# sum of each 24 elements in a matrix

I have a 3D matrix (70x51x8760) (longitude x latitude x time in hours) and I want the sum of each 24 (elements) hours. My new matrix will have this dimension (70x51x365).

any idea?

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In case you reach a situation where the third dimension isn't divisible by 24 then you can do this:

n = 24;
subs = ceil((1:size(A,3))/n)

for ii = 1:size(A, 1)
for jj = 1:size(A,2)

result(ii,jj,:) = accumarray(subs', squeeze(A(ii,jj,:)));

end
end
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reshape into the 4th dimension, sum into the 3rd, and squeeze:

B = squeeze( sum(reshape(A, size(A,1),size(A,2),24,[]), 3));
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or: reshape(A,size(A,1),size(A,2),[],24) for auto-determination f the third dimension. –  Jonas Jan 21 at 15:21
also I would use permute(.., [1 2 4 3]) instead of squeeze to get rid of the singleton dimension (IMO being explicit is better) –  Amro Jan 21 at 15:23
btw it should be reshape(A,size(A,1),size(A,2),24,[]) (and the same flip for Rody's version) –  Amro Jan 21 at 15:39
that code gave me a 70x51x24 matrix, not a 70x51x365... –  rochinha44 Jan 21 at 15:55
@rochinha44: yes, my mistake. See my latest edit. –  Rody Oldenhuis Jan 22 at 8:24

For what it's worth, here is the for-loop version:

A = rand(70,51,8760);  % sample data 3D matrix
n = 24;                % group every n-pages and sum across the 3rd dimension

% calculate starting indices
sz = size(A);
ind = 1:n:sz(3);

% compute the sums in each group of pages
B = zeros(sz(1),sz(2),numel(ind));
for k=1:numel(ind)
B(:,:,k) = sum(A(:,:,ind(k):ind(k)+n-1), 3);
end

The above assumes that size(A,3) is evenly divisible by n. Of course it could be adjusted if that's not the case by processing the first fix(size(A,3)/n)*n slices as before, then doing the remaining pages using one last iteration.

You could compare the above code against @RodyOldenhuis's solution:

B2 = permute(sum(reshape(A,sz(1),sz(2),n,[]),3), [1 2 4 3]);
assert(isequal(B,B2))

(In my tests, this was faster than the for-loop, but not by much)

I also managed to fully vectorize @Dan's solution into a single accumarray call:

[I,J,K] = ndgrid(1:sz(1),1:sz(2),1:sz(3));
B3 = accumarray([I(:) J(:) ceil(K(:)./n)], A(:));
assert(isequal(B,B3))

(Warning: this version is memory-intensive, not to mention much slower than the other solutions)

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