# Vectorizing the creation of a matrix of successive powers

Let `x=1:100` and `N=1:10`. I would like to create a matrix `x^N` so that the `i`th column contains the entries `[1 i i^2 ... i^N]`.

I can easily do this using for loops. But is there a way to do this using vectorized code?

• +1 for getting the chance to see all these different approaches. Oct 13, 2010 at 21:38

I'd go for:

``````x = 1:100;
N = 1:10;
Solution = repmat(x,[length(N)+1 1]).^repmat(([0 N])',[1 length(x)]);
``````

Another solution (probably much more efficient):

``````Solution = [ones(size(x)); cumprod(repmat(x,[length(N) 1]),1)];
``````

Or even:

`````` Solution = bsxfun(@power,x,[0 N]');
``````

Hope this helps.

• +1 for bsxfun + function pointer + simple arguments. If you can express the rule compactly, chances are that combination will let you express it in MATLAB... Oct 13, 2010 at 13:43
• +1 for bsxfun() voodoo. @Adrien, I think there is a typo: N = 1:10; instead of N = 1:0; Oct 13, 2010 at 14:00
• bsxfun() is the nicest. Thanks. Oct 14, 2010 at 7:52

Sounds like a Vandermonde matrix. So use vander:

``````A = vander(1:100);
A = A(1:10, :);
``````
• The only problem is that VANDER creates square matrices, so you do quite a bit of extra work. Oct 13, 2010 at 16:11
• @gnovice: Not a very tricky problem to work around, see code above. Oct 13, 2010 at 16:12
• Actually, since the OP mentioned working with square matrices in a comment, this function looks like a good choice. The only change you'd have to make would be to rotate it using ROT90 so that column `i` contains powers of `i`: `A = rot90(vander(1:N));` Oct 14, 2010 at 15:23

Since your matrices aren't that big, the most straight-forward way to do this would be to use MESHGRID and the element-wise power operator `.^`:

``````[x,N] = meshgrid(1:100,0:10);
x = x.^N;
``````

This creates an 11-by-100 matrix where each column `i` contains `[i^0; i^1; i^2; ... i^10]`.

• nice meshgrid usage. My only problem with this method and the similar ones proposed here is that they do not use the i^th line to compute line i+1 at a low cost. The cumprod variant does it but there is some aesthetics missing. Oct 13, 2010 at 21:44
• @Adrien: For large matrices, you are right that it would probably be faster to compute values by successive multiplication by the base value. For relatively small matrices like the example here, it seems a reasonable trade-off to go with something easy to read and understand but slightly less efficient. ;) Oct 14, 2010 at 0:42
• I like this method... In my actual programming I'm create 10000 by 10000. So maybe I should use the more efficient approaches. Good to know this way though. Thank you! Oct 14, 2010 at 7:53
• @alext87: Those are very large matrices, and you're likely to run into memory problems. In fact, they're so big that when I create a matrix of that size, there's not enough memory left to even perform basic operations on it. For example, `clear all; V=ones(10000); V=V.';` gives me an out-of-memory error. In addition, there's pretty much no point in raising numbers to such large powers. Even just `2^1000` results in `1.0715e+301`, just shy of the maximum value for doubles. Oct 14, 2010 at 15:34
• @Adrien: Actually, the function VANDER which was suggested by Oli Charlesworth takes advantage of the efficient computation you mention. You can see the code by typing `type vander` in the MATLAB Command Window. Oct 14, 2010 at 15:39

Not sure if it really fits your question.

``````bsxfun(@power, cumsum(ones(100,10),2), cumsum(ones(100,10),1))
``````

EDIT: As pointed out by Adrien, my first attempt was not compliant with the OP question.

``````xn = 100;
N=10;
solution = [ones(1,xn); bsxfun(@power, cumsum(ones(N,xn),2), cumsum(ones(N,xn),1))];
``````
• The first line of the computex matrix should be one, in your case it is `1:100` Oct 13, 2010 at 10:20

Why not use an easy to understand for loop?

``````c = [1:10]'; %count to 100 for full scale problem
for i = 1:4; %loop to 10 for full scale problem
M(:,i) = c.^(i-1)
end
``````

It takes more thinking to understand the clever vectorized versions of this code that people have shown. Mine is more of a barbarian way of doing things, but anyone reading it will understand it.

I prefer easy to understand code.

(yes, I could have pre-allocated. Not worth the lowered clarity for small cases like this.)

• If you go for a loop, then you should fill the matrix line by line and not use the .^ operator. Instead fill the first line with ones and then create each new line by multiplying the previous one with `[1:100]`. You have then both readability and efficiency. Oct 13, 2010 at 21:49
• Adrien's suggestion yields a 12% speed increase. For the scale of problem being discussed here, it was imperceptible. I had to run this 100,000 times to get the whole thing to take 2.8 vs 2.5 seconds. To me, my version is simpler to read since there is no initiation step for M, but no accounting for taste! :) Oct 15, 2010 at 13:21