I'm reviewing some `eigenvector/value`

stuff using `numpy`

.

A part of `help(numpy.linalg.eig)`

tells me that:

```
The number `w` is an eigenvalue of `a` if there exists a vector `v` such that
``dot(a,v) = w * v``. Thus, the arrays `a`, `w`, and `v` satisfy the
equations ``dot(a[i,:], v[i]) = w[i] * v[:,i]`` for :math:`i \in \{0,...,M-1\}`.
```

Unless I'm mistaken (and the documentation is wrong) - which is unlikely - the dot product produces a scalar while `w[i]*v[:,i]`

(which I assume is simply scalar multiplication of a vector) produces another vector and thus there's no way of establishing equality?

It may be some further indication of my confusion that I'm not able to compute `dot(a[i,:], v[i])`

directly - numpy tells me that the objects are not aligned.

```
>>> np.dot(a[1,:], v[1])
Traceback (most recent call last):
File "<stdin>", line 1, in <module>
ValueError: objects are not aligned
>>> a[1,:].shape
(1, 2)
>>> v[1].shape
(1, 2)
>>> a[1,:]
matrix([[-1, -4]])
>>> v[1]
matrix([[ 0.24253563, -0.9701425 ]])
>>> np.dot(a[1].ravel().tolist()[0] ,v[1].ravel().tolist()[0])
3.6380343755449944
```