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
>>> w
array([ 1.256 , 1.1937, 0.7273, 0.9516, 0.8714])
```

However, if say `x[4] - 2 * x[0] - 3 * x[2] = 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)
>>> w
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:

```
>>> v[:,0]
array([-0.4077, 0.0059, -0.5886, 0.0018, 0.6981])
```

Ignoring *almost zero* coefficients, above basically says `x[0]`

, `x[2]`

and `x[4]`

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()
(0, 0.0083)
```

Note that `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.