phd-scripts/Unpublished/XFEM/1D_Solver/GetF2D_T.m

function [] = GetF2D_T()
clear all
% Define Main Solution Mesh
NumX=2;
NumY=1;
delX=1.;
delY=1.;
for j=1:NumY+1
   for i=1:NumX+1
       index=i+(NumX+1)*(j-1);
       Node(index,1)=single((i-1.))*delX;
       Node(index,2)=single((j-1.))*delY;
   end
end
numNodes=(NumX+1)*(NumY+1);
for j=1:NumY
    for i=1:NumX
        index=i+NumX*(j-1);
        Element(index,1)=i+(NumX+1)*(j-1);
        Element(index,2)=i+(NumX+1)*(j-1)+1;
        Element(index,3)=i+(NumX+1)*(j)+1;
        Element(index,4)=i+(NumX+1)*(j);
    end
end
numElem=(NumX)*(NumY);
% Define Initial Level Set
%centx=5.;
%centy=5.;
%rad=2.5;
%for i=1:numNodes;
%    dist=sqrt((Node(i,1)-centx)*(Node(i,1)-centx)+(Node(i,2)-centy)*(Node(i,2)-centy));
%    lSet(i)=dist-rad;
%end
for i=1:numNodes;
    dist=Node(i,1)-1.5;
    lSet(i)=dist;
end
% Plot initial level set
%[X]=meshgrid(0:1.:10);
%Z=zeros(11);
%for i=1:numNodes
%    Z(i)=lSet(i);
%end
%surf(X,Z)
% LS Algorithm Parameters
bandwidth=10.;
% Loop through timesteps
for tstep=1:1
    % Identify Narrow Band Elements
    NBindex=0;
    for i=1:numElem
        check=0;
        for iNd=1:4
            if abs(lSet(Element(i,iNd)))<=bandwidth*delX
                check=1;
            end
        end
        % If an element is in the narrow band split it into triangles
        if check==1
            NBindex=NBindex+1;
            NBelem(NBindex,1)=Element(i,1);
            NBelem(NBindex,2)=Element(i,2);
            NBelem(NBindex,3)=Element(i,3);
            NBindex=NBindex+1;
            NBelem(NBindex,1)=Element(i,1);
            NBelem(NBindex,2)=Element(i,3);
            NBelem(NBindex,3)=Element(i,4);  
        end
    end 
    % Velocity BC
    F=zeros(numNodes,1);
    for i=1:NBindex  
        if sign(lSet(NBelem(i,1)))~=sign(lSet(NBelem(i,2)))||sign(lSet(NBelem(i,1)))~=sign(lSet(NBelem(i,3)))
            F(NBelem(i,1))= 0.05;
            F(NBelem(i,2))= 0.05;
            F(NBelem(i,3))= 0.05;
        end
    end
    % Assemble 'Stiffness' Matrices
    A=zeros(numNodes);
    for i=1:NBindex           
        gx(1)=2./3.;
        gx(2)=1./6.;
        gx(3)=1./6.;
        hx(1)=1./6.;
        hx(2)=1./6.;
        hx(3)=2./3.;
        AfL=zeros(3);
        AfLGLS=zeros(3);
        x1=Node(NBelem(i,1),1);
        y1=Node(NBelem(i,1),2);
        x2=Node(NBelem(i,2),1);
        y2=Node(NBelem(i,2),2);
        x3=Node(NBelem(i,3),1);
        y3=Node(NBelem(i,3),2);
        for j=1:3
            g=gx(j);
            h=hx(j);            
            phi(1)=1.-g-h;
            phi(2)=g;
            phi(3)=h;
 			phig(1)=-1.;
			phig(2)=1.;
			phig(3)=0.;    
  			phih(1)=-1.;
			phih(2)=0.;
			phih(3)=1.;             
            djac=2*abs(x1*(y2-y3)+x2*(y3-y1)+x3*(y1-y2));
            for k=1:3
                phix(k)=(1./djac)*((-y1+y3)*phig(k)+(y1-y2)*phih(k));
                phiy(k)=(1./djac)*((x1-x3)*phig(k)+(-x1+x2)*phih(k));
            end
            delphi=[phix;phiy];
            nodalLset=[lSet(NBelem(i,1));lSet(NBelem(i,2));lSet(NBelem(i,3))];
            set=phi*nodalLset;
            delset=delphi*nodalLset;
            AfL=AfL+(phi'*sign(set))*(delset'*delphi)/3.;
            AfLGLS=AfLGLS+(delphi'*delset)*(1./norm(delset))*(delset'*delphi)/3.;        
        end
        sum=AfL+AfLGLS;
        for k=1:3;
            for j=1:3;
               A(NBelem(i,j),NBelem(i,k))=A(NBelem(i,j),NBelem(i,k))+sum(j,k);
            end
        end
    end
    % Apply BCs
    RHS=zeros(numNodes,1);
    Sub=A*F;
    iindex=0;
    for i=1:numNodes
        if F(i)==0.
            iindex=iindex+1;
            RHSred(iindex)=RHS(i)-Sub(i);
            Fred=0.;
            jindex=0;
            for j=1:numNodes
                if F(j)==0.
                    jindex=jindex+1;
                    Ared(iindex,jindex)=A(i,j);
                end
            end
        end
    end
    % Solve for Fred
    Fred=(Ared^-1)*RHSred';
    % Get F
    iindex=0;
    for i=1:numNodes
        if F(i)==0.
            iindex=iindex+1;
            F(i)=Fred(iindex);
        end
    end
    % Update level set
    mMat=zeros(numNodes);
    mMatGLS=zeros(numNodes);
    f1=zeros(numNodes,1);
    f2=zeros(numNodes,1);
    f3=zeros(numNodes,1);
    h=1.;
    visc=0.0005;
    for i=1:NBindex 
        mMatL=zeros(3);
        mMatGLSL=zeros(3);
        f1L=zeros(3,1);
        f2L=zeros(3,1);
        f3L=zeros(3,1);
        gx(1)=2./3.;
        gx(2)=1./6.;
        gx(3)=1./6.;
        hx(1)=1./6.;
        hx(2)=1./6.;
        hx(3)=2./3.;
        x1=Node(NBelem(i,1),1);
        y1=Node(NBelem(i,1),2);
        x2=Node(NBelem(i,2),1);
        y2=Node(NBelem(i,2),2);
        x3=Node(NBelem(i,3),1);
        y3=Node(NBelem(i,3),2);
        for j=1:3
            g=gx(j);
            h=hx(j);            
            phi(1)=1.-g-h;
            phi(2)=g;
            phi(3)=h;
 			phig(1)=-1.;
			phig(2)=1.;
			phig(3)=0.;    
  			phih(1)=-1.;
			phih(2)=0.;
			phih(3)=1.;             
            djac=abs(x1*(y2-y3)+x2*(y3-y1)+x3*(y1-y2));
            for k=1:3
                phix(k)=(1./djac)*((-y1+y3)*phig(k)+(y1-y2)*phih(k));
                phiy(k)=(1./djac)*((x1-x3)*phig(k)+(-x1+x2)*phih(k));
            end 
            delphi=[phix;phiy];
            nodalLset=[lSet(NBelem(i,1));lSet(NBelem(i,2));lSet(NBelem(i,3))];
            nodalF=[F(NBelem(i,1));F(NBelem(i,2));F(NBelem(i,3))];
            delset=delphi*nodalLset;                              
            Floc=phi*nodalF;
            mMatL=mMatL+(phi'*phi)/3.;
            mMatGLSL=mMatGLSL+((delphi'*(delset/norm(delset)))*Floc*(h/abs(Floc)))*phi/3.;
            f1L=f1L+phi'*Floc*norm(delset)/3.;
            f2L=f2L+(delphi'*(delset/norm(delset))*Floc)*(h/abs(Floc))*Floc*norm(delset)/3.;
            vs=h*((abs(visc+Floc*norm(delset)))/(norm(Floc*delset)+h));
            f3L=f3L+vs*delphi'*delset/3.;
        end
        for k=1:3;
            for j=1:3;
               mMat(NBelem(i,j),NBelem(i,k))=mMat(NBelem(i,j),NBelem(i,k))+mMatL(j,k);
               mMatGLS(NBelem(i,j),NBelem(i,k))=mMatGLS(NBelem(i,j),NBelem(i,k))+mMatGLSL(j,k);           
            end
            f1(NBelem(i,k))=f1(NBelem(i,k))+f1L(k);
            f2(NBelem(i,k))=f2(NBelem(i,k))+f2L(k);
            f3(NBelem(i,k))=f3(NBelem(i,k))+f3L(k);       
        end
    end
    mMat
    mMatGLS
    (mMat+mMatGLS)^-1
    f1+f2+f3
    dt=0.1;
    -((((mMat+mMatGLS)^-1)*dt)*(f1+f2+f3))'
    lSet=lSet-((((mMat+mMatGLS)^-1)*dt)*(f1+f2+f3))';
end
lSet';
%scatter3(Node(:,1), Node(:,2), lSet');
Add scripts and inp files. 2024-05-13 19:50:21 +00:00			`function [] = GetF2D_T()`
			`clear all`
			`% Define Main Solution Mesh`
			`NumX=2;`
			`NumY=1;`
			`delX=1.;`
			`delY=1.;`
			`for j=1:NumY+1`
			`for i=1:NumX+1`
			`index=i+(NumX+1)*(j-1);`
			`Node(index,1)=single((i-1.))*delX;`
			`Node(index,2)=single((j-1.))*delY;`
			`end`
			`end`
			`numNodes=(NumX+1)*(NumY+1);`
			`for j=1:NumY`
			`for i=1:NumX`
			`index=i+NumX*(j-1);`
			`Element(index,1)=i+(NumX+1)*(j-1);`
			`Element(index,2)=i+(NumX+1)*(j-1)+1;`
			`Element(index,3)=i+(NumX+1)*(j)+1;`
			`Element(index,4)=i+(NumX+1)*(j);`
			`end`
			`end`
			`numElem=(NumX)*(NumY);`
			`% Define Initial Level Set`
			`%centx=5.;`
			`%centy=5.;`
			`%rad=2.5;`
			`%for i=1:numNodes;`
			`% dist=sqrt((Node(i,1)-centx)(Node(i,1)-centx)+(Node(i,2)-centy)(Node(i,2)-centy));`
			`% lSet(i)=dist-rad;`
			`%end`
			`for i=1:numNodes;`
			`dist=Node(i,1)-1.5;`
			`lSet(i)=dist;`
			`end`
			`% Plot initial level set`
			`%[X]=meshgrid(0:1.:10);`
			`%Z=zeros(11);`
			`%for i=1:numNodes`
			`% Z(i)=lSet(i);`
			`%end`
			`%surf(X,Z)`
			`% LS Algorithm Parameters`
			`bandwidth=10.;`
			`% Loop through timesteps`
			`for tstep=1:1`
			`% Identify Narrow Band Elements`
			`NBindex=0;`
			`for i=1:numElem`
			`check=0;`
			`for iNd=1:4`
			`if abs(lSet(Element(i,iNd)))<=bandwidth*delX`
			`check=1;`
			`end`
			`end`
			`% If an element is in the narrow band split it into triangles`
			`if check==1`
			`NBindex=NBindex+1;`
			`NBelem(NBindex,1)=Element(i,1);`
			`NBelem(NBindex,2)=Element(i,2);`
			`NBelem(NBindex,3)=Element(i,3);`
			`NBindex=NBindex+1;`
			`NBelem(NBindex,1)=Element(i,1);`
			`NBelem(NBindex,2)=Element(i,3);`
			`NBelem(NBindex,3)=Element(i,4);`
			`end`
			`end`
			`% Velocity BC`
			`F=zeros(numNodes,1);`
			`for i=1:NBindex`
			`if sign(lSet(NBelem(i,1)))~=sign(lSet(NBelem(i,2)))\|\|sign(lSet(NBelem(i,1)))~=sign(lSet(NBelem(i,3)))`
			`F(NBelem(i,1))= 0.05;`
			`F(NBelem(i,2))= 0.05;`
			`F(NBelem(i,3))= 0.05;`
			`end`
			`end`
			`% Assemble 'Stiffness' Matrices`
			`A=zeros(numNodes);`
			`for i=1:NBindex`
			`gx(1)=2./3.;`
			`gx(2)=1./6.;`
			`gx(3)=1./6.;`
			`hx(1)=1./6.;`
			`hx(2)=1./6.;`
			`hx(3)=2./3.;`
			`AfL=zeros(3);`
			`AfLGLS=zeros(3);`
			`x1=Node(NBelem(i,1),1);`
			`y1=Node(NBelem(i,1),2);`
			`x2=Node(NBelem(i,2),1);`
			`y2=Node(NBelem(i,2),2);`
			`x3=Node(NBelem(i,3),1);`
			`y3=Node(NBelem(i,3),2);`
			`for j=1:3`
			`g=gx(j);`
			`h=hx(j);`
			`phi(1)=1.-g-h;`
			`phi(2)=g;`
			`phi(3)=h;`
			`phig(1)=-1.;`
			`phig(2)=1.;`
			`phig(3)=0.;`
			`phih(1)=-1.;`
			`phih(2)=0.;`
			`phih(3)=1.;`
			`djac=2abs(x1(y2-y3)+x2(y3-y1)+x3(y1-y2));`
			`for k=1:3`
			`phix(k)=(1./djac)((-y1+y3)phig(k)+(y1-y2)*phih(k));`
			`phiy(k)=(1./djac)((x1-x3)phig(k)+(-x1+x2)*phih(k));`
			`end`
			`delphi=[phix;phiy];`
			`nodalLset=[lSet(NBelem(i,1));lSet(NBelem(i,2));lSet(NBelem(i,3))];`
			`set=phi*nodalLset;`
			`delset=delphi*nodalLset;`
			`AfL=AfL+(phi'sign(set))(delset'*delphi)/3.;`
			`AfLGLS=AfLGLS+(delphi'delset)(1./norm(delset))(delset'delphi)/3.;`
			`end`
			`sum=AfL+AfLGLS;`
			`for k=1:3;`
			`for j=1:3;`
			`A(NBelem(i,j),NBelem(i,k))=A(NBelem(i,j),NBelem(i,k))+sum(j,k);`
			`end`
			`end`
			`end`
			`% Apply BCs`
			`RHS=zeros(numNodes,1);`
			`Sub=A*F;`
			`iindex=0;`
			`for i=1:numNodes`
			`if F(i)==0.`
			`iindex=iindex+1;`
			`RHSred(iindex)=RHS(i)-Sub(i);`
			`Fred=0.;`
			`jindex=0;`
			`for j=1:numNodes`
			`if F(j)==0.`
			`jindex=jindex+1;`
			`Ared(iindex,jindex)=A(i,j);`
			`end`
			`end`
			`end`
			`end`
			`% Solve for Fred`
			`Fred=(Ared^-1)*RHSred';`
			`% Get F`
			`iindex=0;`
			`for i=1:numNodes`
			`if F(i)==0.`
			`iindex=iindex+1;`
			`F(i)=Fred(iindex);`
			`end`
			`end`
			`% Update level set`
			`mMat=zeros(numNodes);`
			`mMatGLS=zeros(numNodes);`
			`f1=zeros(numNodes,1);`
			`f2=zeros(numNodes,1);`
			`f3=zeros(numNodes,1);`
			`h=1.;`
			`visc=0.0005;`
			`for i=1:NBindex`
			`mMatL=zeros(3);`
			`mMatGLSL=zeros(3);`
			`f1L=zeros(3,1);`
			`f2L=zeros(3,1);`
			`f3L=zeros(3,1);`
			`gx(1)=2./3.;`
			`gx(2)=1./6.;`
			`gx(3)=1./6.;`
			`hx(1)=1./6.;`
			`hx(2)=1./6.;`
			`hx(3)=2./3.;`
			`x1=Node(NBelem(i,1),1);`
			`y1=Node(NBelem(i,1),2);`
			`x2=Node(NBelem(i,2),1);`
			`y2=Node(NBelem(i,2),2);`
			`x3=Node(NBelem(i,3),1);`
			`y3=Node(NBelem(i,3),2);`
			`for j=1:3`
			`g=gx(j);`
			`h=hx(j);`
			`phi(1)=1.-g-h;`
			`phi(2)=g;`
			`phi(3)=h;`
			`phig(1)=-1.;`
			`phig(2)=1.;`
			`phig(3)=0.;`
			`phih(1)=-1.;`
			`phih(2)=0.;`
			`phih(3)=1.;`
			`djac=abs(x1(y2-y3)+x2(y3-y1)+x3*(y1-y2));`
			`for k=1:3`
			`phix(k)=(1./djac)((-y1+y3)phig(k)+(y1-y2)*phih(k));`
			`phiy(k)=(1./djac)((x1-x3)phig(k)+(-x1+x2)*phih(k));`
			`end`
			`delphi=[phix;phiy];`
			`nodalLset=[lSet(NBelem(i,1));lSet(NBelem(i,2));lSet(NBelem(i,3))];`
			`nodalF=[F(NBelem(i,1));F(NBelem(i,2));F(NBelem(i,3))];`
			`delset=delphi*nodalLset;`
			`Floc=phi*nodalF;`
			`mMatL=mMatL+(phi'*phi)/3.;`
			`mMatGLSL=mMatGLSL+((delphi'(delset/norm(delset)))Floc(h/abs(Floc)))phi/3.;`
			`f1L=f1L+phi'Flocnorm(delset)/3.;`
			`f2L=f2L+(delphi'(delset/norm(delset))Floc)(h/abs(Floc))Floc*norm(delset)/3.;`
			`vs=h((abs(visc+Flocnorm(delset)))/(norm(Floc*delset)+h));`
			`f3L=f3L+vsdelphi'delset/3.;`
			`end`
			`for k=1:3;`
			`for j=1:3;`
			`mMat(NBelem(i,j),NBelem(i,k))=mMat(NBelem(i,j),NBelem(i,k))+mMatL(j,k);`
			`mMatGLS(NBelem(i,j),NBelem(i,k))=mMatGLS(NBelem(i,j),NBelem(i,k))+mMatGLSL(j,k);`
			`end`
			`f1(NBelem(i,k))=f1(NBelem(i,k))+f1L(k);`
			`f2(NBelem(i,k))=f2(NBelem(i,k))+f2L(k);`
			`f3(NBelem(i,k))=f3(NBelem(i,k))+f3L(k);`
			`end`
			`end`
			`mMat`
			`mMatGLS`
			`(mMat+mMatGLS)^-1`
			`f1+f2+f3`
			`dt=0.1;`
			`-((((mMat+mMatGLS)^-1)dt)(f1+f2+f3))'`
			`lSet=lSet-((((mMat+mMatGLS)^-1)dt)(f1+f2+f3))';`
			`end`
			`lSet';`
			`%scatter3(Node(:,1), Node(:,2), lSet');`