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

I tried several algoithm, this one


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:


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.

  x=t(H) %*% H
  for (i in 1:length(xp)){
    if (xp[i] != 0){
  return(s$u %*% diag(xp) %*% t(s$v) %*% t(H))
[1]: http://hamedhaseli.webs.com/downloads

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