This question already has an answer here:

I'm trying to use the function integral to return an array of integrated points

I have a function defined:

v = @(t) cos(t);

and I'd like to find the integrated function, x(t) for several such values stored in tvec:

tvec = linspace(0,10,1000);    
x = @(tf) integral(@(t) v(t),0,tf,'ArrayValued',true);

But it doesn't appear that Matlab allows the array valued bit to be the limit of integration, since x(tvec) results in error. Any suggestions?

marked as duplicate by Andras Deak, TroyHaskin, Adriaan, Daniel matlab Feb 10 '16 at 11:59

This question has been asked before and already has an answer. If those answers do not fully address your question, please ask a new question.


Note: there is a duplicate question with a much more efficient solution than this one.

The problem is that integral only accepts scalar limits. In your example the integrand is scalar-valued, so you should omit the 'ArrayValued' setting: that will allow MATLAB to vectorize the integration for each upper bound.

You can use arrayfun to feed each upper limit to integrate. Also, you can just pass v, a function handle to integral, no need to redefine an anonymous function for it locally:

v = @(t) cos(t);
x = @(tf) arrayfun(@(tmax) integral(v,0,tmax),tf);

tvec = linspace(0,10,1000);    
sinvec = x(tvec);

It seems to work:



  • 2
    My way's faster. ;) – TroyHaskin Feb 10 '16 at 0:05
  • @Troy no doubt:D Think we should vote for dupe? Either that, or you should add a similar answer here. – Andras Deak Feb 10 '16 at 0:13
  • I was thinking about that when I saw your answer. The question is different, but the desired result is the same ... Is that a dupe or is there merit in both questions (i.e., I think this question is better posed than the one I linked to)? – TroyHaskin Feb 10 '16 at 0:18
  • Yes, this question is more self-contained, but the other one starts with "I am trying to integrate the sine-function. My goal is to get not just the value of the area inbetween a certain distance but the specific values of the integrated course.". That's exactly what our OP wants, only with cos. So I think it could be a valid dupe, and your solution should be much faster for larger problems. The latter makes me say that either we should vote for dupe (in which case readers get redirected to your answer), or you should add a specific answer here. – Andras Deak Feb 10 '16 at 0:26
  • 1
    @TroyHaskin I was initially concerned that Troy's solution (in dupe question) would accumulate error at the boundaries of several small integrals. I confirmed these solutions are the same to within floating point precision (and that Troy's is much faster!) for several dX increment sizes. – anon01 Feb 10 '16 at 17:54

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