I think I get what you're asking, but I'm not completely sure how does the `ndimage.generic_filter`

work (how abstruse is the source!).

Here's just a simple wrapper function. This function will take in an array, all the parameters `ndimage.generic_filter`

needs. Function returns an array where each **element** of the former array is now represented by an **array** with shape (2,), result of the function is stored as the second element of that array.

```
def generic_expand_filter(inarr, func, **kwargs):
shape = inarr.shape
res = np.empty(( shape+(2,) ))
temp = ndimage.generic_filter(inarr, func, **kwargs)
for row in range(shape[0]):
for val in range(shape[1]):
res[row][val][0] = inarr[row][val]
res[row][val][1] = temp[row][val]
return res
```

Output, where `res`

denotes just the `generic_filter`

and res2 denotes `generic_expand_filter`

, of this function is:

```
>>> a.shape #same as res.shape
(10, 10)
>>> res2.shape
(10, 10, 2)
>>> a[0]
array([ 0., 1., 2., 3., 4., 5., 6., 7., 8., 9.])
>>> res[0]
array([ 3., 8., 16., 24., 32., 40., 48., 56., 64., 69.])
>>> print(*res2[0], sep=", ") #this is just to avoid the vertical default output
[ 0. 3.], [ 1. 8.], [ 2. 16.], [ 3. 24.], [ 4. 32.], [ 5. 40.], [ 6. 48.], [ 7. 56.], [ 8. 64.], [ 9. 69.]
>>> a[0][0]
0.0
>>> res[0][0]
3.0
>>> res2[0][0]
array([ 0., 3.])
```

Of course you probably don't want to save the old array, but instead have both fields as new results. Except I don't know what exactly you had in mind, if the two values you want stored are unrelated, just add a `temp2`

and `func2`

and call another `generic_filter`

with the same `**kwargs`

and store that as the first value.

However if you want an actual vector quantity that is calculated using multiple `inarr`

elements, meaning that the two new created fields aren't independent, you are just going to have to write that kind of a function, one that takes in an array, `idx`

, `idy`

indices and returns a tuple\list\array value which you can then unpack and assign to the result.