Successive over-relaxation

In numerical linear algebra, the method of successive over-relaxation (SOR) is a variant of the Gauss–Seidel method for solving a linear system of equations, resulting in faster convergence. A similar method can be used for any slowly converging iterative process.

It was devised simultaneously by David M. Young, Jr. and by Stanley P. Frankel in 1950 for the purpose of automatically solving linear systems on digital computers. Over-relaxation methods had been used before the work of Young and Frankel. An example is the method of Lewis Fry Richardson, and the methods developed by R. V. Southwell. However, these methods were designed for computation by human calculators, and they required some expertise to ensure convergence to the solution which made them inapplicable for programming on digital computers. These aspects are discussed in the thesis of David M. Young, Jr.

Given a square system of n linear equations with unknown x:

where:

Then A can be decomposed into a diagonal component D, and strictly lower and upper triangular components L and U:

where

The system of linear equations may be rewritten as:

for a constant ω > 1, called the relaxation factor.

The method of successive over-relaxation is an iterative technique that solves the left hand side of this expression for x, using previous value for x on the right hand side. Analytically, this may be written as:

where ${\displaystyle \mathbf {x} ^{(k)}}$ is the kth approximation or iteration of ${\displaystyle \mathbf {x} }$ and ${\displaystyle \mathbf {x} ^{(k+1)}}$ is the next or k + 1 iteration of ${\displaystyle \mathbf {x} }$. However, by taking advantage of the triangular form of (D+ωL), the elements of x^(k+1) can be computed sequentially using forward substitution:

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