I'm getting inverse of matrix even if determinant is zero. I tried with the code below:
import numpy as np
from scipy import linalg
matrix=np.array([[5,10],[2,4]])
print(linalg.det(matrix))
linalg.inv(matrix)
The problem here is a disconnect between how different routines calculate the matrix determinant. For example:
import numpy as np
matrix=np.array([[5.,10.],[2.,4.]])
print(np.linalg.det(matrix))
print(np.linalg.slogdet(matrix))
try:
invmatrix=np.linalg.inv(matrix)
except np.linalg.LinAlgError:
print("inversion failed")
produces no exception and prints this:
-1.1102230246251625e-15
(-1.0, -34.43421547668305)
i.e. not using a direct algebraic calculation of the determinant (which scipy.linalg.det
does) yields a non-zero determinant, because of accumulated floating point rounding error. Thus the standard linear algebra routines treat the matrix as non-singular and produce an incorrect inverse from an extremely poor conditioned problem.
(Tested with numpy version 1.15.4 and scipy version 1.1.0)
NameError: name 'matrix' is not defined on line 5
.singular matrix
error, are you sure you're not callinglinalg.pinv
somewhere else?