Solving normal equation system in C++

I would like to solve the system of linear equations:

`````` Ax = b
``````

A is a `n x m` matrix (not square), b and x are both `n x 1` vectors. Where A and b are known, n is from the order of 50-100 and m is about 2 (in other words, A could be maximum [100x2]).

I know the solution of `x`: `\$x = \inv(A^T A) A^T b\$`

I found few ways to solve it: uBLAS (Boost), Lapack, Eigen and etc. but i dont know how fast are the CPU computation time of 'x' using those packages. I also don't know if this numerically a fast why to solve 'x'

What is for my important is that the CPU computation time would be short as possible and good documentation since i am newbie.

After solving the normal equation `Ax = b` i would like to improve my approximation using regressive and maybe later applying Kalman Filter.

My question is which C++ library is the robuster and faster for the needs i describe above?

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How do you multiple an n x m matrix by an n dimensional column vector? Presumably x is actually m dimensional. –  David Heffernan Jan 3 '11 at 14:23
Also, have you got some requirement that states a minimum amount of buzzword compliance? –  David Heffernan Jan 3 '11 at 14:24
@Eagle I don't think the Boost uBLAS library implements this but please correct me if I'm wrong. It rather seems that uBLAS provides you with vectors, matrices and basic operations (multiplication, addition) but nothing like LU, QR, SVD or matrix inversion, let alone OLS implementation. However it's probably a good library to implement such algorithms. Again, please tell me if I'm wrong or if you find a good Boost uBLAS OLS implementation... –  Arthur Jan 8 '12 at 16:53
i was wrong, there is LU decomposition in lu.hpp. Along with the included triangular solver it lets you do some stuffs –  Arthur Jan 9 '12 at 3:20

This is a least squares solution, because you have more unknowns than equations. If m is indeed equal to 2, that tells me that a simple linear least squares will be sufficient for you. The formulas can be written out in closed form. You don't need a library.

If m is in single digits, I'd still say that you can easily solve this using A(transpose)*A*X = A(transpose)*b. A simple LU decomposition to solve for the coefficients would be sufficient. It should be a much more straightforward problem than you're making it out to be.

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He talks about Kalman filter. I presume he is comfortable with linear algebra and OLS in particular. He wants optimized library. –  watson1180 Jan 3 '11 at 14:40
@duffymo, you are right, for now the solution of \$x = \inv(A^T A) A^T b\$ is what i am searching. The Kalman Filter is maybe for future development. What was importent to me is which wich libary (that support inverse, transpose, matrix multiplication and etc.) should i work with (Boost, Eigen, Lapack or etc.) –  Eagle Jan 3 '11 at 14:44
@duffymo, i thought i need Eigen or Boost for matrix transpose, inverse and multiplication. If i dont need those things right now, then what do i need? –  Eagle Jan 3 '11 at 16:06
@Eagle you don't need to calculate the inverse. –  David Heffernan Jan 3 '11 at 17:33
Eigenvalue problems are different from solving systems of equations. I'll have to go back and review what I know about Kalman filtering to recall if eigenvalues are central to its implementation. (Sorry, my books are at home.) –  duffymo Jan 3 '11 at 18:18

uBlas is not optimized unless you use it with optimized BLAS bindings.

The following are optimized for multi-threading and SIMD:

1. Intel MKL. FORTRAN library with C interface. Not free but very good.
2. Eigen. True C++ library. Free and open source. Easy to use and good.
3. Atlas. FORTRAN and C. Free and open source. Not Windows friendly, but otherwise good.

Btw, I don't know exactly what are you doing, but as a rule normal equations are not a proper way to do linear regression. Unless your matrix is well conditioned, QR or SVD should be preferred.

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Also ACML for AMD chips. This one is free I believe. –  Tom Jan 3 '11 at 14:12
I'm not sure the optimised mult-threaded versions would be that much of a benefit for matrices as miniscule as this. –  David Heffernan Jan 3 '11 at 14:12
would boost::numeric::ublas be consider as "optimized BLAS bindings"? –  Eagle Jan 3 '11 at 14:22
@David Heffernan. 100x100 isn't that small. –  watson1180 Jan 3 '11 at 14:24
I wrote a simulator (master thesis) which generate some values. It could be a jump in the data and i am trying to detect it in real-time using statistical tests and updating my Normal equation estimation. I know that there are other ways, but this is what i am using –  Eagle Jan 3 '11 at 14:27

If liscencing is not a problem, you might try the gnu scientific library

http://www.gnu.org/software/gsl/

It comes with a blas library that you can swap for an optimised library if you need to later (for example the intel, ATLAS, or ACML (AMD chip) library.

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GSL linear algebra routines aren't optimized. –  watson1180 Jan 3 '11 at 14:27
@watson so what, you don't need fancy optimisation for 100x2? –  David Heffernan Jan 3 '11 at 14:32
@watson It provides an interface to the underlying BLAS library however? You can exchange for your favourate BLAS library in linking rather than in code if you find you really need to optimise –  Tom Jan 3 '11 at 14:33
@David Heffernan. Cache is no problem, because 100x2 fits into L1, but with SSE it can be up to 4-8 times faster than uBLAS (if done in single precision). Download Eigen and see for yourself. –  watson1180 Jan 3 '11 at 15:37

If you have access to MATLAB, I would recommend using its C libraries.

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hmm, rather a brutal solution to a trivial problem! –  David Heffernan Jan 3 '11 at 14:22
AFAIK, Matlab C library (at least linear algebra routines) use/based some of the well known publicly available libraries (LAPACK). –  watson1180 Jan 3 '11 at 14:31
@watson all the linear algebra libraries are essentially the same and derived from the Handbook –  David Heffernan Jan 3 '11 at 14:37
@David Heffernan. Hope your are joking. MKL, Eigen, ATLAS are optimized to exploit cache memory more efficiently. Stock LAPACK (r u referring to LAPACK handbook?) provides only (un-optimized) reference implementation and high level routines. –  watson1180 Jan 3 '11 at 14:45
@David Heffernan. Math formulas are the same, but implementations are different. Tuning to memory hierarchy is done differently. LAPACK and uBLAS don't do any tuning. –  watson1180 Jan 3 '11 at 15:33

If you really need to specialize, you can approximate matrix inversion (to arbitrary precision) using the Skilling method. It uses order (N^2) operations only (rather than the order N^3 of usual matrix inversion - LU decomposition etc).

Its described in the thesis of Gibbs linked to here (around page 27):

http://www.inference.phy.cam.ac.uk/mng10/GP/thesis.ps.gz

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Never use matrix inversion to solve linear systems. Solving linear systems is by essence a O(n^2) problem. –  Alexandre C. Jan 3 '11 at 14:26
@Alexandre Really? - I would be interested in your solution. LU decomposition, for example is Order N^3 (according to the thesis I cite, anyway). –  Tom Jan 3 '11 at 14:32
@Alexandre I don't think big O is very relevant for small problems like this.... –  David Heffernan Jan 3 '11 at 14:40
@David I agree entirely, but the question wants as "fast as possible" so I offer this as a future specialisation if they really need it. –  Tom Jan 3 '11 at 14:42