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, 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)

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)
  • 2
    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

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]]
  • 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
  • 1
    Moreover, it's returning an empty matrix for me []. What could be wrong? – Nona Urbiz May 4 '11 at 20:58
  • 7
    @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
  • 3
    @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

Sympy makes this straightforward.

>>> from sympy import Matrix
>>> A = [[2, 3, 5], [-4, 2, 3], [0, 0, 0]]
>>> A = Matrix(A)
>>> A * A.nullspace()[0]
>>> A.nullspace()
[    1]])]
  • Exactly the solution I was looking for! – cxxl Apr 30 '18 at 14:46

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.

  • 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

A faster but less numerically stable method is to use a rank-revealing QR decomposition, such as scipy.linalg.qr with pivoting=True:

import numpy as np
from scipy.linalg import qr

def qr_null(A, tol=None):
    Q, R, P = qr(A.T, mode='full', pivoting=True)
    tol = np.finfo(R.dtype).eps if tol is None else tol
    rnk = min(A.shape) - np.abs(np.diag(R))[::-1].searchsorted(tol)
    return Q[:, rnk:].conj()

For example:

A = np.array([[ 2, 3, 5],
              [-4, 2, 3],
              [ 0, 0, 0]])
Z = qr_null(A)

#[[  4.44089210e-16]
# [  6.66133815e-16]
# [  0.00000000e+00]]

Your method is almost correct. The issue is that the shape of s returned by the function scipy.linalg.svd is (K,) where K=min(M,N). Thus, in your example, s only has two entries (the singular values of the first two singular vectors). The following correction to your null function should allow it to work for any sized matrix.

import scipy
import numpy as np
from scipy import linalg, matrix
def null(A, eps=1e-12):
...    u, s, vh = scipy.linalg.svd(A)
...    padding = max(0,np.shape(A)[1]-np.shape(s)[0])
...    null_mask = np.concatenate(((s <= eps), np.ones((padding,),dtype=bool)),axis=0)
...    null_space = scipy.compress(null_mask, vh, axis=0)
...    return scipy.transpose(null_space)
A = matrix([[2,3,5],[-4,2,3]])
print A*null(A)
>>>[[  4.44089210e-16]
>>> [  6.66133815e-16]]
A = matrix([[1,0,1,0],[0,1,0,0],[0,0,0,0],[0,0,0,0]])
print null(A)
>>>[[ 0.         -0.70710678]
>>> [ 0.          0.        ]
>>> [ 0.          0.70710678]
>>> [ 1.          0.        ]]
print A*null(A)
>>>[[ 0.  0.]
>>> [ 0.  0.]
>>> [ 0.  0.]
>>> [ 0.  0.]]
  • 1
    I have been using this code in my work and I noticed a problem. An eps value of 1e-15 seems to be too small. Notably, consider the matrix A = np.ones(13,2). This code will report that this matrix has a rank 0 null space. This is due to the scipy.linalg.svd function reporting that the second singular value is above 1e-15. I don't know much about the algorithms behind this function, however I suggest using eps=1e-12 (and perhaps lower for very large matrices) unless someone with more knowledge can chime in. (In infinite precision the second singular value should be 0). – Thomas Wentworth Dec 19 '14 at 16:55

As of last year (2017), scipy now has a built-in null_space method in the scipy.linalg module (docs).

The implementation follows the canonical SVD decomposition and is pretty small if you have an older version of scipy and need to implement it yourself (see below). However, if you're up-to-date, it's there for you.

def null_space(A, rcond=None):
    u, s, vh = svd(A, full_matrices=True)
    M, N = u.shape[0], vh.shape[1]
    if rcond is None:
        rcond = numpy.finfo(s.dtype).eps * max(M, N)
    tol = numpy.amax(s) * rcond
    num = numpy.sum(s > tol, dtype=int)
    Q = vh[num:,:].T.conj()
    return Q

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