# Matlab: Moore-Penrose pseudo inverse algorithm implementation

I am searching for a Matlab implementation of the Moore-Penrose algorithm computing pseudo-inverse matrix.

I tried several algoithm, this one

http://arxiv.org/ftp/arxiv/papers/0804/0804.4809.pdf

appeared good at the first look.

However, the problem it, that for large elements it produces badly scaled matrices and some internal operations fail. It concerns the following steps:

``````L=L(:,1:r);
M=inv(L'*L);
``````

I am trying to find a more robust solution which is easily implementable in my other SW. Thanks for your help.

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You may want to take this question to either math.stackexchange.com or dsp.stackexchange.com –  Ali Nov 11 '12 at 10:54

What is wrong with using the built-in `pinv`?

Otherwise, you could take a look at the implementation used in Octave. It is not in Octave/MATLAB syntax, but I guess you should be able to port it without much problems.

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Yes, pinv is OK. But I would like to use the code in another SW written in different language. –  justik Nov 11 '12 at 11:28
I think the pseudo-inverse should be available for almost any decent programming language (e.g. using the LAPACK library). In general I wouldn't recommend implementing numerical algorithms yourself for anything that should be reliable (unless of course you know what you are doing). –  Egon Nov 11 '12 at 22:41

I re-implemented one in C# using the Mapack matrix library by Lutz Roeder. Perhaps this, or the Java version, will be useful to you.

``````/// <summary>
/// The difference between 1 and the smallest exactly representable number
/// greater than one. Gives an upper bound on the relative error due to
/// rounding of floating point numbers.
/// </summary>
const double MACHEPS = 2E-16;

// NOTE: Code for pseudoinverse is from:
// http://the-lost-beauty.blogspot.com/2009/04/moore-penrose-pseudoinverse-in-jama.html

/// <summary>
/// Computes the Moore–Penrose pseudoinverse using the SVD method.
/// Modified version of the original implementation by Kim van der Linde.
/// </summary>
/// <param name="x"></param>
/// <returns>The pseudoinverse.</returns>
public static Matrix MoorePenrosePsuedoinverse(Matrix x)
{
if (x.Columns > x.Rows)
return MoorePenrosePsuedoinverse(x.Transpose()).Transpose();
SingularValueDecomposition svdX = new SingularValueDecomposition(x);
if (svdX.Rank < 1)
return null;
double[] singularValues = svdX.Diagonal;
double tol = Math.Max(x.Columns, x.Rows) * singularValues[0] * MACHEPS;
double[] singularValueReciprocals = new double[singularValues.Length];
for (int i = 0; i < singularValues.Length; ++i)
singularValueReciprocals[i] = Math.Abs(singularValues[i]) < tol ? 0 : (1.0 / singularValues[i]);
Matrix u = svdX.GetU();
Matrix v = svdX.GetV();
int min = Math.Min(x.Columns, u.Columns);
Matrix inverse = new Matrix(x.Columns, x.Rows);
for (int i = 0; i < x.Columns; i++)
for (int j = 0; j < u.Rows; j++)
for (int k = 0; k < min; k++)
inverse[i, j] += v[i, k] * singularValueReciprocals[k] * u[j, k];
return inverse;
}
``````
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Here is the R code [I][1] have written to compute M-P pseudoinverse. I think that is simple enough to be translated into matlab code.

``````pinv<-function(H){
x=t(H) %*% H
s=svd(x)
xp=s\$d
for (i in 1:length(xp)){
if (xp[i] != 0){
xp[i]=1/xp[i]
}
else{
xp[i]=0
}
}
return(s\$u %*% diag(xp) %*% t(s\$v) %*% t(H))
}``````