ADI Iteration: Difference between revisions
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== Algorithm Details == | |||
Year : -150 | |||
Family : [[SDD Systems Solvers]] | |||
Authors : Carl Friedrich Gauss | |||
Paper Link : NA | |||
Time Complexity : | |||
== Problem Statement == | |||
In mathematics, Gaussian elimination, also known as row reduction, is an algorithm for solving systems of linear equations. It consists of a sequence of operations performed on the corresponding matrix of coefficients. This method can also be used to compute the rank of a matrix, the determinant of a square matrix, and the inverse of an invertible matrix. | |||
== PseudoCode == | |||
1 h := 1 /* Initialization of the pivot row */ | |||
2 k := 1 /* Initialization of the pivot column */ | |||
3 | |||
4 while h ≤ m and k ≤ n: | |||
5 /* Find the k-th pivot: */ | |||
6 i_max := argmax (i = h ... m, abs(A[i, k])) | |||
7 if A[i_max, k] = 0 | |||
8 /* No pivot in this column, pass to next column */ | |||
9 k := k+1 | |||
10 else | |||
11 swap rows(h, i_max) | |||
12 /* Do for all rows below pivot: */ | |||
13 for i = h + 1 ... m: | |||
14 f := A[i, k] / A[h, k] | |||
15 /* Fill with zeros the lower part of pivot column: */ | |||
16 A[i, k] := 0 | |||
17 /* Do for all remaining elements in current row: */ | |||
18 for j = k + 1 ... n: | |||
19 A[i, j] := A[i, j] - A[h, j] * f | |||
20 /* Increase pivot row and column */ | |||
21 h := h + 1 | |||
22 k := k + 1 | |||
== Applications == | |||
Gaussian-elimination-based algorithm for mesh-connected processors | |||
Scheduling Algorithms for Parallel Gaussian Elimination | |||
Recover Generator Polynomials of Convolutional Codes | |||
== Implementations == | |||
Python : https://gist.github.com/j9ac9k/6b5cd12aa9d2e5aa861f942b786293b4 | |||
C++ Library : https://github.com/nomemory/neat-matrix-library |
Latest revision as of 10:54, 10 October 2022
Algorithm Details
Year : -150
Family : SDD Systems Solvers
Authors : Carl Friedrich Gauss
Paper Link : NA
Time Complexity :
Problem Statement
In mathematics, Gaussian elimination, also known as row reduction, is an algorithm for solving systems of linear equations. It consists of a sequence of operations performed on the corresponding matrix of coefficients. This method can also be used to compute the rank of a matrix, the determinant of a square matrix, and the inverse of an invertible matrix.
PseudoCode
1 h := 1 /* Initialization of the pivot row */ 2 k := 1 /* Initialization of the pivot column */ 3 4 while h ≤ m and k ≤ n: 5 /* Find the k-th pivot: */ 6 i_max := argmax (i = h ... m, abs(A[i, k])) 7 if A[i_max, k] = 0 8 /* No pivot in this column, pass to next column */ 9 k := k+1 10 else 11 swap rows(h, i_max) 12 /* Do for all rows below pivot: */ 13 for i = h + 1 ... m: 14 f := A[i, k] / A[h, k] 15 /* Fill with zeros the lower part of pivot column: */ 16 A[i, k] := 0 17 /* Do for all remaining elements in current row: */ 18 for j = k + 1 ... n: 19 A[i, j] := A[i, j] - A[h, j] * f 20 /* Increase pivot row and column */ 21 h := h + 1 22 k := k + 1
Applications
Gaussian-elimination-based algorithm for mesh-connected processors
Scheduling Algorithms for Parallel Gaussian Elimination
Recover Generator Polynomials of Convolutional Codes
Implementations
Python : https://gist.github.com/j9ac9k/6b5cd12aa9d2e5aa861f942b786293b4
C++ Library : https://github.com/nomemory/neat-matrix-library