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I have an n-by-m matrix that I want to convert to a mn-by-m matrix, with each m-by-m block of the result containing the diagonal of each row.

For example, if the input is:

[1 2; 3 4; 5 6]

the output should be:

[1 0; 0 2; 3 0; 0 4; 5 0; 0 6]

Of course, I don't want to assemble the matrix step by step myself with a for loop.
Is there a vectorized and simple way to achieve this?

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up vote 4 down vote accepted

For a vectorized way to do this, create the linear indices of the diagonal elements into the resulting matrix, and assign directly.

%# create some input data
inArray = [10 11;12 13;14 15];

%# make the index array

idxArray = reshape(1:nr*nc,nc,nr)';
idxArray = bsxfun(@plus,idxArray,0:nr*nc:nr*nc^2-1);

%# create output
out = zeros(nr*nc,nc);
out(idxArray) = inArray(:);

out =

    10     0
     0    11
    12     0
     0    13
    14     0
     0    15
share|improve this answer
Can you explain what bsxfun does? – ja72 Jun 14 '12 at 14:47
@ja72: bsxfun automatically expands arrays so that you can e.g. add a n-by-1 array to a n-by-m array. The handle at the beginning (@plus in this case) tells which operation to perform. It's faster and much more convenient that using repmat. – Jonas Jun 14 '12 at 14:50
bsxfun rocks!!! – Shai Dec 12 '12 at 12:54

Here's a simple vectorized solution, assuming X is the input matrix:

Y = repmat(eye(size(X, 2)), size(X, 1), 1);
Y(find(Y)) = X;

Another alternative is to use sparse, and this can be written as a neat one-liner:

Y = full(sparse(1:numel(X), repmat(1:size(X, 2), 1, size(X, 1)), X'));
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+1: this must have been accepted solution; 2d step is another amazing application of Octave matrix indexes – topchef Jun 25 '12 at 1:39
This solution is preferable to using bsxfun because it doesn't require function passing so it can be better optimized in native code. Also, consider making Y sparse. – dspyz Mar 19 '13 at 18:58
@dspyz sparse is a good suggestion, thanks. I've added another solution :-) – Eitan T Mar 19 '13 at 19:17

The easiest way I see to do this is actually quite simple, using simple index referencing and the reshape function:

I = [1 2; 3 4; 5 6];
J(:,[1,4]) = I;
K = reshape(J',2,6)';

If you examine J, it looks like this:

J =
     1     0     0     2
     3     0     0     4
     5     0     0     6

Matrix K is just what wanted:

K =
     1     0
     0     2
     3     0
     0     4
     5     0
     0     6

As Eitan T has noted in the comments, the above is specific to the example, and doesn't cover the general solution. So below is the general solution, with m and n as described in the question.

J(:,1:(m+1):m^2) = I;

If you want to test it to see it working, just use


Note: if J already exists, this can cause problems. In this case, you need to also use

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-1: This triggers an error: "Subscripted assignment dimension mismatch.". Even if it would've worked, that's not even the correct output. – Eitan T Mar 18 '13 at 9:00
The dimension mismatch is due to a typo - I said J(:,1:4), but it was supposed to say J(:,[1,4]). I transcribed it incorrectly, is all. The error has been corrected, and it should work as expected. As for the output, if you pay attention, I was describing the matrix J, which is NOT the final output. K is the output, and it looks exactly like what litro requested... at least, it is on Octave. – Glen O Mar 18 '13 at 9:58
It works now, so I've removed the downvote. However note that it is not generic because it works only when I has two columns. – Eitan T Mar 18 '13 at 10:04
True, it's not generic, as I had written it. I'll add a more general solution, because it does generalise pretty well. – Glen O Mar 18 '13 at 10:07
Please do, otherwise your answer wouldn't be useful... – Eitan T Mar 18 '13 at 10:16

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