# Python pseudo inverse and determinant of a vector

How to compute the pseudo inverse of a vector and also the determinant? (preferably with either numpy, or better pandas)

I tried this but it doesn't work:

``````import numpy
vect = [1, 2, 3, 4]
numpy.linalg.pinv(vect)
``````

But I get this error:

``````---------------------------------------------------------------------------
LinAlgError                               Traceback (most recent call last)
<ipython-input-106-e362654e383f> in <module>()
19 vect = [1, 2, 3, 4]
---> 20 print(np.linalg.pinv(vect))

C:\Python27\lib\site-packages\numpy\linalg\linalg.pyc in pinv(a, rcond)
1544     _assertNonEmpty(a)
1545     a = a.conjugate()
-> 1546     u, s, vt = svd(a, 0)
1547     m = u.shape[0]
1548     n = vt.shape[1]

C:\Python27\lib\site-packages\numpy\linalg\linalg.pyc in svd(a, full_matrices, compute_uv)
1269     """
1270     a, wrap = _makearray(a)
-> 1271     _assertRank2(a)
1272     _assertNonEmpty(a)
1273     m, n = a.shape

C:\Python27\lib\site-packages\numpy\linalg\linalg.pyc in _assertRank2(*arrays)
153         if len(a.shape) != 2:
154             raise LinAlgError, '%d-dimensional array given. Array must be \
--> 155             two-dimensional' % len(a.shape)
156
157 def _assertSquareness(*arrays):

LinAlgError: 1-dimensional array given. Array must be             two-dimensional
``````
-

Perhaps you want this?

``````>>> np.linalg.pinv([[1, 2, 3, 4]])
array([[ 0.03333333],
[ 0.06666667],
[ 0.1       ],
[ 0.13333333]])
``````

Note the extra set of brackets. As the error message suggests, you can only take the pseudo-inverse of a matrix. If you just have a vector you need to make it into a 1-row matrix.

-
Thank's for the tip! Indeed it works for linalg.pinv, but it does not for linalg.det! (error: "Array must be square") Do you have any idea how I can deal with det? –  gaborous Apr 8 '13 at 19:33
@user1121352: Can I ask what use case you have for a determinant of a non-square matrix? –  DSM Apr 8 '13 at 19:38
@user1121352: The determinant is only mathematically defined for square matrices. –  BrenBarn Apr 8 '13 at 19:38
No it's okay, I was adapting a code I did in the past with Octave, and the Octave's diag() function both can return a vector from a matrix, or a matrix from a vector (highly confusing!). Thank's for the tip, I keep it in my books. –  gaborous Apr 8 '13 at 19:41
@BrenBarn: there are actually some generalizations you can make and still call something a determinant, but they're pretty obscure, and seldom useful. (BTW, your avatar takes me way back..) –  DSM Apr 8 '13 at 19:44