6x6 system of multivariate quadratic equations ... non-negative real solutions

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Michal
Michal el 1 de Nov. de 2024
Editada: Bruno Luong el 5 de Nov. de 2024
What is the best way (what solver?) to effectively find real non-negative solutions of 6 multivariate quadratic equations (6 variables)?
f_i(x) = 0, i = 1,6, where x = [x1,x2,...,x6] and f_i(x) is the quadratic form with known real coeffs.
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Walter Roberson
Walter Roberson el 4 de Nov. de 2024
To confirm, you have the form:
syms x [6 1]
syms A [6 6]
A = diag(diag(A))
x' * A * x
Bruno Luong
Bruno Luong el 4 de Nov. de 2024
"A always contains only one non-zero diagonal element on the ith row/column "
To me it means
Ai(j,j) == 0 is true for i ~= j and
false for i == j.

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Respuesta aceptada

Bruno Luong
Bruno Luong el 4 de Nov. de 2024
Editada: Bruno Luong el 4 de Nov. de 2024
Assuming the equations are
x' * Ai * x + bi'*x + ci = 0 for i = 1,2, ..., N = 6.
Ai are assumed to be symmetric. If not replace with Asi := 1/2*(Ai + Ai').
You could try to iteratively solve linearized problem; in pseudo code:
x = randn(N,1); % or your solution of previous step, slowly changing as stated
L = zeros(N);
r = zeros(N,1);
notconverge = true;
while notconverge
for i = 1:N
L(i,:) = (2*x'*Ai + bi');
r(i) = -(x'*Ai*x + bi'*x + ci);
end
dx = L \ r;
xold = x;
x = x + dx;
x = max(x,0); % since we want solution >= 0
notconverge = norm(x-xold,p) > tolx && ...
norm(r,q) > tolr; % select p, q, tolx and tolr approproately
end
I guess fmincon, fsolve do somesort of Newton-like or linearization internally. But still worth to investogate. Here the linearization is straight forward and fast to compute. Some intermediate vectors in computing L and r are common and can be shared.
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Michal
Michal el 4 de Nov. de 2024
Editada: Michal el 4 de Nov. de 2024
Because in my case is ci = 0, then r(i)= 0 for x = 0 and i = 1,2, ..., 6
So, in a case of all negative components of x, is then dx = L\r = 0 and convergence of the Newton iterations is broken. Am I right?
Bruno Luong
Bruno Luong el 4 de Nov. de 2024
Editada: Bruno Luong el 5 de Nov. de 2024
x = 0 is ONE solution (up to 2^6 in the worst case). You have Newton actually converges to a local minima of ONE solution. Bravo.
You need to change
x = randn(N,1);
so as it would converge to a desired solution.

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Más respuestas (2)

Aquatris
Aquatris el 1 de Nov. de 2024
fsolve seems to work for most cases, if not lsqnonlin is also an option. here is a general explanation
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Michal
Michal el 1 de Nov. de 2024
Frankly, I hope there might be some more specialized solver for quadratic forms.
John D'Errico
John D'Errico el 1 de Nov. de 2024
@Michal
No. There is not. We all want for things that are not possible. Probably more likely to hope for peace in the world. Yeah, right.

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Torsten
Torsten el 1 de Nov. de 2024
Movida: Torsten el 1 de Nov. de 2024
I think there is no specialized solver for a system of quadratic equations. Thus a general nonlinear solver ("fsolve","lsqnonlin","fmincon") is the only chance you have.
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Torsten
Torsten el 1 de Nov. de 2024
Editada: Torsten el 1 de Nov. de 2024
You shouldn't think about speed at the moment. You are lucky if you get your system solved and if the solution is as expected. A system of quadratic equations is a challenge.
If this works satisfactory, you can save time if you set the solution of the last call to the nonlinear solver to the initial guess of the next call (since you say that your coefficients vary slowly).
Michal
Michal el 1 de Nov. de 2024
Editada: Michal el 1 de Nov. de 2024
Yes... you are definitely right :)

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