You could indeed do this taking advantage of broadcasting.

Lets start by generating some random `ndarrays`

of the specified shape in order to check that the final dimensions are as expected:

```
a = np.random.rand(101, 256, 1, 3, 1, 10)
b = np.random.rand(101)
```

In this case you would have to add up to `a.ndim`

dimensions to `b`

so that each value in `b`

is subtracted to each of the values in the last dimension of `a`

. Following the idea from this post we can add up to `a.ndim`

new dimensionsions in a more concise way using `np.reshape`

as follows:

```
b = b.reshape((-1,) + (1,)*(a.ndim-1))
print(b.shape)
# (101, 1, 1, 1, 1, 1)
```

Now we could subtract `b`

from `a`

as required by doing:

```
a[..., 0, None] = a[..., 0, None] - b.reshape((-1,) + (1,) * (a.ndim-1))
```

And if we check the shape of `a`

:

```
print(a.shape)
# (101, 256, 1, 3, 1, 10)
```

### Details

Here are some explanations on some questions that might arise from the previous answer. Lets consider the following simpler example:

```
a = np.array([[1,2,3],[4,5,6]])
print(a)
array([[1, 2, 3],
[4, 5, 6]])
print(a.shape)
# (2, 3)
b = np.array([1,1])[:,None]
array([[1],
[1]])
print(b.shape)
# (2, 1)
```

So for this example, we could apply the same logic as the solution above with:

```
a[:,0,None] = a[:,0,None] - b
array([[0, 2, 3],
[3, 5, 6]])
```

Which by inspecting the resulting array, as expected `b`

has been subtracted from `a`

on the first index along its last axis, so the first column in all rows.

So first point,

Why do we have to add a new axis in `a`

for subtraction?

It is necessary to add a new axis to `a`

given the shape of `b`

. Note that `b`

is a 2-dimensional array `array([[1],[1]])`

, so if you were to subtract it directly from `a`

, you would get:

```
a[..., 0] - b
array([[0, 3],
[0, 3]])
```

So, what has happened here is that the smaller array, i.e. the first term, which is simply a `1D`

view slice from `a`

, `array([1, 4])`

, has been broadcasted across the larger array so that they have compatible shapes.

This would not be necessary if the shape of `b`

were instead `(2,)`

:

```
b = np.array([1,1])
a[:,0] - b
# array([0, 3])
```

But due to the way in which `b`

in the actual solution has been defined, it has the same amount of dimensions as `a`

. So in order to obtain the correct output, we must add a new axis to `a`

:

```
a[:,0,None] - b
array([[0],
[3]])
```

This way we obtain the correct output.

With the method above it doesn't seem possible to assign the difference to a new array acting as a "corrected copy" of a?

The answer to this question can be understood by taking a look at the result from the subtraction:

```
c = a[:,0,None] - b
c.shape
(2, 1)
```

So here `a[:,0,None]`

is what is called a "sliced view" of `a`

. So note that by assigning this result to `c`

, you are only saving the actual `sliced wiew`

of `a`

, not the entire `ndarray`

. If you want to modify `a`

on the same positions of the actual slice, you will have to assign it to a same sliced view of `a`

, so:

```
a[:,0,None] = a[:,0,None] - b
print(a.shape)
# (2, 3)
```

Now the result does have the expected output, as we have only modified a slice of `a`

. If you did want to save a copy of the original `ndarray`

you could use `np.copy`

, which will return an actual copy rather than a slice of `a`

, and then assign the result to the "corrected copy":

```
a_c = np.copy(a)
a_c[:,0,None] = a[:,0,None] - b
```