# How to use MATLAB to numerically solve equation with unknown embedded in integral?

I've been trying to use MATLAB to solve equations like this:

B = alpha*Y0*sqrt(epsilon)/(pi*ln(b/a)*sqrt(epsilon_t))*integral from 0 to pi of (2*sinint(k0*sqrt(epsilon*(a^2+b^2-2abcos(theta))-sinint(2*k0*sqrt(epsilon)*a*sin(theta/2))-sinint(2*k0*sqrt(epsilon)*b*sin(theta/2))) with regard to theta

Where epsilon is the unknown.

I know how to symbolically solve equations with unknown embedded in an integral by using `int()` and `solve()`, but using the symbolic integrator `int()` takes too long for equations this complicated. When I try to use `quad()`, `quadl()` and `quadgk()`, I have trouble dealing with how the unknown is embedded in the integral.

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Are all of the other constants defined above? (i.e. alpha, Y0, etc.) –  Sticky073 Dec 5 '12 at 21:59
Those constants are just arbitrary constants for the purposes of calculation, only epsilon is the unknown. theta is just the integration variable (like dx,dy,dz, etc) –  user1880273 Dec 5 '12 at 22:19

This sort of thing gets complicated real fast. Although it is possible to do it all in a single inline equation, I would advise you to split it up into multiple nested functions, if only for readability.

The best example of why readability is important: you have a bracketing problem in the eqution you posted; there's not enough closing brackets, so I can't be entirely sure what the equation looks like in mathematical notation :)

Anyway, here's one way to do it with the version I --think-- you meant:

``````function test

% some random values for testing

Y0 = rand;
b  = rand;
a  = rand;
k0 = rand;
alpha     = rand;
epsilon_t = rand;

D = -0.015;

% define SIMPLE anonymous function
Bb = @(ep) F(ep).*main_integral(ep) - D;

% aaaand...solve it!
sol = fsolve(Bb, 1)

% The anonymous function above is only simple, because of these:

% the main integral
function val = main_integral(epsilon)

% we need for loop through epsilon, due to how quad(gk) solves things
val = zeros(size(epsilon));
for ii = 1:numel(epsilon)

ep = epsilon(ii);

% NOTE how the sinint's all have a different function as argument:
2*sinint(A(ep,th)) - sinint(B(ep,th)) - sinint(C(ep,th)), ...
0, pi);
end

end

% factor in front of integral
function f = F(epsilon)
f = alpha*Y0*sqrt(epsilon)./(pi*log(b/a)*sqrt(epsilon_t)); end

% first sinint argument
function val = A(epsilon, theta)
val = k0*sqrt(epsilon*(a^2+b^2-2*a*b*cos(theta))); end

% second sinint argument
function val = B(epsilon, theta)
val = 2*k0*sqrt(epsilon)*a*sin(theta/2); end

% third sinint argument
function val = C(epsilon, theta)
val = 2*k0*sqrt(epsilon)*b*sin(theta/2); end

end
``````

The solution above will still be quite slow, but I think that's pretty normal for integrals this complicated.

I don't think implementing your own `sinint` will help much, as most of the speed loss is due to the for loops with non-builtin functions...If it's speed you want, I'd go for a MEX implementation with your own Gauss-Kronrod adaptive quadrature routine.

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