# MATLAB adding matrices with different dimensions [closed]

I'm having trouble adding two arrays with different sizes. When I explored a bit on this site it seemed like most questions involved vectors with different sizes, but not actual matrices with multiple dimensions in both rows and columns.

I know it "doesn't make sense" mathematically to add matrices with different dimensions. It's just a tool I'm using to make code work easier, but here goes the question:

``````A = magic(4);
B = magic(3);
C = A + B
``````

That is basically what I want to do. I just want to make B have zeros along the 4th row and 4th column, and then I could have the same dimensions and add them. But how do I do it? Thanks in advance =)

EDIT: Also, in particular I would like to add B to A in a way so the original 3x3 from A basically "moves over" 1 column but stays in the same row.

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## closed as off-topic by Eitan T, Mario, Jeremiah Willcock, Will Eddins, GravitonJul 17 '13 at 6:28

This question appears to be off-topic. The users who voted to close gave this specific reason:

• "Questions asking for code must demonstrate a minimal understanding of the problem being solved. Include attempted solutions, why they didn't work, and the expected results. See also: Stack Overflow question checklist" – Eitan T, Mario, Jeremiah Willcock, Will Eddins, Graviton
If this question can be reworded to fit the rules in the help center, please edit the question.

I'm not sure I understand your edit. Care to give an example? –  beaker Jul 15 '13 at 15:18

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@A S Ahh! Thank you that is the perfect thing =) –  spaderdabomb Jul 15 '13 at 13:01
@ASHmm...actually it's being a little difficult. The argument 'pre' for padarray almost does what I want, except I only one it to 'pre' in the column dimension and 'post' in the row dimension....I do not see a method to do that. –  spaderdabomb Jul 15 '13 at 13:08

Assuming `A` may be re-used destructively, you can also accomplish it with direct indexing into `A`. This saves a dependency (`padarray`) and reduces the memory complexity to `O(N)` (instead of `O(N²)` for `padarray` or manual padding):

``````idx = {1:size(B,1), 1:size(B,2)};
A(idx{:}) = A(idx{:}) + B;
``````

Or, for arbitrarily shaped matrices,

``````A(1:size(B,1),1:size(B,2),2) = B;
sum(A,3)
``````

but I advise you to be really careful with all this, and at most use it sparingly. The fact that it is not possible natively is actually a protection against creating bugs. The dimensions of a matrix have mathematical meaning; trying to automate resizing by one of the standard operations breaks the mathematical rules, which more often than not is a fertile breading ground for bugs.

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What if you don't want to modify matrix `A`? :) –  Eitan T Jul 15 '13 at 13:46
@EitanT: then just say `C = A` and index `C` :) –  Rody Oldenhuis Jul 15 '13 at 13:52
and what if `A` is smaller in size than `B`? (Just nitpickin'... :P ) –  Eitan T Jul 15 '13 at 14:12
@EitanT or `size(A,1) > size(B,1)` and `size(A,2) < size(B,2)` (Just sayin'... :P ) –  beaker Jul 15 '13 at 14:30
@EitanT: I must admit I saw your solution only after I posted the second edit to my answer, so I apologize if it seemed I tried to hijack your post. And you weren't irritating me, just...stimulating me to conjure up good counterarguments :p –  Rody Oldenhuis Jul 15 '13 at 14:55

Note that `padarray` requires the Image Processing Toolbox to be installed.

A native solution involving padding would look like this:

``````C = B;
C(end + 1:size(A, 1), end + 1:size(A, 1)) = 0;
C = C + A;
``````

This assumes that matrix `A` is larger in dimensions than `B`, but you can easily modify this code if not.

An alternative to padding is adding the matrix `B` to the appropriate elements in `A`. This can be accomplished in a lot of ways, for instance:

``````C = zeros(max(size(A), size(B)));  %// Preallocate matrix to accommodate result
C(1:size(A, 1), 1:size(A, 2)) = A;
C(1:size(B, 1), 1:size(B, 2)) = C(1:size(B, 1), 1:size(B, 2)) + B;
``````

This specific example computes the indices of the elements of `A` and `B` in the matrix `C`, and sums overlapping elements.

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