I have two sets of vectors x_i \in R^n and z_i \in R^m
I want to find a transformation matrix W such that W x_i approximates z_i,
i.e. I want to find W that minimizes: sum_i || W x_i − z_i ||^2
Is there a Python function that does this?
I have two sets of vectors x_i \in R^n and z_i \in R^m
I want to find a transformation matrix W such that W x_i approximates z_i,
i.e. I want to find W that minimizes: sum_i || W x_i − z_i ||^2
Is there a Python function that does this?
Using this kronecker product identity it becomes a classic linear regression problem. But even without that, it is just the transpose of a linear regression setup.
import numpy as np
m, n = 3, 4
N = 100 # num samples
rng = np.random.RandomState(42)
W = rng.randn(m, n)
X = rng.randn(n, N)
Z_clean = W.dot(X)
Z = Z_clean + rng.randn(*Z_clean.shape) * .001
Using Z
and X
we can estimate W
by solving argmin_W ||X^T W^T - Z^T||^2
W_est = np.linalg.pinv(X.T).dot(Z.T).T
from numpy.testing import assert_array_almost_equal
assert_array_almost_equal(W, W_est, decimal=3)
Z = Z_clean + rng.randn(*Z_clean.shape) * .001
Feb 24, 2016 at 14:12
Z_clean
according to the model. Then I add noise (the line you are inquiring about does this) in order to show that the method works even if the data are slightly perturbed. The noise is Gaussian because a least-squares estimate implicitly assumes Gaussian noise.
Feb 24, 2016 at 20:54