Mercurial > repos > public > sbplib
view +multiblock/Grid.m @ 774:66eb4a2bbb72 feature/grids
Remove default scaling of the system.
The scaling doens't seem to help actual solutions. One example that fails in the flexural code.
With large timesteps the solutions seems to blow up. One particular example is profilePresentation
on the tdb_presentation_figures branch with k = 0.0005
| author | Jonatan Werpers <jonatan@werpers.com> |
|---|---|
| date | Wed, 18 Jul 2018 15:42:52 -0700 |
| parents | b0386d2c180d |
| children | a55d3c1e1f83 |
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classdef Grid < grid.Grid properties grids connections boundaryGroups nPoints end % General multiblock grid methods % grids -- cell array of N grids % connections -- NxN upper triangular cell matrix. connections{i,j} % specifies the connection between block i and j. If % it's empty there is no connection otherwise it's a 2 % -cell-vector with strings naming the boundaries to be % connected. (inverted coupling?) % boundaryGroups -- A struct of BoundaryGroups. The field names of the % struct are the names of each boundary group. % The boundary groups can be used to collect block % boundaries into physical boundaries to simplify % getting boundary operators and setting boundary conditions function obj = Grid(grids, connections, boundaryGroups) default_arg('boundaryGroups', struct()); assertType(grids, 'cell') obj.grids = grids; obj.connections = connections; obj.nPoints = 0; for i = 1:length(grids) obj.nPoints = obj.nPoints + grids{i}.N(); end obj.boundaryGroups = boundaryGroups; end function n = size(obj) n = length(obj.grids); end % N returns the number of points in the grid function o = N(obj) o = obj.nPoints; end % Ns returns the number of points in each sub grid as a vector function o = Ns(obj) ns = zeros(1,obj.nBlocks); for i = 1:obj.nBlocks ns(i) = obj.grids{i}.N(); end o = ns; end function n = nBlocks(obj) n = length(obj.grids); end % d returns the spatial dimension of the grid function o = D(obj) o = obj.grids{1}.D(); end % points returns a n x d matrix containing the coordinates for all points. function X = points(obj) X = sparse(0,obj.D()); for i = 1:length(obj.grids) X = [X; obj.grids{i}.points]; end end % Split a grid function on obj to a cell array of grid function on each block function gfs = splitFunc(obj, gf) nComponents = length(gf)/obj.nPoints; nBlocks = length(obj.grids); % Collect number of points in each block N = zeros(1,nBlocks); for i = 1:nBlocks N(i) = obj.grids{i}.N(); end gfs = blockmatrix.fromMatrix(gf, {N,1}); end % TODO: Split op? % Should the method to split an operator be moved here instead of being in multiblock.DiffOp? % Converts a gridfunction to a set of plot matrices % Takes a grid function and and a structured grid. function F = funcToPlotMatrices(obj, gf) % TODO: This method should problably not be here. % The funcToPlotMatrix uses .size poperty of the grids % Which doesn't always exist for all types of grids. % It's only valid for structured grids gfs = obj.splitFunc(gf); F = cell(1, obj.nBlocks()); for i = 1:obj.nBlocks() F{i} = grid.funcToPlotMatrix(obj.grids{i}, gfs{i}); end end % Restricts the grid function gf on obj to the subgrid g. function gf = restrictFunc(obj, gf, g) gfs = obj.splitFunc(gf); for i = 1:length(obj.grids) gfs{i} = obj.grids{i}.restrictFunc(gfs{i}, g.grids{i}); end gf = cell2mat(gfs); end % Projects the grid function gf on obj to the grid g. function o = projectFunc(obj, gf, g) error('not implemented') p = g.points(); o = zeros(length(p),1); for i = 1:length(p) I = whatGrid(p(i)); o(i) = obj.grids{I}.projectFunc(gf, p(i)); end function I = whatGrid(p) % Find what grid a point lies on end end % Find all non interface boundaries of all blocks. % Return their grid.boundaryIdentifiers in a cell array. function bs = getBoundaryNames(obj) bs = {}; for i = 1:obj.nBlocks() candidates = obj.grids{i}.getBoundaryNames(); for j = 1:obj.nBlocks() if ~isempty(obj.connections{i,j}) candidates = setdiff(candidates, obj.connections{i,j}{1}); end if ~isempty(obj.connections{j,i}) candidates = setdiff(candidates, obj.connections{j,i}{2}); end end for k = 1:length(candidates) bs{end+1} = {i, candidates{k}}; end end end % Return coordinates for the given boundary/boundaryGroup function b = getBoundary(obj, boundary) switch class(boundary) case 'cell' I = boundary{1}; name = boundary{2}; b = obj.grids{I}.getBoundary(name); case 'multiblock.BoundaryGroup' b = sparse(0,obj.D()); for i = 1:length(boundary) b = [b; obj.getBoundary(boundary{i})]; end otherwise error('Unknown boundary indentifier') end end end end