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I'm trying to find the null space (solution space of Ax=0) of a given matrix. I've found two examples, but I can't seem to get either to work. Moreover, I can't understand what they're doing to get there, so I can't debug. I'm hoping someone might be able to walk me through this.

The documentation pages (numpy.linalg.svd, and numpy.compress) are opaque to me. I learned to do this by creating the matrix C = [A|0], finding the reduced row echelon form and solving for variables by row. I can't seem to follow how it's being done in these examples.

Thanks for any and all help!

Here is my sample matrix, which is the same as the wikipedia example:

A = matrix([

Method (found here, and here):

import scipy
from scipy import linalg, matrixr
def null(A, eps=1e-15):
    u, s, vh = scipy.linalg.svd(A)
    null_mask = (s <= eps)
    null_space = scipy.compress(null_mask, vh, axis=0)
    return scipy.transpose(null_space)

When I try it, I get back an empty matrix:

Python 2.6.6 (r266:84292, Sep 15 2010, 16:22:56) 
[GCC 4.4.5] on linux2
Type "help", "copyright", "credits" or "license" for more information.
>>> import scipy
>>> from scipy import linalg, matrix
>>> def null(A, eps=1e-15):
...    u, s, vh = scipy.linalg.svd(A)
...    null_mask = (s <= eps)
...    null_space = scipy.compress(null_mask, vh, axis=0)
...    return scipy.transpose(null_space)
>>> A = matrix([
...     [2,3,5],
...     [-4,2,3]
...     ])  
>>> null(A)
array([], shape=(3, 0), dtype=float64)
share|improve this question
The wikipedia page you linked to actually gives a very nice explanation of why you should use an SVD to calculate the null space (or solve) of a matrix when you're dealing with floating point values. en.wikipedia.org/wiki/… The approach you describe (solving for variables row-by-row) will amplify any rounding errors, etc. (This is the same reason you should almost never explicitly calculate the inverse of a matrix...) –  Joe Kington May 4 '11 at 20:29

2 Answers 2

up vote 1 down vote accepted

It appears to be working okay for me:

A = matrix([[2,3,5],[-4,2,3],[0,0,0]])
A * null(A)
>>> [[  4.02455846e-16]
>>>  [  1.94289029e-16]
>>>  [  0.00000000e+00]]
share|improve this answer
I'm sure I'm missing something, but Wikipedia suggests that the values should be [ [-.0625], [-1.625], [1] ]? –  Nona Urbiz May 4 '11 at 20:36
Moreover, it's returning an empty matrix for me []. What could be wrong? –  Nona Urbiz May 4 '11 at 20:58
@Nona Urbiz - It's returning an empty matrix because you're not putting in a row of zeros, as Bashwork (and wikipedia) does above. Also, the null space values returned ([-0.33, -0.85, 0.52]) are normalized so that the magnitude of the vector is 1. The wikipedia example is not normalized. If you just take n = null(A) and have a look at n / n.max(), you'll get [-.0625, -1.625, 1]. –  Joe Kington May 4 '11 at 21:08
Awesome. Thank you so much. That makes sense. –  Nona Urbiz May 4 '11 at 21:15
@Bashwork - How would I know to programmatically add a row of zeroes? Does the matrix have to be square? –  Coder Sep 2 '12 at 20:27

You get the SVD decomposition of the matrix A. s is a vector of eigenvalues. You are interested in almost zero eigenvalues (see $A*x=\lambda*x$ where $\abs(\lambda)<\epsilon$), which is given by the vector of logical values null_mask.

Then, you extract from the list vh the eigenvectors corresponding to the almost zero eigenvalues, which is exactly what you are looking for: a way to span the null space. Basically, you extract the rows and then transpose the results so that you get a matrix with eigenvectors as columns.

share|improve this answer
Thank you very much for taking the time to reply and help me. Your answer was very helpful to me, but I accepted Bashworks answer as ultimately, it brought me to the solution. The only reason I am able to understand the solution though, is your response. –  Nona Urbiz May 4 '11 at 21:16
No worry, I thought your problem was something else. –  Wok May 5 '11 at 10:03

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