双二次Lagrange 有限元计算特征值程序（基于iFEM）

function lambda = c0P2(h)
%% Mesh
[node,elem] = squarequadmesh([0,1,0,1],h);
elem = elem(:,[1,4,3,2]);
  showmesh(node,elem);
  findnode(node);
  findquadelem(node,elem);
%% Construct Data Structure
[elem2dof,edge,inDof] = c0dofP2(elem);
elem2dof=double(elem2dof);
N = size(node,1);  NT = size(elem,1);  
Ndof = N+NT+size(edge,1);
A=sparse(Ndof,Ndof);
B=sparse(Ndof,Ndof);
%% Assemble stiffness matrix
% Since Dphi_i*Dphi_j is quadratic, 
% numerical quadrature rule is used here
option.quadorder = 4;   % default order
[pts,weight] = quadquadpts(option.quadorder);
pts=pts*2-1;
x=pts(:,1);y=pts(:,2);
h1=h/2;h2=h1;
area=h2*h1;
%% Assemble Matrix 
for i=1:9 
    for j=i:9
DuDv=area*(Dxphi(x,y,h1,i).*Dxphi(x,y,h1,j)...
          +Dyphi(x,y,h2,i).*Dyphi(x,y,h2,j))'*weight; 
uv=area*(phi(x,y,i).*phi(x,y,j))'*weight; 
      if i==j
A = A + sparse(elem2dof(:,i),elem2dof(:,j),DuDv,Ndof,Ndof);
B = B + sparse(elem2dof(:,i),elem2dof(:,j),uv,Ndof,Ndof);
      else
A = A + sparse([elem2dof(:,i);elem2dof(:,j)],...
               [elem2dof(:,j);elem2dof(:,i)],DuDv,Ndof,Ndof);
B = B + sparse([elem2dof(:,i);elem2dof(:,j)],...
               [elem2dof(:,j);elem2dof(:,i)],uv,Ndof,Ndof);
      end
    end
end
%% Solve Ax = lambda Bx, and its first solution is 2*pi^2
lambda=eigs(A(inDof,inDof),B(inDof,inDof),1,'sm'); 
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% subfunction Dxphi
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
    function s = Dxphi(xi,eta,L1,i) % gradient of basis phi for x
    switch i
        case 1
            s = (eta.*(2.*xi - 1).*(eta - 1))/(4*L1);           
        case 2
            s = (eta.*(2.*xi + 1).*(eta - 1))/(4*L1);           
        case 3
            s = (eta.*(2.*xi + 1).*(eta + 1))/(4*L1);          
        case 4
            s = (eta.*(2.*xi - 1).*(eta + 1))/(4*L1);
        case 5
            s = -(eta.*xi.*(eta - 1))/L1;
        case 6
            s = -((eta.^2 - 1).*(2*xi + 1))/(2*L1);
        case 7
            s = -(eta.*xi.*(eta + 1))/L1;
        case 8
            s = -((eta.^2 - 1).*(2.*xi - 1))/(2*L1); 
        case 9
            s = (2*xi.*(eta.^2 - 1))/L1;
    end
    end
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% subfunction Dxphi
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
    function s = Dyphi(xi,eta,L2,i) % gradient of basis phi for y
     switch i
     case 1 
         s = (xi.*(2.*eta - 1).*(xi - 1))/(4*L2);
     case 2 
         s = (xi.*(2.*eta - 1).*(xi + 1))/(4*L2);
     case 3
         s = (xi.*(2.*eta + 1).*(xi + 1))/(4*L2);
     case 4
         s = (xi.*(2.*eta + 1).*(xi - 1))/(4*L2);
    case 5 
        s = -((2.*eta - 1).*(xi.^2 - 1))/(2*L2);
    case 6
        s = -(eta.*xi.*(xi + 1))/L2;
    case 7 
        s =-((2*eta + 1).*(xi.^2 - 1))/(2*L2);
    case 8 
        s = -(eta.*xi.*(xi - 1))/L2;
    case 9
        s = (2*eta.*(xi.^2 - 1))/L2;
     end
    end

%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% subfunction phi
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
    function s = phi(xi,eta,i) % gradient of basis phi
    switch i
        case 1
            s = (eta.*xi.*(eta - 1).*(xi - 1))/4;           
        case 2
            s = (eta.*xi.*(eta - 1).*(xi + 1))/4;            
        case 3
            s = (eta.*xi.*(eta + 1).*(xi + 1))/4;             
        case 4
            s = (eta.*xi.*(eta + 1).*(xi - 1))/4; 
        case 5
            s = -(eta.*(xi.^2 - 1).*(eta - 1))/2;
        case 6
            s = -(xi.*(eta.^2 - 1).*(xi + 1))/2;
        case 7
            s = -(eta.*(xi.^2 - 1).*(eta + 1))/2;
        case 8
            s = -(xi.*(eta.^2 - 1).*(xi - 1))/2;
        case 9
            s = (eta.^2 - 1).*(xi.^2 - 1);
    end
    end
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
end

function [elem2dof,edge,inDof] = c0dofP2(elem)
totalEdge=sort([elem(:,[1,2]);elem(:,[2,3]);elem(:,[3,4]);elem(:,[4,1])],2);
[edge, i2, j] = myunique(totalEdge);
N = max(elem(:)); 
NT = size(elem,1);
NE = size(edge,1);
elem2edge = reshape(j,NT,4);
elem2dof = uint32([elem N+elem2edge (N+NE+1:N+NE+NT)']);
i1(j(4*NT:-1:1)) = 4*NT:-1:1; 
i1 = i1';
bdEdgeIdx = (i1 == i2);
isBdDof = false(N+NE+NT,1);
isBdDof(edge(bdEdgeIdx,:)) = true;   % nodal 
idx = find(bdEdgeIdx);
isBdDof(N+idx) = true;
inDof = find(~isBdDof);
end

 

http://files.cnblogs.com/files/wangshixi12/%E5%8F%8C%E4%BA%8C%E6%AC%A1Lagrange%E6%9C%89%E9%99%90%E5%85%83.rar