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Hi everybody, i am looking for a solution for comparison of convergence time between two algorithms, two optimization problem actually. Is there any toolbox or sample code?

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hadi mostafavi amjad
hadi mostafavi amjad am 5 Nov. 2020
Geschlossen: MATLAB Answer Bot am 20 Aug. 2021
Calc convergence time of two algorithm and find out which one is better!

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Walter Roberson
Walter Roberson am 5 Nov. 2020
Ran in:
Niters = 5;
x = 1 : 50;
y = besselj(3, x) + randn(size(x))/20;
nvars = 2;
model1 = @(AB, x) AB(1).*x.^AB(2); %a*x^b
model2 = @(AB, x) x.^3 + AB(1).*x.^2 + AB(2).*log(x); %x^3 + a*x^2 + b*log(x);
residue1 = @(AB) sum((model1(AB, x) - y).^2);
residue2 = @(AB) sum((model2(AB, x) - y).^2);
models = {residue1, residue2};
modnames = {'a*x^b', 'x^3 + a*x^2 + b*log(x)'};
Nmodels = length(models);
x0 = randn(1,nvars) * 10;
fminunc_options = optimoptions(@fminunc, 'MaxIterations', 1e5);
ga_options = optimoptions(@ga, 'MaxGenerations', 1e5);
A = []; b = []; Aeq = []; beq = []; lb = []; ub = []; nlcon = [];
alg1 = @(FUN) fminunc( FUN, x0, fminunc_options );
alg2 = @(FUN) ga(FUN, nvars, A, b, Aeq, beq, lb, ub, nlcon, ga_options);
algs = {alg1, alg2};
algnames = {'fminunc', 'ga'};
itercount_fminunc = @(info) info.funcCount;
itercount_ga = @(info) info.funccount;
itercount_funs = {itercount_fminunc, itercount_ga};
Nalgs = length(algs);
timings = zeros(Niters, Nalgs, Nmodels);
fvals = zeros(Niters, Nalgs, Nmodels);
infos = cell(Niters, Nalgs, Nmodels);
bestAB = cell(Niters, Nalgs, Nmodels);
itercounts = zeros(Niters, Nalgs, Nmodels);
for modidx = 1 : Nmodels
thismodel = models{modidx};
for algidx = 1 : Nalgs
thisalg = algs{modidx};
itercount_fun = itercount_funs{modidx};
for iter = 1 : Niters
tic;
[bestAB{iter, algidx, modidx}, fvals(iter, algidx, modidx), ~, infos{iter, algidx, modidx}] = thisalg(thismodel);
timings(iter, algidx, modidx) = toc;
itercounts(iter, algidx, modidx) = itercount_fun(infos{iter, algidx, modidx});
end
end
end
Local minimum found. Optimization completed because the size of the gradient is less than the value of the optimality tolerance. Local minimum found. Optimization completed because the size of the gradient is less than the value of the optimality tolerance. Local minimum found. Optimization completed because the size of the gradient is less than the value of the optimality tolerance. Local minimum found. Optimization completed because the size of the gradient is less than the value of the optimality tolerance. Local minimum found. Optimization completed because the size of the gradient is less than the value of the optimality tolerance. Local minimum found. Optimization completed because the size of the gradient is less than the value of the optimality tolerance. Local minimum found. Optimization completed because the size of the gradient is less than the value of the optimality tolerance. Local minimum found. Optimization completed because the size of the gradient is less than the value of the optimality tolerance. Local minimum found. Optimization completed because the size of the gradient is less than the value of the optimality tolerance. Local minimum found. Optimization completed because the size of the gradient is less than the value of the optimality tolerance. Optimization terminated: average change in the fitness value less than options.FunctionTolerance. Optimization terminated: average change in the fitness value less than options.FunctionTolerance. Optimization terminated: average change in the fitness value less than options.FunctionTolerance. Optimization terminated: average change in the fitness value less than options.FunctionTolerance. Optimization terminated: average change in the fitness value less than options.FunctionTolerance. Optimization terminated: average change in the fitness value less than options.FunctionTolerance. Optimization terminated: average change in the fitness value less than options.FunctionTolerance. Optimization terminated: average change in the fitness value less than options.FunctionTolerance. Optimization terminated: average change in the fitness value less than options.FunctionTolerance. Optimization terminated: average change in the fitness value less than options.FunctionTolerance.
meantimes = permute(mean(timings), [2 3 1]);
meaniters = permute(mean(itercounts), [2 3 1]);
t = table(meaniters(:), meantimes(:), repmat(modnames(:), Nalgs, 1), repelem(algnames(:), Nmodels, 1));
t.Properties.VariableNames = {'iterations', 'time [s]', 'model', 'algorithm'};
disp(t)
iterations time [s] model algorithm __________ _________ __________________________ ___________ 42 0.093775 {'a*x^b' } {'fminunc'} 42 0.0073104 {'x^3 + a*x^2 + b*log(x)'} {'fminunc'} 39900 0.84803 {'a*x^b' } {'ga' } 40915 0.56368 {'x^3 + a*x^2 + b*log(x)'} {'ga' }

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