Calculating determinant of a matrix [closed]

I need an recursive algorithm to calculate determinant of n*n matrix.

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closed as not a real question by Brian Agnew, Sjoerd, viraptor, Jacob, gnoviceJul 2 '10 at 14:34

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You might want to post some of your own code here to get some help as "plz give me codez!" doenst sit well with the community. Either that or it smells of homework and the first point still applies there too. – jpg Jul 2 '10 at 9:31
What language are you using? – Mark Dickinson Jul 2 '10 at 9:40

The Standard Method for computing the determinant is LU decomposition. Use a library like LAPACK in production code. There is absolutely no point in using recursion, LU decomposition is usually implemented by solving M = LU in closed form, and takes O(n^3) operations.

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``````

|a b c d ...|
det |...........|
|...........|
|...........|

= a * det(M1) - b * det(M2) + c * det(M3) - d * det(M4) + ... - ...
``````

where Mn is the remaining Matrix if you drop the first row and the n-th column

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I don't see the point in recursiveness here.

This matrix operation can easily be implemented in a SIMD operation, can be divided into threads, can be very well calculated on the GPU.

Recursiveness consumes a lot of memory, and some systems have limits in recursion depths.

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Wikipedia has a formula for calculating determinants. It involves permutations, which can easily be generated recursively. Google has plenty of results on "permutation algorithm".

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The formula with permutations has n! terms and is not usable for large n. – lhf Jul 2 '10 at 10:43
It's most likely homework and probably what his teachers expect, so it doesn't really matter. – IVlad Jul 2 '10 at 11:19