I am working on a problem where I want to use ode45 on the KS equation 
. To do so, I am employing the method of lines by semidiscretising the equation in the spacial dimension. The code has periodic boundary conditions, However, I am running into problems when trying to test the finite difference expressions for the second and fourth order derivatives. My code for the derivatives are as follows (using central difference approximation):
u_xx = ( u(wrapN(i+1,N)) - 2*u(i) + u(wrapN(i-1,N)) ) / (h^2);
u_xxxx = ( u(wrapN(i+2,N)) - 4*u(wrapN(i+1,N)) + 6*u(i) - 4*u(wrapN(i-1,N)) + u(wrapN(i-2,N))) / (h^4);
where wrapN is a helper function to help wrap the indices at the boundaries of u to the start/end of the input matrix (and returns the wrapped value fine):
wrapN = @(x, n) (1 + mod(x-1, n));
and N is simply defined as the length of the input array.
However, when I create a test case using a simple cosine function, I get inaccurate results. When I use the input:
x = -pi:0.01:(pi-0.01);
u = cos(x);
Calculating u_xx centered at i=1 gives 1.3692, rather than 1 as expected.
Calculating u_xxxx at i=1 gives an even more incorrect value, -7.8937e+03, and additionally u_xxxx at i=N gives 4.7062e+03 rather than a similar value as expected for a periodic function.
The expressions are otherwise well behaved for values outside those used by the boundary calculations
