Finite Difference Approximation of 1st Order Error Bi-Harmonic Operator

7 Ansichten (letzte 30 Tage)
Hello,
I am working on a summer project at my university which involves simulating a pair of reaction-diffusion equations. I have chosen to approximate the differentials with the finite difference method. I have successfully applied the method to the laplacian operator (shown below), however, I appear to be having issue with the bi-harmonic operator (shown below).
Laplacian_2D_1stOrder
function out = Laplacian2D(in, res)
h = res;
k = res;
f_xx = (circshift(in,[ 0, 1]) - 2 .* circshift(in,[ 0, 0]) + circshift(in,[ 0, -1])).*h;
f_yy = (circshift(in,[ 1, 0]) - 2 .* circshift(in,[ 0, 0]) + circshift(in,[ -1, 0])).*k;
out = f_xx + f_yy;
end
BiHarmonic_2D_1stOrder
function out = Biharmonic2D(in, res)
h = res;
k = res;
f_xxxx = (circshift(in,[ 0, -2]) - 4.*circshift(in,[ 0, -1]) + 6.*circshift(in,[ 0, 0]) - 4.*circshift(in,[ 0, 1]) + circshift(in,[ 0, 2])).*res;
f_yyyy = (circshift(in,[ -2, 0]) - 4.*circshift(in,[ -1, 0]) + 6.*circshift(in,[ 0, 0]) - 4.*circshift(in,[ 1, 0]) + circshift(in,[ 2, 0])).*res;
f_xxyy = (circshift(in,[ -1, -1]) - 2.*circshift(in,[ 0, -1]) + circshift(in,[ 1, -1]) - 2.*circshift(in,[ -1, 0]) + 4.*circshift(in,[ 0, 0]) - 2.*circshift(in,[ 1, 0]) + circshift(in,[ -1, 1]) - 2.*circshift(in,[ 0, 1]) + circshift(in,[ 1, 1])).*res;
out = f_xxxx + f_xxyy + f_xxyy + f_yyyy;
end
Quoting from Wikipedia:
In mathematics, finite-difference methods (FDM) are numerical methods for solving differential equations by approximating them with difference equations, in which finite differences approximate the derivatives. FDMs are thus discretization methods.
I derived the approximations by following the work of David Eberly "Derivative Approximation by Finite Difference" Link: http://read.pudn.com/downloads203/sourcecode/game/955182/3D%20Geometry%20Tuts/FiniteDifferences.pdf
The x and y resolutions are the same. I found that different resolutions led to spatial stretching. (I think this is obvious but would be happy to learn if there is a reason why or a situation where one would have different x and y spatial resolutions?)
When I call my functions, they appear to work, but the Laplacian appears far better behaved than the bi-harmonic operator. I tested both on the MATLAB Peaks function and compared them to MATHEMATICA's built in laplacian and hiharmonic operator functions and they returned the same results (roughly, I assume the difference is between my approximation and MATHEMATICA's more accurate differentiation).
My questions to the community are:
  1. Have I implemented these correctly, specifically the resolutions, but also the addition at the end of the functions to return the overall approximation?
  2. Is there a more efficient way to implement them within MATLAB? I know that MATLAB has a laplacian operator but I was unable to find a Bi-Harmonic function, hence deriving it myself.
  3. When applying these to PDEs, is the error order acceptable? The PDEs will be applied to a pair of Cahn-Hilliard equations:
Should they therefore be of a higher order for a stability or a convergence reason?
Thank you for your assisstance. Regards, Matthew

Antworten (1)

Elizabeth Reese
Elizabeth Reese am 6 Sep. 2017
I believe you have these implemented correctly and that both have second-order accuracy. I am not sure how you are defining res, but make sure that there is a correct translation from resolution (generally points/distance) to grid spacing ( h = distance between points). Then, the Laplacian should be over h^2 and the biharmonic should be over h^4.
As far as efficiency, you can still use the built-in del2 function to compute the discrete Laplacian in MATLAB. You can apply it twice to your data to get the BiHarmonic.
As far as the x and y resolutions are concerned, this will depend on the mesh that you are working with but they will be the same if you have a uniform mesh.
If you are interested in improving the accuracy, I recommend taking a look at the following page and just expanding your finite differences to include more points.

Kategorien

Mehr zu Computational Fluid Dynamics (CFD) finden Sie in Help Center und File Exchange

Community Treasure Hunt

Find the treasures in MATLAB Central and discover how the community can help you!

Start Hunting!

Translated by