Suppose that `f`

is a function of one parameter whose output is an *n*-dimensional (*m*_{1} × *m*_{2}… × *m*_{n}) array, and that `B`

is a vector of length *k* whose elements are all valid arguments for `f`

.

I am looking for a convenient, and more importantly, "shape-agnostic", MATLAB expression (or recipe) for producing the (

n+1)-dimensional (m_{1}×m_{2}×…×m_{n}×k) array obtained by "stacking" thekn-dimensional arrays`f(b)`

, where the parameter`b`

ranges over`B`

.

To do this in `numpy`

, I would use an expression like this one:

```
C = concatenate([f(b)[..., None] for b in B], -1)
```

In case it's of any use, I'll unpack this numpy expression below (see **APPENDIX**), but the feature of it that I want to emphasize now is that *it is entirely agnostic about the shapes/sizes of* `f(b)`

*and* `B`

. For the types of applications I have in mind, the ability to write such "shape-agnostic" code is of *utmost importance*. (I stress this point because much MATLAB code I come across for doing this sort of manipulation is decidedly not "shape-agnostic", and I don't know how to make it so.)

**APPENDIX**

In general, if `A`

is a numpy array, then the expression `A[..., None]`

can be thought as "reshaping" `A`

so that it gets one extra, trivial, dimension. Thus, if `f(b)`

is an *n*-dimensional (*m*_{1} × *m*_{2}… × *m*_{n}) array, then, `f(b)[..., None]`

is the corresponding (*n*+1)-dimensional (*m*_{1} × *m*_{2} ×…× *m*_{n} × 1) array. (The reason for adding this trivial dimension will become clear below.)

With this clarification out of the way, the meaning of the first argument to `concatenate`

, namely:

```
[f(b)[..., None] for b in B]
```

is not too hard to decipher. It is a standard Python "list comprehension", and it evaluates to the sequence of the *k* (*n*+1)-dimensional (*m*_{1} × *m*_{2} ×…× *m*_{n} × 1) arrays `f(b)[..., None]`

, as the parameter `b`

ranges over the vector `B`

.

The second argument to `concatenate`

is the "axis" along which the concatenation is to be performed, expressed as the index of the corresponding dimension of the arrays to be concatenated. In this context, the index -1 plays the same role as the `end`

keyword does in MATLAB. Therefore, the expression

```
concatenate([f(b)[..., None] for b in B], -1)
```

says "concatenate the arrays `f(b)[..., None]`

along their last dimension". It is in order to provide this "last dimension" to concatenate over that it becomes necessary to reshape the `f(b)`

arrays (with, e.g., `f(b)[..., None]`

).