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I want to subtract all values in a[nn,...,0] by b[nn] while keeping the original structure of the array a.


I have a problem with indexing and elementwise subtraction from an ndnumpy array. In my case, array a has 6 dimensions

In[]: a.shape
Out[]: (101, 256, 1, 3, 1, 10)

For the sake of consistency, the lowest dimension N=0 has 10 elements and the highest N=5 has 101 elements.

I also have a 1D array b which is the same size as the highest dimension in a.

In[]: b.shape
Out[]: (101,)

I want to subtract b from a in such a way that the nn-th element in b is subtracted from the values a[nn,...,0]. I know I can do this using for loops, but it should also be possible to broadcast b in such a way that I can use something like

In[]: c= a[:,...,0]-b[somehow broadcastet or reshaped]
In[]: c.shape()
Out[]:  (101, 256, 1, 3, 1, 10)
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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
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    Ok I got it. Thank you very much for your time. – Katoon Mar 6 '19 at 12:18

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