Note: This discussion is about an older version of the COMSOL Multiphysics® software. The information provided may be out of date.
Discussion Closed This discussion was created more than 6 months ago and has been closed. To start a new discussion with a link back to this one, click here.
Solving a 4th order PDE: how to specify boundary conditions
Posted 20 dic 2012, 22:06 GMT-5 Fluid & Heat, Studies & Solvers, Structural Mechanics Version 4.3a 4 Replies
Please login with a confirmed email address before reporting spam
∇^2 v = w
∇^2 w = 0
where v = v(x,y) and w = w(x,y).
Suppose that in the original problem, I had the two boundary conditions:
w = 1 on D1
dw/dn = 0 on D1
w = unknown constant on D2
dw/dn = 1 on D2
I am not sure how I translate to the system now in (v, w). In particular, the value of w on the boundary D2 is unknown, but it is known that D2 is constant.
From my reading, it seems that I have to use the notion of Lagrange multipliers. But there is very little documentation on this in Comsol's manuals. I would appreciate if someone could help.
Please login with a confirmed email address before reporting spam
I also have a 4th-order PDE to solve, and it's more complex than the one in your question. I've been struggling with that for some time. Hope we both can solve our problems.
Here's a few thoughts about your question:
One thing to note is that the knowledge of Dirichlet boundary condition on a boundary enables you to calculate the tangential derivative of the dependent variable. So on boundary D1, dw/dt=0 (as your Dirichlet BC has a constant value) and dw/dn=0 means dw/dx=dw/dy=0, then everything about v on D1 is zero. For D2, dw/dt=0 and dw/dn=1. From these two conditions, I guess you can find the conditions for v on D2.
What I'm not sure about is which of these conditions one should impose explicitly as some of them are obviously redundant.
Best
--
Pu, ZHANG ??
Departamento de Física Teórica de la Materia Condensada,
Universidad Autónoma de Madrid,
Madrid, Spain.
Please login with a confirmed email address before reporting spam
One thing to note is that the knowledge of Dirichlet boundary condition on a boundary enables you to calculate the tangential derivative of the dependent variable. So on boundary D1, dw/dt=0 (as your Dirichlet BC has a constant value) and dw/dn=0 means dw/dx=dw/dy=0, then everything about v on D1 is zero. For D2, dw/dt=0 and dw/dn=1. From these two conditions, I guess you can find the conditions for v on D2.
Hi,
Perhaps I'm being dense, but on D1, where w = 0 and dw/dn = 0 on the boundary, why does that necessarily imply that v = 0?
For example, take the function w(x,y) = x^3 y^2 along D1 defined by y = 0. Then both w = 0 and dw/dn = dw/dy = 0 on the boundary, but the laplacian of w (and thus v) is non-zero.
Do you know much about the Lagrangian multipliers option in Comsol? I see mu = [mu1, mu2] in the equation definition in the screenshot here: i.imgur.com/LCDpx.png, but where is this used and where is it defined? It does not appear in the Neumann/Flux condition.
Please login with a confirmed email address before reporting spam
When w=const on D1, you have dw/dt=0. Together with dw/dn=0, you know dw/dx=dw/dy=0. But I think we can't get more.
Best
--
Pu, ZHANG ??
Departamento de Física Teórica de la Materia Condensada,
Universidad Autónoma de Madrid,
Madrid, Spain.
Please login with a confirmed email address before reporting spam
www.comsol.com/support/knowledgebase/816/
worked for me