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RegularChains[MatrixTools][MatrixInverse] - compute the inverse of a matrix modulo a regular chain
Calling Sequence
MatrixInverse(A, rc, R)
Parameters
A
-
square Matrix with coefficients in the ring of fractions of R
rc
regular chain of R
R
polynomial ring
Description
The command MatrixInverse(A, rc, R) returns two lists.
The first list the command returns is a list of pairs where is a regular chain and is the inverse of A modulo the saturated ideal of .
The second list the command returns is a list of triplets where is a regular chain and A is the input matrix such that A is not invertible modulo the saturated ideal of .
All the returned regular chains form a triangular decomposition of rc (in the sense of Kalkbrener).
It is assumed that rc is strongly normalized.
The algorithm is an adaptation of the algorithm of Bareiss.
This command is part of the RegularChains[MatrixTools] package, so it can be used in the form MatrixInverse(..) only after executing the command with(RegularChains[MatrixTools]). However, it can always be accessed through the long form of the command by using RegularChains[MatrixTools][MatrixInverse](..).
Examples
Automatic case discussion.
Assume we have two variables y and z that have the same square and z is a 4th root of -1. Suppose we need to compute modulo this relation.
We want to compute the inverse of the previous matrix.
Let us check the first result.
Consider now this other matrix.
Get a generic answer that would hold both cases.
Check.
See Also
Chain, Empty, Equations, IsStronglyNormalized, IsZeroMatrix, JacobianMatrix, LowerEchelonForm, MatrixCombine, MatrixMultiply, MatrixOverChain, MatrixTools, NormalForm, PolynomialRing, RegularChains
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