You could make use of the broadcasting functionality. This is a very powerful concept, that opend many doors to me once i understood it. The idea is that numpy does simple operations (+,-,*,/ etc.) element by element if you use it in combinations with two arrays. This means, that of course thy must have the same shape (same number of elements in each dimension). for example A.shape == (3,4) and B.shape == (3,4) you can do A*B and get in new array of the same shape where each element is the product of the elements in A and B at the same indexes.

```
a = ones((3,4))*2
b = ones((3,4))*3
c = a*b
print c.shape
> (3,4)
```

From that rule there is a smart exception: Whenever an array has only one element in a dimension certain dimension then it is broadcasted. This means this one dimension will be "blown up" along this axis with as many identical copies as needed to be compatible with the other array.

```
a = ones((3,4))*2
b = ones((1,4))*3
c = a*b
print c.shape
> (3,4)
```

Ok, for your problem you can use that by adding a dimensions into your arrays:
so you had a.shape = (2,) you want to get (2,1)
and b.shape = (3,) you want (1,3) so that is you use an operation on them it will be broadcasted so each element from a will be multiplied with each element from b. you do this by adding np.newaxis into your array

```
a = np.array((2,3))[:,np.newaxis]
b = np.array((5,6,7))[np.newaxis,:]
print a.shape
> (2,1)
print b.shape
> (1,3)
c = a*b
> (2,3)
```

now you will get an array of the shape (2,3) but you wanted a 1d array, so you can use flatten()
to sum up:

```
a = np.array((2,3))[:,np.newaxis]
b = np.array((5,6,7))[np.newaxis,:]
c = (a[:,np.newaxis]*b[np.newaxis,:]).flatten()
```

`numpy`

later in the answer. – Alex Thornton Apr 6 '14 at 14:02