# Is there a limit in the number of degrees of freedom with the lm_feasible algorithm? If so, what is the limit?

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)

[U,eneFinale,cvg,outp] = nonlin_min(fct,U,para)
``````

Full example:

``````clear

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