

var B = Matrix.columnVector([8, 20, 32]);

var x = solve(A, B, (useSVD = true)); // there are many solutions. x can be [1, 2, 1].transpose(), or [1.33, 1.33, 1.33].transpose(), etc.

var error = Matrix.sub(B, A.mmul(x)); // The error enables to evaluate the solution x found.

```

#### Decompositions

##### QR Decomposition

```js

var A = new Matrix([

  [2, 3, 5],

  [4, 1, 6],

  [1, 3, 0],

]);

var QR = new QrDecomposition(A);

var Q = QR.orthogonalMatrix;

var R = QR.upperTriangularMatrix;

// So you have the QR decomposition. If you multiply Q by R, you'll see that A = Q.R, with Q orthogonal and R upper triangular

```

##### LU Decomposition

```js

var A = new Matrix([

  [2, 3, 5],

  [4, 1, 6],

  [1, 3, 0],

]);

var LU = new LuDecomposition(A);

var L = LU.lowerTriangularMatrix;

var U = LU.upperTriangularMatrix;

var P = LU.pivotPermutationVector;

// So you have the LU decomposition. P includes the permutation of the matrix. Here P = [1, 2, 0], i.e the first row of LU is the second row of A, the second row of LU is the third row of A and the third row of LU is the first row of A.

```

##### Cholesky Decomposition

```js

var A = new Matrix([

  [2, 3, 5],

  [4, 1, 6],

  [1, 3, 0],

]);

var cholesky = new CholeskyDecomposition(A);

var L = cholesky.lowerTriangularMatrix;

```

##### Eigenvalues & eigenvectors

```js

var A = new Matrix([

  [2, 3, 5],

  [4, 1, 6],

  [1, 3, 0],

]);

var e = new EigenvalueDecomposition(A);

var real = e.realEigenvalues;

var imaginary = e.imaginaryEigenvalues;

var vectors = e.eigenvectorMatrix;

```

#### Linear dependencies

```js

var A = new Matrix([

  [2, 0, 0, 1],

  [0, 1, 6, 0],

  [0, 3, 0, 1],

  [0, 0, 1, 0],

  [0, 1, 2, 0],

]);

var dependencies = linearDependencies(A);

// dependencies is a matrix with the dependencies of the rows. When we look row by row, we see that the first row is [0, 0, 0, 0, 0], so it means that the first row is independent, and the second row is [ 0, 0, 0, 4, 1 ], i.e the second row = 4 times the 4th row + the 5th row.

```

## License

[MIT](./LICENSE)

[npm-image]: https://img.shields.io/npm/v/ml-matrix.svg

[npm-url]: https://npmjs.org/package/ml-matrix

[ci-image]: https://github.com/mljs/matrix/workflows/Node.js%20CI/badge.svg?branch=main

[ci-url]: https://github.com/mljs/matrix/actions?query=workflow%3A%22Node.js+CI%22

[download-image]: https://img.shields.io/npm/dm/ml-matrix.svg

[download-url]: https://npmjs.org/package/ml-matrix