How to integrate PDE solution in 2D space?

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Andrew Ferguson
Andrew Ferguson el 15 de En. de 2020
Comentada: Andrew Ferguson el 16 de En. de 2020
I am solving a time dependent PDE using solvepde. I want to numerically integrate the solution (at the end time, tf) over a 2D space on a semicircle (Face 2) in the geometry. The geometry I'm using is:
R1 = [3;4;-0.01;0.01;0.01;-0.01;-0.01;-0.01;0;0];
R2 = [3;4;-0.01;0.01;0.01;-0.01;0;0;0.01;0.01];
C1 = [1;0;0;Rg];
C1 = [C1;zeros(length(R1) - length(C1),1)];
gm = [R1,R2,C1];
sf = '(R1+C1)-R2';
ns = char('R1','R2','C1')';
g = decsg(gm,sf,ns);
geometryFromEdges(model,g);
figure
pdegplot(model,'EdgeLabels','on','FaceLabels','on');
I've tried using the following to get me in the right direction, but haven't been able to make any progress.
xq = -0.01:0.001:0.01;
yq = -(0.007317./2).*ones(size(xq));
uintrp = interpolateSolution(result,xq,yq);
No matter how I try to set up xq and yq, I always get the following error:
Error using pde.PDEResults/validatePointsMatrix (line 3)
Query point matrix does not contain coordinates of 2-D space in required format.
Can anyone help me?

Respuesta aceptada

Ravi Kumar
Ravi Kumar el 16 de En. de 2020
If you are solving a single PDE, i.e., you used createpde(1) then you need to specify time-steps as the last argument. If you have a system of PDEs, then you need to also specify the component of solution:
uintrp = interpolateSolution(result,xq,yq,1:size(tlist));
where tlist is what you used in solvepde.
Regards,
Ravi
  3 comentarios
Ravi Kumar
Ravi Kumar el 16 de En. de 2020
I don't think asymmetry in tspan shouldn't matter. The interpolated solution grid could be coarser than the actual solution grid. Can you elaborate on what is the difference with images that compare them?
Regards,
Ravi
Andrew Ferguson
Andrew Ferguson el 16 de En. de 2020
So I am solving the diffusion equation and have a component diffusing outward from the center of the semicircle and into the rest of the rectanglular shape. The colormap using solvepde displays a result that is expected - the concentration of the component decreases radially outward and decreases at the center from its initial value of 0.22. However, when I plot the results from interpolate solution, it shows that a large portion in the center of the semicircle is at 0.22 (which is untrue) and that a portion inside the semicircle is actually above 0.22, which isn't possible either.

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