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This MATLAB code shows how one can build a bridge according to topological optimization theory. The code is also based on Euler-Bernoulli beam theory.

The very last part (%% Optimality Criteria Update) consists of optimality criteria method. However, I have some trouble understanding this sentence.

xnew=max(0.001,max(x-move,min(1,min(x+move,x.*sqrt(-dc./lmid)))));

At the end of this sentence, one is going to compare 1, x+move, and x.*sqrt(-dc./lmid), and find the minimum value among them. However, I don't understand what this x.*sqrt(-dc./lmid) means, and why it suddenly comes out.

Can anyone explain what this x.*sqrt(-dc./lmid) means, and why do I have to compare it? This image might be of help.

%% Ground-structure based Topology Optimization by D.-M. Kim, May 2016
function gstop(Nx,Ny,Vlim,penal,maxL)
% Generate Nodes & Elements
[node,elem]=GS(Nx,Ny,maxL);

Ne=size(elem,1);    % Total number of elements
% Initialize
x=zeros(Ne,1);
x(1:Ne)=0.1;     % initial density
loop=0;
change=1;
change2=1;
c=0;
cold=0;
diffc=1;
diffc2=1;
xold=x;

filedir = 'images/Plot_iteration_';

% Start Iteration
while ((change>0.001 && change2>0.001) || (diffc>1e-2 && diffc2>1e-2))
    loop=loop+1;
    xold2=xold;
    xold=x;
    cold2=cold;
    cold=c;
    % FE-analysis
    [U]=FE(Nx,Ny,node,elem,x,penal);
    % Objective Function and Sensitivity Analysis
    [KE]=stiffness(elem);       % element stiffness matrix
    c=0.;
    dc=zeros(Ne,1);
    for jj=1:Ne
        n1=elem(jj,1);
        n2=elem(jj,2);
        Ue=U([3*n1-2;3*n1-1;3*n1;3*n2-2;3*n2-1;3*n2],1);
        c=c+x(jj)^penal*Ue'*KE(:,:,jj)*Ue;
        dc(jj)=-penal*x(jj)^(penal-1)*Ue'*KE(:,:,jj)*Ue;
    end
    % Design Update by the Optimality Criteria Method
    [x]=OC(x,elem,Vlim,dc);
    % Print Results
    change=max(abs(x-xold));
    change2=max(abs(x-xold2));
    diffc=abs((c-cold)/c);
    diffc2=abs((c-cold2)/c);
    disp(['It.:' sprintf('%4i',loop) ' / Obj.:' sprintf('%10.4f',c)...
        ' / Vol.:' sprintf('%6.3f',x'*elem(:,3))...
        ' / ch.:' sprintf('%6.3f',change)])
    % Plot Densities
    clf
    hold on
    plot(node(:,1),node(:,2),'.','color','r','markersize',3)
    [xsort,order]=sort(x);
    for jj=1:Ne
        if xsort(jj)>0.01
            n1=elem(order(jj),1);
            n2=elem(order(jj),2);            
            % undeformed
            x1=node(n1,1); y1=node(n1,2);
            x2=node(n2,1); y2=node(n2,2);
              % deformed
              x1=node(n1,1)+U(3*n1-2); y1=node(n1,2)+U(3*n1-1);
              x2=node(n2,1)+U(3*n2-2); y2=node(n2,2)+U(3*n2-1);
            r=3*xsort(jj);
            rr=1-xsort(jj);
            plot([x1,x2],[y1,y2],'linewidth',r,'color',rr*[0 0 0])

            % plotting the mirror image
            hold on
            plot([-x1, -x2], [y1, y2],'linewidth',r,'color',rr*[1 1 1])
        end
    end
    axis equal; axis tight; axis off; pause(1e-6);

    print(strcat(filedir, int2str(loop)), '-dpng');
end

%% Generate Ground-structure (Nodes & Elements)
function [node,elem]=GS(Nx,Ny,maxL)
Nn=Nx*Ny;       % Total Number of nodes
node=zeros(Nn,2);   % Location of nodes (col1: x-dir / col2: y-dir)
Lx=80; Ly=40;
% Generate Nodes
no=0;
for jy=1:Ny
    for jx=1:Nx
        no=no+1;
        node(no,1)=(Lx/(Nx-1))*(jx-1);    % x-dir. position
        node(no,2)=(Ly/(Ny-1))*(jy-1);    % y-dir. position
    end
end

% Generate Elements
elem=zeros(10000,4);    % Element data (node 1 / node 2 / elem. length / rotation angle)
no=0;
for n1=1:Nn
    no_temp=0;
    the_temp=[];
    for n2=n1+1:Nn
        x1=node(n1,1); y1=node(n1,2);
        x2=node(n2,1); y2=node(n2,2);
        dx=x2-x1; dy=y2-y1;
        E_len=norm([dx,dy]);
        E_theta=acos(dx/E_len);
        max_length=maxL*(Lx/(Nx-1));
        % Save element data only if the length is shorter than maxL
        if (E_len<=max_length)&&(no_temp==0||isempty(find(abs(the_temp-E_theta)<1e-3,1)))
            no=no+1;
            elem(no,:)=[n1,n2,E_len,E_theta];
            no_temp=no_temp+1;
            the_temp(no_temp,1)=E_theta;
        end
    end
end
elem=elem(1:no,:);

%% FE-analysis
function [U]=FE(Nx,Ny,node,elem,x,penal)
[KE]=stiffness(elem);       % element stiffness matrix
Nn=size(node,1);    % Total number of nodes
Ne=size(elem,1);    % Total number of elements
K=zeros(3*Nn,3*Nn);     % global stiffness matrix
F=zeros(3*Nn,1);        % load vector
U=zeros(3*Nn,1);        % displacement vector
for jj=1:Ne
    n1=elem(jj,1);
    n2=elem(jj,2);
    edof=[3*n1-2;3*n1-1;3*n1;3*n2-2;3*n2-1;3*n2];
    K(edof,edof)=K(edof,edof)+x(jj)^penal*KE(:,:,jj);
end
% Define Loads and Supports
F(2,1)=-10;    %kN
fixeddofs=union([1:3*Nx:3*Nx*(Ny-1)+1],[3:3*Nx:3*Nx*(Ny-1)+3]);
fixeddofs=union([3*Nx-1],fixeddofs);
alldofs=[1:3*Nn];
freedofs=setdiff(alldofs,fixeddofs);
% Solving
U(freedofs,:)=K(freedofs,freedofs)\F(freedofs,:);
U(fixeddofs,:)=0;

%% Stiffness matrix
function [KE]=stiffness(elem)
E=10000;
b=0.2;
h=0.4;
inertia=b*h^3/12;
csarea=b*h;
Ne=size(elem,1);    % Total number of elements
KE1=zeros(6,6,Ne);
KE2=zeros(6,6,Ne);
KE=zeros(6,6,Ne);
KEL=zeros(6,6,Ne);
for jj=1:Ne
    EL=elem(jj,3);
    KE1(:,:,jj)=inertia*E/(EL^3)*...
        [0  0       0       0   0       0;
        0   12      6*EL    0   -12     6*EL;
        0   6*EL    4*EL^2  0   -6*EL   2*EL^2;
        0   0       0       0   0       0;
        0   -12     -6*EL   0   12      -6*EL;
        0   6*EL    2*EL^2  0   -6*EL   4*EL^2];
    KE2(:,:,jj)=csarea*E/EL*...
        [1  0   0   -1  0   0;
        0   0   0   0   0   0;
        0   0   0   0   0   0;
        -1  0   0   1   0   0;
        0   0   0   0   0   0;
        0   0   0   0   0   0];
    cs=cos(elem(jj,4));
    si=sin(elem(jj,4));
    T=[cs si  0   0   0   0;
        -si cs  0   0   0   0;
        0   0   1   0   0   0;
        0   0   0   cs  si  0;
        0   0   0   -si cs  0;
        0   0   0   0   0   1];
    KEL(:,:,jj)=KE1(:,:,jj)+KE2(:,:,jj);
    KE(:,:,jj)=T'*KEL(:,:,jj)*T;
end

%% Optimality Criteria Update
function [xnew]=OC(x,elem,Vlim,dc)
l1=0; l2=100000; move=0.1;
while (l2-l1>1e-4)
    lmid=0.5*(l2+l1);
    xnew=max(0.001,max(x-move,min(1,min(x+move,x.*sqrt(-dc./lmid)))));
    vol=xnew'*elem(:,3);
    if vol-Vlim>0
        l1=lmid;
    else
        l2=lmid;
    end
end

1 Answer 1

3

TL;DR: answering the question directly

what this x.*sqrt(-dc./lmid) means, and why do I have to compare it?

(1) x.*sqrt(-dc./lmid) is x·Beη, the updated value xenew.

(2) You have to compare it to make sure that it is inside an appropriate interval (greater than or equal to xmin and xe-m, and less than or equal to 1 and xe+m).

Explanation

What is Beη

Following the optimality criteria, you want to update your previous xe estimation to a more accurate value. You will achieve this by multiplying xe by a factor q:

xenew = xe·q

  • If q is exactly 1, then xe is already in a (possibly local) optimum.
  • If q > 1, then you underestimated xe.
  • If q < 1, then you overestimated xe.

In your example, q is Beη.

Meaning of η

The first thing to note is that η is a tuning parameter, i.e., it is used to help the convergence of the method. It is called "damping coefficient" because it restricts the size of Beη (note that 0 < η <= 1). In your example, it was empirically set to 0.5, which is the square root.

Why the comparison

xe is restricted to xmin <= xe <= 1. So, we have to make sure that if xenew is less than xmin or greater than 1, we will truncate it. For reference, this operation is commonly called clamping. Besides, we also want to restrict xenew to be somewhat close to xe (to help convergence). Thus, we need to clamp xenew again to be closer than an m value. Both comparisons will assure that xenew is valid (xmin <= xe·Beη <= 1) and close to the previous value (xe - m <= xe·Beη <= xe + m).

What is sqrt(-dc./lmid)

It is Beη. Looking at the image you added, we can see that the sqrt comes from η, -dc is -∂c/∂xe, and lmid comes from λ·∂V/∂xe. As in this case the volume of an element is always the same, dV = 1, and thus it gets out of the equation. Thus, lmid is only λ. It is called "mid" because to find it, the code runs a bisection algorithm, which divides the interval by half every iteration.

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