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I am developing a finite element software that minimizes the energy of a mechanical structure. Using octave and its optim package, I run into a strange issue: The lm_feasible algorithm doesn't calculate at all when I use more than 300 degrees of freedom (DoF). Another algorithm (sqp) performs the calculation but doesn't work well when I complexify the structure and are out of my test case.

Is there a limit in the number of DoF with lm_feasible algorithm?

If so, how many DoF are maximally possible?

To give an overview and general idea of how the code works:

[x,y] = geometryGenerator()

U = zeros(lenght(x)*2,1);
U(1:2:end-1) = x;
U(2:2:end) = y;

%Non geometric argument are not optimised, and fixed during calculation
fct =@(U)complexFunctionOfEnergyIWrap(U(1:2:end-1),U(2:2:end), variousMaterialPropertiesAndOtherArgs)

para = optimset("f_equc_idx",contEq,"lb",lb,"ub",ub,"objf_grad",dEne,"objf_hessian",d2Ene,"MaxIter",1000);
[U,eneFinale,cvg,outp] = nonlin_min(fct,U,para)

Full example:

clear

pkg load optim

function [x,y] = geometryGenerator(r,elts = 100)
  teta  = linspace(0,pi,elts = 100);
  x = r * cos(teta);
  y = r * sin(teta);
endfunction

function ene  = complexFunctionOfEnergyIWrap (x,y,E,P, X,Y)
  ene = 0;
  for i = 1:length(x)-1
    ene += E*(x(i)/X(i))^4+ E*(y(i)/Y(i))^4- P *(x(i)^2+(x(i+1)^2)-x(i)*x(i+1))*abs(y(i)-y(i+1));
  endfor
endfunction

[x,y] = geometryGenerator(5,100)

%Little distance from axis to avoid division by zero
x +=1e-6;
y +=1e-6;
%Saving initial geometry
X = x;
Y = y;

%Vectorisation of the function
%% Initial vector
U = zeros(length(x)*2,1);
U(1:2:end-1) = linspace(min(x),max(x),length(x));
U(2:2:end) = linspace(min(y),max(y),length(y));

%%Constraints
Aeq = zeros(3,length(U));
%%% Blocked bottom
    Aeq(1,1) = 1;
    Aeq(2,2) = 1;
%%% Sliding top    
    Aeq(3,end-1) = 1;
%%%Initial condition
    beq = zeros(3,1);
    beq(1) = U(1);
    beq(2) = U(2);
    beq(3) = U(end-1);

    contEq = @(U) Aeq * U - beq;

%Parameter
Mat = 0.2e9;
pressure = 50;

%% Vectorized function. Non geometric argument are not optimised, and fixed during calculation
fct =@(U)complexFunctionOfEnergyIWrap(U(1:2:end-1),U(2:2:end), Mat, pressure, X, Y)

para = optimset("Algorithm","lm_feasible","f_equc_idx",contEq,"MaxIter",1000);
[U,eneFinale,cvg,outp] = nonlin_min(fct,U,para)

xFinal = U(1:2:end-1);
yFinal = U(2:2:end);

plot(x,y,';Initial geo;',xFinal,yFinal,'--x;Final geo;')
  • can you create a MCVE? – Andy Jul 12 '19 at 14:55
  • It probable depends on how much RAM your machine has available, how much is allocated to Octave, etc. I know FEA well, and I understand what optimization means, but I don't know what "minimize the energy of a mechanical structure" means. Is this a static or dynamic problem? What non-geometric variables are allowed to float? Over what range? What do your constraints look like? 300 dof is not a large problem at all. I doubt very much that this is your problem. – duffymo Jul 12 '19 at 18:54
  • @Andy I will ASAP. But it may not replicate the issue as the function to optimize will be simpler – Cailloumax Jul 15 '19 at 7:43
  • @duffymo This is a static axisymmetric problem. By minimize energy, I mean like my elements are kind of little spring with mass affected by several forces, and all this forces have potential energy (and the spring as well). I search the geometric conformation where the sum of all forces is minimal. For constraints, I have a point pinned to a location (X and Y of first equal initial location), and a sliding point on Y axis (X equal 0 on last point). My geometry is a simple chain of elements – Cailloumax Jul 15 '19 at 7:43
  • I know the physics, thank you. I thought that FEA gave you that minimum solution. You start the formulation with a functional integral or weighted residuals. The resulting matrix expression is the minimum energy solution. Optimization suggests something else entirely to me. – duffymo Jul 15 '19 at 13:53
1

Finite Element Method is typically formulated as the optimal criteria for the minimization problem, which is equivalent to the Virtual Work Principle (see books like Hughes of Bathe). The Virtual Work, represents a set of linear (or nonlinear) equations which can be solved more efficiently (with fsolve).

If for some motive you must solve the problem as an optimization problem, then, if you are considering linear elasticity, your strain energy is quadratic, thus you could use the qp Octave function.

To use sparse matrices could also be helpful.

| improve this answer | |
  • I know that I can use qp to solve the problem (cause I do), and this doesn't really address the question, which is: is there a limit on the number of DoF with lm_feasible. Because I have some non-convergence issue with sqp algorithm, even with many iterations, when my condition begin to be "extreme". With lm_feasible, wich is derivated from Gauss-Newton, I have better and quicker convergence. However, when I use many elements, it doesn't process at all (with lm_feasible). – Cailloumax Jul 15 '19 at 7:52
  • Now that you added the functional to minimize I can see that the problem is very nonlinear. Optimization convergence is related to the initial point and the search space size. You should try with an initial point very close to the solution first and see if it converges. If not, then your functional or gradient are wrong. Just to know... Which is the problem u are solving? – jorgepz Jul 15 '19 at 10:40
  • I do inflatable structures resolution. My best initial guess is to give the "out of the box"/factory shape and then apply pressure condition. The problem is that in certain pressure cases this initial shape is really different from the final minimal energy one. – Cailloumax Jul 16 '19 at 7:54
  • 1
    then, you should start validating your algorithm using very small loads. in that case your initial guess is very similar to the optimal, and (if the code is ok) it should converge. if not, you have a problem somewhere. in that case you could then check if you are solving the right problem by minimizing a function with known solution.... solving this is probably something your advisor shall help you to do... – jorgepz Jul 16 '19 at 8:37

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