I've been working with numpy
matrices in an algorithm lately and I've encountered a problem :
I use 3 matrices in total.
m1 = [[ 3 2 2 ... 3 2 3]
[ 3 3 3 ... 2 2 2]
[500 501 502 ... 625 626 627]
...
[623 624 625 ... 748 749 750]
[624 625 626 ... 749 750 751]
[625 626 627 ... 750 751 752]]
m1
is a (128,128) singular square matrix. The first two rows are seemingly random sequences of 2s and 3s. The next rows are filled algorithmically counting from 500, adding one for each row and for each column starting from the third row, first column.
m2 = [[ 2 3 500 ... 623 624 625]
[ 2 2 500 ... 623 624 625]
[ 3 2 500 ... 623 624 625]
...
[ 2 3 500 ... 623 624 625]
[ 2 2 500 ... 623 624 625]
[ 3 2 500 ... 623 624 625]]
m2
is also a (128,128) singular square matrix. This time, the random sequences are attributed to the first two columns. The rest of each row is filled with 500, 501, 502, 503, and so on.
m3 = [[ 790 784 157500 ... 196245 196560 196875]
[ 804 811 161000 ... 200606 200928 201250]
[ 180501 180411 36064000 ... 44935744 45007872 45080000]
...
[ 219861 219771 43936000 ... 54744256 54832128 54920000]
[ 220181 220091 44000000 ... 54824000 54912000 55000000]
[ 220501 220411 44064000 ... 54903744 54991872 55080000]]
m3 = m1*m2
So what I wanted to do was to recover m2
using m1
and m3
. Theoretically, all I had to do was execute the following code m2 = (m1**-1)*m3
. Unfortunately, due to m1
being a singular matrix, it was not possible to calculate its inverse and, even if it were possible, the matrix was too big, causing numerous numerical imprecisions.
Instead, I decided to use the Moore-Penrose Inverse of m1
, which doesn't require the matrix to be non-singular and, similarly to the Inverse, makes it theoretically possible to recover m2
, using np.linalg.pinv(m1) * m3
.
Once again, I use the term "theoretically" because, as it turns out, numpy
is too imprecise when it comes to such calculations with big matrices, and here's the result I obtain for m2
:
[[ 2.46207616 2.48959603 500. ... 623. 624.
625. ]
[ 2.38612549 2.61197086 500. ... 623. 624.
625. ]
[ 2.38711085 2.6125801 500. ... 623. 624.
625. ]
...
[ 2.61998539 2.37184747 500. ... 623. 624.
625. ]
[ 2.54403472 2.4942223 500. ... 623. 624.
625. ]
[ 2.62195611 2.37306595 500. ... 623. 624.
625. ]]
As you can see, the whole 'filler' part of m1
is correctly calculated, no problem with that. However, it seemed to have problems with the first two columns, and rounding the numbers to 2s and 3s gives me an incorrect m2
.
I'm looking for a way to make the np.linalg.pinv()
method way more precise with its float calculations so it can obtain the proper values for the sequences, as those are very important.
By doing some research, I learned that np.linalg.pinv()
has an argument called rcond
, described as the following :
rcond : (…) array_like of float
Cutoff for small singular values. Singular values smaller (in modulus) than rcond * largest_singular_value (again, in modulus) are set to zero. Broadcasts against the stack of matrices
rcond
is, by default, set to 1e-15
. I thought that reducing that number even further could help with imprecision. 1e-16
wasn't enough and, starting from 1e-17
, I get very weird values, such as those :
[[ 3.000e+00 3.000e+00 5.000e+02 ... 6.230e+02 6.240e+02 6.250e+02]
[ 1.100e+01 4.000e+00 1.840e+02 ... 1.722e+03 2.032e+03 1.831e+03]
[-3.000e+00 -5.000e+00 -4.030e+02 ... -1.232e+03 -7.400e+02 -1.272e+03]
...
[ 1.100e+01 1.200e+01 2.164e+03 ... 4.030e+03 4.872e+03 1.873e+03]
[-1.200e+01 -9.000e+00 -1.618e+03 ... -3.240e+03 -2.519e+03 -4.167e+03]
[ 2.000e+01 2.600e+01 4.535e+03 ... 5.165e+03 5.881e+03 5.189e+03]]
So, basically, I'm stuck, I don't know how to increase precision.
Worst part is, I have a module that can dramatically increase float precision, it's called mpmath
and also has matrices that appear to work even better with my algorithm as the numpy
ones. But mpmath
doesn't have a method to calculate pseudoinverses, and numpy
doesn't adapt its own float precision to the value set with mpmath
.
Would you have any suggestions I could try to get the correct m2
using the pseudoinverse method ?
m1 @ m2_estimated == m3
, roughly?m1
will typically have rank4
and a124D
nullspace. In other words each column ofm2_recon
has 124 degrees of freedom that are not constrained by the requirementm1@x == m3
numpy
doesn't return an Exception for Singular Matrices ? It does that usually. @Eric I might try to use information aboutm2
to better recover its first two lines, but I'm still not sure how to do it. Then again, if I had slight imprecision that wouldn't be a problem, but, to give you an idea :m3[0] = [[ 780 791 160000 ... 199360 199680 200000]]
;(m1 @ m2_estimated)[0] = [[2.53173393e+02 3.53364135e+02 6.06764737e+04 ... 1.42436998e+05 9.72372952e+04 8.91055922e+04]
@Paul Panzer What would you recommend ?