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[spec] Fluidity Boundary Conditions
kynan edited this page Feb 23, 2013
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https://code.launchpad.net/~grm08/fluidity/pyop2-bcs
- Fluidity mesh objects contain face objects
- which in turn contain a list of boundary_ids
- boundary_ids are (in FEniCS terms) a MeshFunction over facets, associating each facet with exactly one boundary ID.
- For interior facets and for exterior facets to which no other ID has been associated, this ID is 0
- (Boundary ID is always an integer)
- Now at Field level, there are boundary condition objects
- these associate a boundary condition with one or more boundary ids
- among other things, the boundary condition objects contain a list of the surface facets to which they apply.
- so that's your list of surface elements
- does that mean that the easiest thing is to associate any boundary condition with a boundary, then retrieve the list of surface elements through the mechanism you just described?
- since I imagine we want to be able to write in the "UFL" box in diamond something like: DirichletBC(mesh, bdry_id, condition)
- and not actually use the fluidity infrastructure for computing boundary conditions
- I think that's correct. And actually we can eventually unify the two by that route
- is there any danger that i'll end up overwriting some other boundary condition specified in the flml that the user wanted by inserting my own "dummy" BC?
- If we have a FEniCS-compatible way of doing it, then we could eventually call our routines driven by the flml to cause the fluidity interface.
- I think for the moment, the rule is that UFL equations do not honour flml boundary conditions so there is no conflict
- ah, that would be the "unified" case, and there would be no conflict
- The weak BCs way of doing this is described at: http://fenicsproject.org/documentation/dolfin/1.0.0/python/demo/pde/subdomains-poisson/python/documentation.html
- if i understand correctly, fluidity has already created boundaries and assigned them IDs based on the input mesh - is that right?
- however, that doesn't preclude us from supporting the fenics way of doing it, since we could always compute the subdomain specified anyway
-
mesh%faces%face_list
:face (i,j)
is the face in elementi
adjacent to elementj
. thei
-th row of that sparsity is the list of facets of that element in local facet number order.j
will be negative for a boundary facet, but you probably don't need to care about that. -
mesh%faces%face_element_list
gives you the element corresponding to a face. - You just need to map from the global face number to the element local facet id which you need to get by finding the index of that facet in the
i
th row of face list. - Given that this is the way that we will always do integrals over
ds
, it may be worth cacheing that lookup.
We need:
- An OP2 Set of elements for each boundary.
- A Dat on this set containing the local face number of the face that is on the boundary, which agrees with the UFC specification on facet numbering.
- A mapping from the local element numbers of each boundary element to the global node numbers.
To build the boundary data structures:
- First uniquify
mesh.faces.boundary_ids
to get a list of the boundaries we need to build. - Scan through the column indices for
face_list
. If an entry is negative, then that element/face is on the boundary. - For each element that is on the boundary, we add it to the correct boundary element set. The correct set is looked up by looking up
face_list[i,j]
wherei
is the element andj
is the negative index with the boundary, and using this to index into theboundary_ids
array. The mappings to the global node numbers are simply looked up throughndglno
for that element. The facet number is the index ofj
into thei
-th row offace_list
- this is add to the facet number dat.