# How does numpy.newaxis work and when to use it?

When I try

``````numpy.newaxis
``````

the result gives me a 2-d plot frame with x-axis from 0 to 1. However, when I try using `numpy.newaxis` to slice a vector,

``````vector[0:4,]
[ 0.04965172  0.04979645  0.04994022  0.05008303]
vector[:, np.newaxis][0:4,]
[[ 0.04965172]
[ 0.04979645]
[ 0.04994022]
[ 0.05008303]]
``````

Is it the same thing except that it changes a row vector to a column vector?

Generally, what is the use of `numpy.newaxis`, and in which circumstances should we use it?

Simply put, `numpy.newaxis` is used to increase the dimension of the existing array by one more dimension, when used once. Thus,

• 1D array will become 2D array

• 2D array will become 3D array

• 3D array will become 4D array

• 4D array will become 5D array

and so on..

Here is a visual illustration which depicts promotion of 1D array to 2D arrays. Scenario-1: `np.newaxis` might come in handy when you want to explicitly convert a 1D array to either a row vector or a column vector, as depicted in the above picture.

Example:

``````# 1D array
In : arr = np.arange(4)
In : arr.shape
Out: (4,)

# make it as row vector by inserting an axis along first dimension
In : row_vec = arr[np.newaxis, :]     # arr[None, :]
In : row_vec.shape
Out: (1, 4)

# make it as column vector by inserting an axis along second dimension
In : col_vec = arr[:, np.newaxis]     # arr[:, None]
In : col_vec.shape
Out: (4, 1)
``````

Scenario-2: When we want to make use of numpy broadcasting as part of some operation, for instance while doing addition of some arrays.

Example:

Let's say you want to add the following two arrays:

`````` x1 = np.array([1, 2, 3, 4, 5])
x2 = np.array([5, 4, 3])
``````

If you try to add these just like that, NumPy will raise the following `ValueError` :

``````ValueError: operands could not be broadcast together with shapes (5,) (3,)
``````

In this situation, you can use `np.newaxis` to increase the dimension of one of the arrays so that NumPy can broadcast.

``````In : x1_new = x1[:, np.newaxis]    # x1[:, None]
# now, the shape of x1_new is (5, 1)
# array([,
#        ,
#        ,
#        ,
#        ])
``````

``````In : x1_new + x2
Out:
array([[ 6,  5,  4],
[ 7,  6,  5],
[ 8,  7,  6],
[ 9,  8,  7],
[10,  9,  8]])
``````

Alternatively, you can also add new axis to the array `x2`:

``````In : x2_new = x2[:, np.newaxis]    # x2[:, None]
In : x2_new     # shape is (3, 1)
Out:
array([,
,
])
``````

``````In : x1 + x2_new
Out:
array([[ 6,  7,  8,  9, 10],
[ 5,  6,  7,  8,  9],
[ 4,  5,  6,  7,  8]])
``````

Note: Observe that we get the same result in both cases (but one being the transpose of the other).

Scenario-3: This is similar to scenario-1. But, you can use `np.newaxis` more than once to promote the array to higher dimensions. Such an operation is sometimes needed for higher order arrays (i.e. Tensors).

Example:

``````In : arr = np.arange(5*5).reshape(5,5)

In : arr.shape
Out: (5, 5)

# promoting 2D array to a 5D array
In : arr_5D = arr[np.newaxis, ..., np.newaxis, np.newaxis]    # arr[None, ..., None, None]

In : arr_5D.shape
Out: (1, 5, 5, 1, 1)
``````

As an alternative, you can use `numpy.expand_dims` that has an intuitive `axis` kwarg.

``````# adding new axes at 1st, 4th, and last dimension of the resulting array
In : newaxes = (0, 3, -1)
In : arr_5D = np.expand_dims(arr, axis=newaxes)
In : arr_5D.shape
Out: (1, 5, 5, 1, 1)
``````

More background on np.newaxis vs np.reshape

`newaxis` is also called as a pseudo-index that allows the temporary addition of an axis into a multiarray.

`np.newaxis` uses the slicing operator to recreate the array while `numpy.reshape` reshapes the array to the desired layout (assuming that the dimensions match; And this is must for a `reshape` to happen).

Example

``````In : A = np.ones((3,4,5,6))
In : B = np.ones((4,6))
In : (A + B[:, np.newaxis, :]).shape     # B[:, None, :]
Out: (3, 4, 5, 6)
``````

In the above example, we inserted a temporary axis between the first and second axes of `B` (to use broadcasting). A missing axis is filled-in here using `np.newaxis` to make the broadcasting operation work.

General Tip: You can also use `None` in place of `np.newaxis`; These are in fact the same objects.

``````In : np.newaxis is None
Out: True
``````

P.S. Also see this great answer: newaxis vs reshape to add dimensions

## What is `np.newaxis`?

The `np.newaxis` is just an alias for the Python constant `None`, which means that wherever you use `np.newaxis` you could also use `None`:

``````>>> np.newaxis is None
True
``````

It's just more descriptive if you read code that uses `np.newaxis` instead of `None`.

## How to use `np.newaxis`?

The `np.newaxis` is generally used with slicing. It indicates that you want to add an additional dimension to the array. The position of the `np.newaxis` represents where I want to add dimensions.

``````>>> import numpy as np
>>> a = np.arange(10)
>>> a
array([0, 1, 2, 3, 4, 5, 6, 7, 8, 9])
>>> a.shape
(10,)
``````

In the first example I use all elements from the first dimension and add a second dimension:

``````>>> a[:, np.newaxis]
array([,
,
,
,
,
,
,
,
,
])
>>> a[:, np.newaxis].shape
(10, 1)
``````

The second example adds a dimension as first dimension and then uses all elements from the first dimension of the original array as elements in the second dimension of the result array:

``````>>> a[np.newaxis, :]  # The output has 2 [] pairs!
array([[0, 1, 2, 3, 4, 5, 6, 7, 8, 9]])
>>> a[np.newaxis, :].shape
(1, 10)
``````

Similarly you can use multiple `np.newaxis` to add multiple dimensions:

``````>>> a[np.newaxis, :, np.newaxis]  # note the 3 [] pairs in the output
array([[,
,
,
,
,
,
,
,
,
]])
>>> a[np.newaxis, :, np.newaxis].shape
(1, 10, 1)
``````

## Are there alternatives to `np.newaxis`?

There is another very similar functionality in NumPy: `np.expand_dims`, which can also be used to insert one dimension:

``````>>> np.expand_dims(a, 1)  # like a[:, np.newaxis]
>>> np.expand_dims(a, 0)  # like a[np.newaxis, :]
``````

But given that it just inserts `1`s in the `shape` you could also `reshape` the array to add these dimensions:

``````>>> a.reshape(a.shape + (1,))  # like a[:, np.newaxis]
>>> a.reshape((1,) + a.shape)  # like a[np.newaxis, :]
``````

Most of the times `np.newaxis` is the easiest way to add dimensions, but it's good to know the alternatives.

## When to use `np.newaxis`?

In several contexts is adding dimensions useful:

• If the data should have a specified number of dimensions. For example if you want to use `matplotlib.pyplot.imshow` to display a 1D array.

• If you want NumPy to broadcast arrays. By adding a dimension you could for example get the difference between all elements of one array: `a - a[:, np.newaxis]`. This works because NumPy operations broadcast starting with the last dimension 1.

• To add a necessary dimension so that NumPy can broadcast arrays. This works because each length-1 dimension is simply broadcast to the length of the corresponding1 dimension of the other array.

1 If you want to read more about the broadcasting rules the NumPy documentation on that subject is very good. It also includes an example with `np.newaxis`:

``````>>> a = np.array([0.0, 10.0, 20.0, 30.0])
>>> b = np.array([1.0, 2.0, 3.0])
>>> a[:, np.newaxis] + b
array([[  1.,   2.,   3.],
[ 11.,  12.,  13.],
[ 21.,  22.,  23.],
[ 31.,  32.,  33.]])
``````

You started with a one-dimensional list of numbers. Once you used `numpy.newaxis`, you turned it into a two-dimensional matrix, consisting of four rows of one column each.

You could then use that matrix for matrix multiplication, or involve it in the construction of a larger 4 x n matrix.

`newaxis` object in the selection tuple serves to expand the dimensions of the resulting selection by one unit-length dimension.

It is not just conversion of row matrix to column matrix.

Consider the example below:

``````In :x1 = np.arange(1,10).reshape(3,3)
print(x1)
Out: array([[1, 2, 3],
[4, 5, 6],
[7, 8, 9]])
``````

Now lets add new dimension to our data,

``````In :x1_new = x1[:,np.newaxis]
print(x1_new)
Out:array([[[1, 2, 3]],

[[4, 5, 6]],

[[7, 8, 9]]])
``````

You can see that `newaxis` added the extra dimension here, x1 had dimension (3,3) and X1_new has dimension (3,1,3).

How our new dimension enables us to different operations:

``````In :x2 = np.arange(11,20).reshape(3,3)
print(x2)
Out:array([[11, 12, 13],
[14, 15, 16],
[17, 18, 19]])
``````

Adding x1_new and x2, we get:

``````In :x1_new+x2
Out:array([[[12, 14, 16],
[15, 17, 19],
[18, 20, 22]],

[[15, 17, 19],
[18, 20, 22],
[21, 23, 25]],

[[18, 20, 22],
[21, 23, 25],
[24, 26, 28]]])
``````

Thus, `newaxis` is not just conversion of row to column matrix. It increases the dimension of matrix, thus enabling us to do more operations on it.