You can detect high-multi-collinearity by inspecting the eigen values of correlation matrix. A very low eigen value shows that the data are collinear, and the corresponding eigen vector shows which variables are collinear.
If there is no collinearity in the data, you would expect that none of the eigen values are close to zero:
>>> xs = np.random.randn(100, 5) # independent variables
>>> corr = np.corrcoef(xs, rowvar=0) # correlation matrix
>>> w, v = np.linalg.eig(corr) # eigen values & eigen vectors
array([ 1.256 , 1.1937, 0.7273, 0.9516, 0.8714])
However, if say
x - 2 * x - 3 * x = 0, then
>>> noise = np.random.randn(100) # white noise
>>> xs[:,4] = 2 * xs[:,0] + 3 * xs[:,2] + .5 * noise # collinearity
>>> corr = np.corrcoef(xs, rowvar=0)
>>> w, v = np.linalg.eig(corr)
array([ 0.0083, 1.9569, 1.1687, 0.8681, 0.9981])
one of the eigen values (here the very first one), is close to zero. The corresponding eigen vector is:
array([-0.4077, 0.0059, -0.5886, 0.0018, 0.6981])
Ignoring almost zero coefficients, above basically says
x are colinear (as expected). If one standardizes
xs values and multiplies by this eigen vector, the result will hover around zero with small variance:
>>> std_xs = (xs - xs.mean(axis=0)) / xs.std(axis=0) # standardized values
>>> ys = std_xs.dot(v[:,0])
>>> ys.mean(), ys.var()
ys.var() is basically the eigen value which was close to zero.
So, in order to capture high multi-linearity, look at the eigen values of correlation matrix.