Assuming I understood you correctly, you can do what you want in the following way (the comments explain what I do step by step):

```
% allocate space for the output
R = zeros(80, 90, 19);
% iterate over all 19 sets
for i=1:19
% extract ith set of 20 matrices to a separate cell
icell = {C{:,1,i}};
% concatenate all 20 matrices and reshape the result
% so that one matrix is kept in one column of A
% as a vector of size 80*90
A = reshape([icell{:}], 80*90, 20);
% sum all 20 matrices and calculate the mean
% the result is a vector of size 80*90
A = sum(A, 2)/20;
% reshape A into a matrix of size 80*90
% and save to the result matrix
R(:,:,i) = reshape(A, 80, 90);
end
```

You could skip the extraction to `icell`

and concatenate the ith set of 20 matrices directly

```
A = reshape([C{:,1,i}], 80*90, 20);
```

I only did it here for some clarity.

The above steps can be more briefly (but definitely much more cryptically!) expressed by the following `arrayfun`

call:

```
F = @(i)(reshape(sum(reshape([C{:,1,i}], 80*90, 20), 2)/20, 80, 90));
R = arrayfun(F, 1:19, 'uniform', false);
R = reshape([R2{:}], 80, 90, 19);
```

The anonymous function `F`

does essentially one iteration of the loop. It is called 19 times by `arrayfun`

, once for every set of matrices. I would suggest you stick with the loop.