`np.dot`

is a generalization of matrix multiplication.
In regular matrix multiplication, an (N,M)-shape matrix multiplied with a (M,P)-shaped matrix results in a (N,P)-shaped matrix. The resultant shape can be thought of as being formed by squashing the two shapes together (`(N,M,M,P)`

) and then removing the middle numbers, `M`

(to produce `(N,P)`

). This is the property that `np.dot`

preserves while generalizing to arrays of higher dimension.

When the docs say,

"For N dimensions it is a sum product over the last axis of a and the
second-to-last of b".

it is speaking to this point. An array of shape `(u,v,M)`

dotted with an array of shape `(w,x,y,M,z)`

would result in an array of shape `(u,v,w,x,y,z)`

.

Let's see how this rule looks when applied to

```
In [25]: V = np.arange(2); V
Out[25]: array([0, 1])
In [26]: M = np.arange(4).reshape(2,2); M
Out[26]:
array([[0, 1],
[2, 3]])
```

First, the easy part:

```
In [27]: np.dot(M, V)
Out[27]: array([1, 3])
```

There is no surprise here; this is just matrix-vector multiplication.

Now consider

```
In [28]: np.dot(V, M)
Out[28]: array([2, 3])
```

Look at the shape of V and M:

```
In [29]: V.shape
Out[29]: (2,)
In [30]: M.shape
Out[30]: (2, 2)
```

So `np.dot(V,M)`

is like matrix multiplication of a (2,)-shaped matrix with a (2,2)-shaped matrix, which should result in a (2,)-shaped matrix.

The last (and only) axis of `V`

and the second-to-last axis of `M`

(aka the first axis of `M`

) are multiplied and summed over, leaving only the last axis of `M`

.

If you want to visualize this: `np.dot(V, M)`

looks as though V has 1 row and 2 columns:

```
[[0, 1]] * [[0, 1],
[2, 3]]
```

and so, when V is multiplied by M, `np.dot(V, M)`

equals

```
[[0*0 + 1*2], [2,
[0*1 + 1*3]] = 3]
```

However, I don't really recommend trying to visualize NumPy arrays this way -- at least I never do. I focus almost exclusively on the shape.

```
(2,) * (2,2)
\ /
\ /
(2,)
```

You just think about the "middle" axes being dotted, and disappearing from the resultant shape.

`np.sum(arr, axis=0)`

tells NumPy to sum the elements in `arr`

*eliminating* the 0th axis. If `arr`

is 2-dimensional, the 0th axis are the rows. So for example, if `arr`

looks like this:

```
In [1]: arr = np.arange(6).reshape(2,3); arr
Out[1]:
array([[0, 1, 2],
[3, 4, 5]])
```

then `np.sum(arr, axis=0)`

will sum along the columns, thus *eliminating* the 0th axis (i.e. the rows).

```
In [2]: np.sum(arr, axis=0)
Out[2]: array([3, 5, 7])
```

The 3 is the result of 0+3, the 5 equals 1+4, the 7 equals 2+5.

Notice `arr`

had shape (2,3), and after summing, the 0th axis is *removed* so the result is of shape (3,). The 0th axis had length 2, and each sum is composed of adding those 2 elements. The shape (2,3) "becomes" (3,). You can know the resultant shape in advance! This can help guide your thinking.

To test your understanding, consider `np.sum(arr, axis=1)`

. Now the 1-axis is removed. So the resultant shape will be `(2,)`

, and element in the result will be the sum of 3 values.

```
In [3]: np.sum(arr, axis=1)
Out[3]: array([ 3, 12])
```

The 3 equals 0+1+2, and the 12 equals 3+4+5.

So we see that summing an axis *eliminates* that axis from the result. This has bearing on `np.dot`

, since the calculation performed by `np.dot`

is a *sum* of products. Since `np.dot`

performs a summing operation along certain axes, that axis is removed from the result. That is why applying `np.dot`

to arrays of shape (2,) and (2,2) results in an array of shape (2,). The first 2 in both arrays is summed over, eliminating both, leaving only the second 2 in the second array.