limit of the fourier transform in MATLAB

I try to check my formula, which I have derived from a solution of the Laplace equation using the Fourier Transform method. Here is my final deduced function:

``````Phi(x,y) = Sum (A * cos(Beta*xn) * sinh(Beta*yn))
``````

for (n rum from 0 to infinity) where

``````A = (2Vo)*[cos(Beta*a2n) - cos(Beta*a1n)]/[(Beta^2)*(a1n-a2n))*sinh(Beta*bn)]
``````

in which: `Beta = (2n+1)* (pi/2)`, `a1n`, `a2n` are constant over the x axis, which is normalised with `a3 - a` maximum limit dimension on x, and `bn` is the normalised value of `b` (maximum dimension on y axis) w.r.t `a3`. `xn`, `yn`: are also normalised values w.r.t. `a3`. Here my code in Matlab:

``````x = linspace (0,1.7,500);
y = linspace (0,1.2,500);
term = zeros(500);
Phi = zeros(500);
xn = x/1.7;
yn = y/1.7;
a1n = .9/1.7;
a2n = 1.2/1.7;
bn = 1.2/1.7;
Phi0 = 5;
[X,Y] = meshgrid(xn,yn);
for k = 0:100
Beta = (2*k+1)*(pi/2);
C1 = 2*Phi0*(cos(Beta*a2n)-cos(Beta*a1n))/((Beta^2)*(a1n-a2n)*sinh(Beta*bn));
term = C1.*cos(Beta.*X).*sinh(Beta.*Y);
Phi = Phi + term;
end
Output = Phi / Phi0;
mesh(X,Y,Output);
``````

This is just a simple test, so it looks somehow difficult for you. Here, on x direction, constant: `a3 = 1.7`, `a1 = 0.9`, `a2 = 1.2`; on y direction, constant: `b = 1.2`, `Phi = Vo = 5`;

Here is the plot in Matlab:

Correct result

Until this step, it is satisfied my requirement. Howerver, when I try to increase the order of the Fourier transform, in this case (`k = 0:500`), the result is quite weird:

weird result after increasing order of the Fourier Transform

As you can see, the graph changes in its shape and also both limits.

Actually, I do not know the result. I think that there should be no errors in my code, and it might related to some limitation of the program. Otherwise, could you please help me find out the reason?

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I find it extremely hard to understand what you are trying to do here, and what exactly the problem is. Part of the problem are your partially incomplete sentences and warped formatting – I tried to clean that up, please check whether it is still what you mean. –  A. Donda Jan 9 at 21:25
Why is the first result ok and the second weird, considering you don't know what the correct solution looks like? What you are computing there is not exactly the Fourier transform, but (I guess) you approximate a precise result given in the form of a Fourier series by a partial sum of the series terms. Since the true value is reached only in the limit, it is not surprising that different approximations look different – it depends on how quickly the series converges. –  A. Donda Jan 9 at 21:28
I strongly doubt that this is a problem with limitations of Matlab, and I'd recommend you double-check your derivations. If you need help with that, I'd suggest you ask on math.stackexchange.com, or maybe physics.stackexchange.com. –  A. Donda Jan 9 at 21:30
Hello A.Donda, sorry for late reply. No, there are no problems in my function. If you tried my code, you would see the weird difference when you increase the order of the Fourier Series. As you can see, my parameters are normalized to a3 = 1.7. In theory, when you increase the order (n), the graph "becomes" better approximation. For the normalized values, the graph should be be start form 0 to (1.2/1.7) = 0.7 (in the y-direction). However, you see, in the second picture, it starts from 0 to somewhere around 0.5 or 0.6, and the shape of the graph changes also. –  user3036972 Jan 14 at 21:49