Python/arithmetic_analysis/gaussian_elimination.py

"""
Gaussian elimination method for solving a system of linear equations.
Gaussian elimination - https://en.wikipedia.org/wiki/Gaussian_elimination
"""


import numpy as np


def retroactive_resolution(coefficients: np.matrix, vector: np.array) -> np.array:
    """
    This function performs a retroactive linear system resolution
        for triangular matrix

    Examples:
        2x1 + 2x2 - 1x3 = 5         2x1 + 2x2 = -1
        0x1 - 2x2 - 1x3 = -7        0x1 - 2x2 = -1
        0x1 + 0x2 + 5x3 = 15
    >>> gaussian_elimination([[2, 2, -1], [0, -2, -1], [0, 0, 5]], [[5], [-7], [15]])
    array([[2.],
           [2.],
           [3.]])
    >>> gaussian_elimination([[2, 2], [0, -2]], [[-1], [-1]])
    array([[-1. ],
           [ 0.5]])
    """

    rows, columns = np.shape(coefficients)

    x = np.zeros((rows, 1), dtype=float)
    for row in reversed(range(rows)):
        sum = 0
        for col in range(row + 1, columns):
            sum += coefficients[row, col] * x[col]

        x[row, 0] = (vector[row] - sum) / coefficients[row, row]

    return x


def gaussian_elimination(coefficients: np.matrix, vector: np.array) -> np.array:
    """
    This function performs Gaussian elimination method

    Examples:
        1x1 - 4x2 - 2x3 = -2        1x1 + 2x2 = 5
        5x1 + 2x2 - 2x3 = -3        5x1 + 2x2 = 5
        1x1 - 1x2 + 0x3 = 4
    >>> gaussian_elimination([[1, -4, -2], [5, 2, -2], [1, -1, 0]], [[-2], [-3], [4]])
    array([[ 2.3 ],
           [-1.7 ],
           [ 5.55]])
    >>> gaussian_elimination([[1, 2], [5, 2]], [[5], [5]])
    array([[0. ],
           [2.5]])
    """
    # coefficients must to be a square matrix so we need to check first
    rows, columns = np.shape(coefficients)
    if rows != columns:
        return []

    # augmented matrix
    augmented_mat = np.concatenate((coefficients, vector), axis=1)
    augmented_mat = augmented_mat.astype("float64")

    # scale the matrix leaving it triangular
    for row in range(rows - 1):
        pivot = augmented_mat[row, row]
        for col in range(row + 1, columns):
            factor = augmented_mat[col, row] / pivot
            augmented_mat[col, :] -= factor * augmented_mat[row, :]

    x = retroactive_resolution(
        augmented_mat[:, 0:columns], augmented_mat[:, columns : columns + 1]
    )

    return x


if __name__ == "__main__":
    import doctest

    doctest.testmod()
Add gaussian_elimination.py for solving linear systems (#1448) 2019-10-25 03:56:56 +00:00			`"""`
			`Gaussian elimination method for solving a system of linear equations.`
			`Gaussian elimination - https://en.wikipedia.org/wiki/Gaussian_elimination`
			`"""`


			`import numpy as np`


			`def retroactive_resolution(coefficients: np.matrix, vector: np.array) -> np.array:`
			`"""`
			`This function performs a retroactive linear system resolution`
			`for triangular matrix`

			`Examples:`
			`2x1 + 2x2 - 1x3 = 5 2x1 + 2x2 = -1`
			`0x1 - 2x2 - 1x3 = -7 0x1 - 2x2 = -1`
			`0x1 + 0x2 + 5x3 = 15`
			`>>> gaussian_elimination([[2, 2, -1], [0, -2, -1], [0, 0, 5]], [[5], [-7], [15]])`
			`array([[2.],`
			`[2.],`
			`[3.]])`
			`>>> gaussian_elimination([[2, 2], [0, -2]], [[-1], [-1]])`
			`array([[-1. ],`
			`[ 0.5]])`
			`"""`

			`rows, columns = np.shape(coefficients)`

			`x = np.zeros((rows, 1), dtype=float)`
			`for row in reversed(range(rows)):`
			`sum = 0`
			`for col in range(row + 1, columns):`
			`sum += coefficients[row, col] * x[col]`

			`x[row, 0] = (vector[row] - sum) / coefficients[row, row]`

			`return x`


			`def gaussian_elimination(coefficients: np.matrix, vector: np.array) -> np.array:`
			`"""`
			`This function performs Gaussian elimination method`

			`Examples:`
			`1x1 - 4x2 - 2x3 = -2 1x1 + 2x2 = 5`
			`5x1 + 2x2 - 2x3 = -3 5x1 + 2x2 = 5`
			`1x1 - 1x2 + 0x3 = 4`
			`>>> gaussian_elimination([[1, -4, -2], [5, 2, -2], [1, -1, 0]], [[-2], [-3], [4]])`
			`array([[ 2.3 ],`
			`[-1.7 ],`
			`[ 5.55]])`
			`>>> gaussian_elimination([[1, 2], [5, 2]], [[5], [5]])`
			`array([[0. ],`
			`[2.5]])`
			`"""`
			`# coefficients must to be a square matrix so we need to check first`
			`rows, columns = np.shape(coefficients)`
			`if rows != columns:`
			`return []`

			`# augmented matrix`
			`augmented_mat = np.concatenate((coefficients, vector), axis=1)`
			`augmented_mat = augmented_mat.astype("float64")`

			`# scale the matrix leaving it triangular`
			`for row in range(rows - 1):`
			`pivot = augmented_mat[row, row]`
			`for col in range(row + 1, columns):`
			`factor = augmented_mat[col, row] / pivot`
			`augmented_mat[col, :] -= factor * augmented_mat[row, :]`

			`x = retroactive_resolution(`
			`augmented_mat[:, 0:columns], augmented_mat[:, columns : columns + 1]`
			`)`

			`return x`


			`if __name__ == "__main__":`
			`import doctest`

			`doctest.testmod()`