compact_topology_optimization/3d/util/top3d.m

%--------------------------
 % @Author: Jingqiao Hu
 % @Date: 2022-01-18 00:12:35
 % @LastEditTime: 2022-01-18 00:41:09
%--------------------------
% AN 169 LINE 3D TOPOLOGY OPITMIZATION CODE BY LIU AND TOVAR (JUL 2013)
function x = top3d(nelx,nely,nelz,volfrac, vF,optDesign)
    % USER-DEFINED LOOP PARAMETERS
    maxloop = 100;    % Maximum number of iterations
    tolx = 0.001;      % Terminarion criterion
    displayflag = 0;  % Display structure flag
    % USER-DEFINED MATERIAL PROPERTIES
    E0 = 1;           % Young's modulus of solid material
    Emin = 1e-9;      % Young's modulus of void-like material
    nu = 0.3;         % Poisson's ratio
    penal = 1;
    rmin = 2;
    
    % USER-DEFINED LOAD DOFs
    switch optDesign
    case 'cantilever'
        il = nelx; jl = 0; kl = 0:nelz;                         % Coordinates
        loadnid = kl*(nelx+1)*(nely+1)+il*(nely+1)+(nely+1-jl); % Node IDs
        loaddof = 3*loadnid(:) - 1;                             % DOFs
        % USER-DEFINED SUPPORT FIXED DOFs
        [jf,kf] = meshgrid(1:nely+1,1:nelz+1);                  % Coordinates
        fixednid = (kf-1)*(nely+1)*(nelx+1)+jf;                 % Node IDs
        fixeddof = [3*fixednid(:); 3*fixednid(:)-1; 3*fixednid(:)-2]; % DOFs
    
    case 'Lshape'
        fixednid = [];
        for i = 1:nely/2+1
            idx = (i-1) * (nely+1) * (nelx+1) + 1;
            fixednid = [fixednid; idx : nely+1 : (nelx/2)*(nely+1)+idx];
        end
        fixeddof = [3*fixednid(:); 3*fixednid(:)-1; 3*fixednid(:)-2]; % DOFs
        
        loadnid = (nely+1) * (nelx+1) * (nelz/2) - nely/4;
        loaddof = 3*loadnid(:) - 1;                             % DOFs
    end

    % PREPARE FINITE ELEMENT ANALYSIS
    nele = nelx*nely*nelz;
    ndof = 3*(nelx+1)*(nely+1)*(nelz+1);
    F = sparse(loaddof,1,-vF,ndof,1);

    U = zeros(ndof,1);
    freedofs = setdiff(1:ndof,fixeddof);
    KE = lk_H8(nu);
    nodegrd = reshape(1:(nely+1)*(nelx+1),nely+1,nelx+1);
    nodeids = reshape(nodegrd(1:end-1,1:end-1),nely*nelx,1);
    nodeidz = 0:(nely+1)*(nelx+1):(nelz-1)*(nely+1)*(nelx+1);
    nodeids = repmat(nodeids,size(nodeidz))+repmat(nodeidz,size(nodeids));
    edofVec = 3*nodeids(:)+1;
    edofMat = repmat(edofVec,1,24)+ ...
        repmat([0 1 2 3*nely + [3 4 5 0 1 2] -3 -2 -1 ...
        3*(nely+1)*(nelx+1)+[0 1 2 3*nely + [3 4 5 0 1 2] -3 -2 -1]],nele,1);
    iK = reshape(kron(edofMat,ones(24,1))',24*24*nele,1);
    jK = reshape(kron(edofMat,ones(1,24))',24*24*nele,1);
    % PREPARE FILTER
    iH = ones(nele*(2*(ceil(rmin)-1)+1)^2,1);
    jH = ones(size(iH));
    sH = zeros(size(iH));
    k = 0;
    for k1 = 1:nelz
        for i1 = 1:nelx
            for j1 = 1:nely
                e1 = (k1-1)*nelx*nely + (i1-1)*nely+j1;
                for k2 = max(k1-(ceil(rmin)-1),1):min(k1+(ceil(rmin)-1),nelz)
                    for i2 = max(i1-(ceil(rmin)-1),1):min(i1+(ceil(rmin)-1),nelx)
                        for j2 = max(j1-(ceil(rmin)-1),1):min(j1+(ceil(rmin)-1),nely)
                            e2 = (k2-1)*nelx*nely + (i2-1)*nely+j2;
                            k = k+1;
                            iH(k) = e1;
                            jH(k) = e2;
                            sH(k) = max(0,rmin-sqrt((i1-i2)^2+(j1-j2)^2+(k1-k2)^2));
                        end
                    end
                end
            end
        end
    end
    H = sparse(iH,jH,sH);
    Hs = sum(H,2);
    % INITIALIZE ITERATION
    x = repmat(volfrac,[nely,nelx,nelz]);
    xPhys = x; 
    loop = 0; 
    change = 1;
    % START ITERATION
    while change > tolx && loop < maxloop
        loop = loop+1;
        % FE-ANALYSIS
        sK = reshape(KE(:)*(Emin+xPhys(:)'.^penal*(E0-Emin)),24*24*nele,1);
        K = sparse(iK,jK,sK); K = (K+K')/2;
        U(freedofs,:) = K(freedofs,freedofs)\F(freedofs,:);
        % OBJECTIVE FUNCTION AND SENSITIVITY ANALYSIS
        ce = reshape(sum((U(edofMat)*KE).*U(edofMat),2),[nely,nelx,nelz]);
        c = sum(sum(sum((Emin+xPhys.^penal*(E0-Emin)).*ce)));
        dc = -penal*(E0-Emin)*xPhys.^(penal-1).*ce;
        dv = ones(nely,nelx,nelz);
        % FILTERING AND MODIFICATION OF SENSITIVITIES
        dc(:) = H*(dc(:)./Hs);  
        dv(:) = H*(dv(:)./Hs);
        % OPTIMALITY CRITERIA UPDATE
        l1 = 0; l2 = 1e9; move = 0.2;
        while (l2-l1)/(l1+l2) > 1e-3
            lmid = 0.5*(l2+l1);
            xnew = max(0,max(x-move,min(1,min(x+move,x.*sqrt(-dc./dv/lmid)))));
            xPhys(:) = (H*xnew(:))./Hs;
            if sum(xPhys(:)) > volfrac*nele, l1 = lmid; else l2 = lmid; end
        end
        change = max(abs(xnew(:)-x(:)));
        x = xnew;
        % PRINT RESULTS
        fprintf(' It.:%5i Obj.:%11.4f Vol.:%7.3f ch.:%7.3f\n',loop,c,mean(xPhys(:)),change);
        % PLOT DENSITIES
        % if displayflag, clf; display_3D(xPhys); end %#ok<UNRCH>
        
        if strcmp(optDesign, 'Lshape')
            xPhys(1:nely/2, nelx/2+1:nelx, :) = 0;
        end
        xPhys(nely/4:(nely/4*3),(nelx/8*3):(nelx/8*5), :) = 0;
        clf; display_3D(xPhys);
    end
%     clf; display_3D(xPhys);
end
    
    
% === GENERATE ELEMENT STIFFNESS MATRIX ===
function [KE] = lk_H8(nu)
A = [32 6 -8 6 -6 4 3 -6 -10 3 -3 -3 -4 -8;
    -48 0 0 -24 24 0 0 0 12 -12 0 12 12 12];
k = 1/144*A'*[1; nu];

K1 = [k(1) k(2) k(2) k(3) k(5) k(5);
    k(2) k(1) k(2) k(4) k(6) k(7);
    k(2) k(2) k(1) k(4) k(7) k(6);
    k(3) k(4) k(4) k(1) k(8) k(8);
    k(5) k(6) k(7) k(8) k(1) k(2);
    k(5) k(7) k(6) k(8) k(2) k(1)];
K2 = [k(9)  k(8)  k(12) k(6)  k(4)  k(7);
    k(8)  k(9)  k(12) k(5)  k(3)  k(5);
    k(10) k(10) k(13) k(7)  k(4)  k(6);
    k(6)  k(5)  k(11) k(9)  k(2)  k(10);
    k(4)  k(3)  k(5)  k(2)  k(9)  k(12)
    k(11) k(4)  k(6)  k(12) k(10) k(13)];
K3 = [k(6)  k(7)  k(4)  k(9)  k(12) k(8);
    k(7)  k(6)  k(4)  k(10) k(13) k(10);
    k(5)  k(5)  k(3)  k(8)  k(12) k(9);
    k(9)  k(10) k(2)  k(6)  k(11) k(5);
    k(12) k(13) k(10) k(11) k(6)  k(4);
    k(2)  k(12) k(9)  k(4)  k(5)  k(3)];
K4 = [k(14) k(11) k(11) k(13) k(10) k(10);
    k(11) k(14) k(11) k(12) k(9)  k(8);
    k(11) k(11) k(14) k(12) k(8)  k(9);
    k(13) k(12) k(12) k(14) k(7)  k(7);
    k(10) k(9)  k(8)  k(7)  k(14) k(11);
    k(10) k(8)  k(9)  k(7)  k(11) k(14)];
K5 = [k(1) k(2)  k(8)  k(3) k(5)  k(4);
    k(2) k(1)  k(8)  k(4) k(6)  k(11);
    k(8) k(8)  k(1)  k(5) k(11) k(6);
    k(3) k(4)  k(5)  k(1) k(8)  k(2);
    k(5) k(6)  k(11) k(8) k(1)  k(8);
    k(4) k(11) k(6)  k(2) k(8)  k(1)];
K6 = [k(14) k(11) k(7)  k(13) k(10) k(12);
    k(11) k(14) k(7)  k(12) k(9)  k(2);
    k(7)  k(7)  k(14) k(10) k(2)  k(9);
    k(13) k(12) k(10) k(14) k(7)  k(11);
    k(10) k(9)  k(2)  k(7)  k(14) k(7);
    k(12) k(2)  k(9)  k(11) k(7)  k(14)];
KE = 1/((nu+1)*(1-2*nu))*...
    [ K1  K2  K3  K4;
    K2'  K5  K6  K3';
    K3' K6  K5' K2';
    K4  K3  K2  K1'];
end
% === DISPLAY 3D TOPOLOGY (ISO-VIEW) ===
function display_3D(rho)
[nely,nelx,nelz] = size(rho);
hx = 1; hy = 1; hz = 1;            % User-defined unit element size
face = [1 2 3 4; 2 6 7 3; 4 3 7 8; 1 5 8 4; 1 2 6 5; 5 6 7 8];
set(gcf,'Name','ISO display','NumberTitle','off');
for k = 1:nelz
    z = (k-1)*hz;
    for i = 1:nelx
        x = (i-1)*hx;
        for j = 1:nely
            y = nely*hy - (j-1)*hy;
            if (rho(j,i,k) > 0.1)  % User-defined display density threshold
                vert = [x y z; x y-hx z; x+hx y-hx z; x+hx y z; x y z+hx;x y-hx z+hx; x+hx y-hx z+hx;x+hx y z+hx];
                vert(:,[2 3]) = vert(:,[3 2]); vert(:,2,:) = -vert(:,2,:);
                patch('Faces',face,'Vertices',vert,'FaceColor',[0.2+0.8*(1-rho(j,i,k)),0.2+0.8*(1-rho(j,i,k)),0.2+0.8*(1-rho(j,i,k))]);
                hold on;
            end
        end
    end
end
axis equal; axis tight; axis off; box on; view([30,30]); pause(1e-6);
end