Error using fmincon MATLAB function

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HAT
HAT on 3 Oct 2020
Edited: HAT on 4 Nov 2020
I would like to obtain the minimum of the function using MATLAB 'fmincon' function where the first eigenvalue derived from the given matrix is my objective function. I was to write/supply its objective function, but it is too long to put it inside the code. I wrote the following code, but I got stuck to continue. The error I found is:
Error using symengine
Unable to convert expression into double array.
I was wondering if I could get help? Thanks.
options = optimoptions('fmincon','GradObj','on');
x = fmincon(@myfun,[1,1],[],[],[],[],[1,1],[2,2],[],options)
function [f,g] = myfun(x)
syms x1 x2;
% 4 by 4 matrix with two variables inside
C=[1 2 x1 4;...
1/2 1 3 x2;...
1/x1 5 1 3/2;...
1/4 1/x2 2 1];
f1 = eig(C); % calculates eigenvalues
f=f1(1); % the first eigenvalue
if nargout > 1 % gradient required
% Calculate partial derivatives of f
g(1) = diff(f,x1);
g(2) = diff(f,x2);
g = double([g(1);g(2)]);% data type double
end
end
  2 Comments
Walter Roberson
Walter Roberson on 5 Oct 2020
When you say "first" do you mean the one with largest absolute value?
Walter Roberson
Walter Roberson on 5 Oct 2020
using the eigenvalue with the largest absolute value is potentially discontinuous in the variables. fmincon requires differentiable jacobian but anything equivalent to a max() operation is not differentiateable at the boundary (and the jacobian potentially turns into zero with respect to some of the variables.)

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Accepted Answer

Matt J
Matt J on 29 Oct 2020
Edited: Matt J on 29 Oct 2020
Ran in:
Because of the discontinuity at x1=0 and x2=0, you need to optimize over each quadrant separately.
s=[+1,+1; %quadrant signs
-1,+1;
+1,-1;
-1,-1];
[X1,X2] =ndgrid(linspace(1e-5,2,100));
clear Q xcell
for i=4:-1:1 %optimize over each quadrant
F=arrayfun(@myfun,X1*s(i,1),X2*s(i,2)); %initial discrete search for initial guess
[r,c]=find(F==min(F(:)),1);
x0=[X1(r,c)*s(i,1),X2(r,c)*s(i,2)];
[xcell{i},Q(i)]= fminsearch(@(x)myfun(x(1),x(2)), x0 ,...
optimset('MaxFunEvals',1e8,'MaxIter',1e6));
end
[~,j]=min(Q); %pick the best quadrant
[fOptimal,xOptimal]=deal(Q(j),xcell{j}) %final solution
fOptimal = 4.0000
xOptimal = 1×2
1.5995 -0.1835
function fval = myfun(x1,x2)
if abs(abs(x1)-1)>=1, fval=inf; return; end
if abs(abs(x2)-1)>=1, fval=inf; return; end
fval= max(abs(eig([1 2 x1 4;...
1/2 1 3 x2;...
1/x1 5 1 3/2;...
1/4 1/x2 2 1])));
end
  8 Comments
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Matt J
Matt J on 1 Nov 2020
You're welcome, but please Accept-click the answer if you consider the question resolved.

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More Answers (1)

Walter Roberson
Walter Roberson on 5 Oct 2020
You can use the symbolic toolbox to generate eig() on the matrix with Symbolic x1 and x2, and then you can matlabFunction that and pass the handle into the objective function. You would also calculate the g functions with respect to each of the four eigenvalues, and pass those handles as well.
The objective would then not have any symbolic operations. It would call the stored handle upon the input x values, getting back a vector of four eigenvalues. It would figure out which had the largest absolute value and store in f. If nargout requires, it would use the index to select the jacobian handle and evaluate it on the current inputs and return those.
  1 Comment
Walter Roberson
Walter Roberson on 29 Oct 2020
% fmincon with gradient vector
syms x1 x2
vars = [x1, x2];
C=[1 2 x1 4;...
1/2 1 3 x2;...
1/x1 1/3 1 1/5;...
4 1/x2 5 1];
f=eig(C) % generate eigenvalues on the matrix with Symbolic x1 and x2
eigFunction = matlabFunction(f, 'vars', {vars}); % matlabFunction that and pass the handle into the objective function
% % calculate the g functions with respect to each of the four eigenvalues
g = jacobian([f(1), f(2), f(3),f(4)], vars); % jacobian
gradFunction = matlabFunction(g, 'vars', {vars});
x=ones(2,1); % initial value
% MATLAB fmincon
options = optimoptions('fmincon','GradObj','on');
x = fmincon(@(x)myfun(x, eigFunction, gradFunction), x, [], [], [], [], [1,1], [2,2], [], options)
function [objFunction2 grad2] = myfun(x, eigFunction, gradFunction)
t = eigFunction(x);
[~, maxidx] = max(abs(t));
objFunction2 = t(maxidx);
% If nargout requires, it would use the index
%to select the jacobian handle and evaluate it on the current inputs and return those.
if nargout > 1
gradvalues = gradFunction(x);
grad2 = gradvalues(maxidx);
end
end

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