function [x,y]=cirsg(bs,s) %CIRSG Gives geometry data for the cirsg PDE model % % NE=CIRSG gives the number of boundary segment % % D=CIRSG(BS) gives a matrix with one column for each boundary segment % specified in BS. % Row 1 contains the start parameter value. % Row 2 contains the end parameter value. % Row 3 contains the number of the left hand region. % Row 4 contains the number of the right hand region. % % [X,Y]=CIRSG(BS,S) gives coordinates of boundary points. BS specifies the % boundary segments and S the corresponding parameter values. BS may be % a scalar. % Copyright 1994-2003 The MathWorks, Inc. % $Revision: 1.8.4.1 $ nbs=5; if nargin==0, x=nbs; % number of boundary segments return end d=[ 0 0 0 0 0 % start parameter value 1 1 1 1 1 % end parameter value 1 1 1 1 1 % left hand region 0 0 0 0 0 % right hand region ]; bs1=bs(:)'; if find(bs1<1 | bs1>nbs), error('PDE:cirsg:InvalidBs', 'Non existent boundary segment number.') end if nargin==1, x=d(:,bs1); return end x=zeros(size(s)); y=zeros(size(s)); [m,n]=size(bs); if m==1 && n==1, bs=bs*ones(size(s)); % expand bs elseif m~=size(s,1) || n~=size(s,2), error('PDE:cirsg:SizeBs', 'bs must be scalar or of same size as s.'); end if ~isempty(s), % boundary segment 1 ii=find(bs==1); if length(ii) x(ii)=interp1([d(1,1),d(2,1)],[-0.70710678118654757 0],s(ii)); y(ii)=interp1([d(1,1),d(2,1)],[0.70710678118654757 0],s(ii)); end % boundary segment 2 ii=find(bs==2); if length(ii) x(ii)=interp1([d(1,2),d(2,2)],[0 -0.70710678118654757],s(ii)); y(ii)=interp1([d(1,2),d(2,2)],[0 -0.70710678118654757],s(ii)); end % boundary segment 3 ii=find(bs==3); if length(ii) x(ii)=1*cos(1.5707963267948966*s(ii)+(-2.3561944901923448))+(0); y(ii)=1*sin(1.5707963267948966*s(ii)+(-2.3561944901923448))+(0); end % boundary segment 4 ii=find(bs==4); if length(ii) x(ii)=1*cos(1.5707963267948966*s(ii)+(-0.78539816339744828))+(0); y(ii)=1*sin(1.5707963267948966*s(ii)+(-0.78539816339744828))+(0); end % boundary segment 5 ii=find(bs==5); if length(ii) x(ii)=1*cos(1.5707963267948966*s(ii)+(0.78539816339744828))+(0); y(ii)=1*sin(1.5707963267948966*s(ii)+(0.78539816339744828))+(0); end end