# MatLab algorithm for composite Simpson's rule

I have tried, just for the fun of it, to write a MatLab-code for the composite Simpson's rule. As far as I can see, the code is correct, but my answers are not as accurate as I would like. If I try my code on the function f = cos(x) + e^(x^2), with a = 0, b = 1 and n = 7, my answer is roughly 1,9, when it should be 2,3. If I use the algorithm available at Wikipedia, I get a very close approximation with n = 7, so my code is obviously not good enough. If someone can see any mistakes in my code, I would really appreciate it!

function x = compsimp(a,b,n,f)
% The function implements the composite Simpson's rule

h = (b-a)/n;
x = zeros(1,n+1);
x(1) = a;
x(n+1) = b;
p = 0;
q = 0;

% Define the x-vector
for i = 2:n
x(i) = a + (i-1)*h;
end

% Define the terms to be multiplied by 4
for i = 2:((n+1)/2)
p = p + (f(x(2*i -2)));
end

% Define the terms to be multiplied by 2
for i = 2:((n-1)/2)
q = q + (f(x(2*i -1)));
end

% Calculate final output
x = (h/3)*(f(a) + 2*q + 4*p + f(b));

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Your interval [a,b] should be split into n intervals. This results in n+1 values for x that form the boundary of each partition. Your vector x contains only n elements. It appears that your code is only dealing with n terms instead of n+1 as required.

EDIT:: Now you have modified the question based on the above, try this

% The 2 factor terms
for i = 2:(((n+1)/2) - 1 )
q = q + (f(x(2*i)));
end

% The 4 factor terms
for i = 2:((n+1)/2)
p = p + (f(x(2*i -1)));
end

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Thanks! I will look into this. The fact that MatLab does not begin indexing at x(0) will never, ever cease to annoy me! –  Kristian Oct 29 '12 at 21:31
@Kristian Yes it can make life confusing. It appears that at the very least you need to make x contain n+1 elements, also x(0) = a not f(a) according to the formula. Similarly x(n) = b not f(b) (using the zero based indexing!!) –  mathematician1975 Oct 29 '12 at 21:33
Thanks again. I have tried fixing my code based on your input, but my answers are still way off, I'm afraid. I'm pretty sure the indexing is throwing me off here, since I am basing my code on a pseudocode written for index-start at x(0). –  Kristian Oct 29 '12 at 21:42
@Kristian why not just partition the x into n intervals then use a loop over x to alternately add multiples of 2 and 4 of the function evaluated at the interior x points instead of calculating each sum separately. That might reduce some index confusion. Alternatively write out the simpsons formula using 1 based indices instead of zero based so that your code and formula indices match ?? –  mathematician1975 Oct 29 '12 at 21:45
@Kristian Does my updated answer help? I have tried recalculating the formula based on 1 based indexing according to the wiki formula –  mathematician1975 Oct 29 '12 at 21:53

The code you have created works just fine. The only problem I see is n. From my experience, try n>=10000 for any function.

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The error committed by the composite Simpson's rule is bounded (in absolute value) by \tfrac{h^4}{180}(b-a) \max_{\xi\in[a,b]} |f^{(4)}(\xi)|, where h is the "step length", given by h=(b-a)/n. –  jack Apr 28 at 19:18