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I will solve a small linear system Ax = b where A is a 4-by-4 symmetric matrix stored 16 double numbers (actually 10 of them are enough to represent it), b is 4-by-1 vector. The problem is, I have to run such kind of systems million times. So I am looking for the most efficient library to solve it. I tried cv::solve() method in OpenCV, but I still find it slow.

As the matrix A is symmetric, I remember Conjugate Gradient algorithm may be a good candidate due to its efficiency. However, I have not found a library on it yet(Intel MKL seems have one, but it is designed for sparse matrix, not well-fit for my problem).

Could any one help me with it?

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Is A always (or at least several times at a time) the same? –  delnan May 3 at 14:34
    
No, every time I solve it, A and b will be new. –  C. Wang May 3 at 14:36
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If you're looking for a library, this is off-topic, if not, this might be off-topic (and on-topic for math.stackexchange.com). –  keyser May 3 at 14:37
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Since the dimensions are smalls, and you only have 4 values to guess, I suspect you would be better off hard-coding the solution rather than relying on libraries that may not take all the specifics (like symmetry) into account. –  Matthieu M. May 3 at 14:41
    
Did you made experiments with all possible algorithms that solve() can use? Their performance can vary greatly for different sizes of matrix. You can see here all options: docs.opencv.org/modules/core/doc/… –  Michael Burdinov May 4 at 14:05

2 Answers 2

Since the matrix dimension is fixed, I think you best off, directly implementing the inverse. There exists a ready made formular for this task. You have:

Inverse Matrix formular

The entries of B are given by: Calculation of the B_ij

Both formulars are taken from this site.

You should be able to further simplify the calculation of these entries exploiting the fact, that your matrix is symmetric. If you do that I think you will be faster than any general matrix inverse implementation.

Then you still need to apply A^-1 to your b, which is a simple matrix vector multiplication, you should also hard code, to get best performance.

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remember to test your code on random matrices against some other solution (e.g. openCV inverse mat solution) to avoid index errors while hardcoding ;) –  Micka May 5 at 9:00
    
This is Cramer's rule. It's probably fine for $3\times3$ matrices but not for $4\times 4$ matrices. LU decomposition is probably faster for this case. LU decomposition is also generally more numerically stable. en.wikipedia.org/wiki/LU_decomposition#Solving_linear_equations Students are taught matrix determinants and matrix inverses at an early stage but both can often be avoided. –  sigfpe Jul 24 at 19:50

For God's sake, please don't write your own. If I understand correctly, you're looking to solve a dense linear system efficiently. This is exactly what LAPACK is for. The version on netlib.org (see this page for guidance on which routine you should use) is pretty fast, but if you need something that really screams look at MKL, ATLAS, or perhaps GotoBLAS.

Edit: Since this is a C++ forum, I should add that you can use the Eigen package to do the solve. It will use some implementation of one of the LAPACK routines.

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The main problem I see, is that LAPACK is not optimized for such tiny systems with 4x4 matrices, but rather for systems with 1000x1000 matrices. Therefore I don't think they get anywhere near a hard coded implementation, in terms of performance. If this is worth the effort implementing it hard coded, depends on how often the calculations will be done. On the other hand, getting started with LAPACK/BLAS is not necessarily easier than a direct implementation. –  Haatschii May 7 at 18:33
    
If you look at the bottom of the Eigen main page, there is a credit to Intel for optimized 4x4 matrix inversion code they included. I'll bet that's plenty fast enough. As @Micka points out, testing is an issue, and you can bet that the Eigen code is plenty well tested. –  rkc May 7 at 21:47
    
Nice, I did not know Eigen (or in this case Intel) has in fact highly optimized code for such small cases. I guess it is usually used for some divide an conquer algorithms where such small problems occur. Your probably right that one won't beat SSE optimized code for that particular problem. For testing I assumed that OP has a working solver to test against, and only wants a high performance variant. Otherwise Eigen is surely a good candidate to test against. –  Haatschii May 7 at 23:43

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