A 1D numpy array* is literally 1D - it has no size in any second dimension, whereas in MATLAB, a '1D' array is actually 2D, with a size of 1 in its second dimension.

If you want your array to have size 1 in its second dimension you can use its `.reshape()`

method:

```
a = np.zeros(5,)
print(a.shape)
# (5,)
# explicitly reshape to (5, 1)
print(a.reshape(5, 1).shape)
# (5, 1)
# or use -1 in the first dimension, so that its size in that dimension is
# inferred from its total length
print(a.reshape(-1, 1).shape)
# (5, 1)
```

## Edit

As Akavall pointed out, I should also mention `np.newaxis`

as another method for adding a new axis to an array. Although I personally find it a bit less intuitive, one advantage of `np.newaxis`

over `.reshape()`

is that it allows you to add multiple new axes in an arbitrary order without explicitly specifying the shape of the output array, which is not possible with the `.reshape(-1, ...)`

trick:

```
a = np.zeros((3, 4, 5))
print(a[np.newaxis, :, np.newaxis, ..., np.newaxis].shape)
# (1, 3, 1, 4, 5, 1)
```

`np.newaxis`

is just an alias of `None`

, so you could do the same thing a bit more compactly using `a[None, :, None, ..., None]`

.

* An `np.matrix`

, on the other hand, is always 2D, and will give you the indexing behavior you are familiar with from MATLAB:

```
a = np.matrix([[2, 3], [4, 5]])
print(a[:, 0].shape)
# (2, 1)
```

For more info on the differences between arrays and matrices, see here.

`np.matrix`

will give you behavior that you expect. – Akavall Jun 17 '13 at 2:25