Unable to find explicit solution in Lagrangian optimization

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Fabian
Fabian el 11 de Feb. de 2024
Comentada: Matt J el 11 de Feb. de 2024
I am trying to find the analytical solution to the following problem:
I tried solving it by coding the Lagrangian by hand and use solve, but Matlab prints the warning: "Unable to find explicit solution".
I used the following code:
syms e1 e2 p1 p2 rho gamma lambda
syms E H(e1,e2)
H(e1,e2) = (e1^rho +e2^rho)^(1/rho)
L(e1, e2, lambda) = p1*e1 +p2*e2 + lambda*(H(e1,e2)-E)
L_e1 = diff(L,e1) == 0
L_e2 = diff(L,e2) == 0
L_lambda = diff(L,lambda) == 0
system = [L_e1,L_e2,L_lambda]
[e1_s,e2_s,lambda_s]=solve(system,[e1 e2 lambda])
Do you know what I could do to solve this? Or is there a different and better way to find an analytical solution?
  1 comentario
Matt J
Matt J el 11 de Feb. de 2024
Editada: Matt J el 11 de Feb. de 2024
Note that the problem can always be rewritten in the simpler form,
where x=e/E and P=p*E. This is assuming E is a known positive constant.

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Catalytic
Catalytic el 11 de Feb. de 2024
Editada: Catalytic el 11 de Feb. de 2024
An analytical solution for 0<rho<1 is -
A=[1 0;
0 1;
-1 0;
0 -1]*E;
[fval,i]=min(A*[p1;p2]);
e1=A(i,1);
e2=A(i,2);
  2 comentarios
Catalytic
Catalytic el 11 de Feb. de 2024
Editada: Catalytic el 11 de Feb. de 2024
Ran in:
You can see this graphically by plotting the constrained region. The region always has extreme points at (), so that's where the optimum must lie.
E=1;
for rho=[0.1:0.2:0.9]
fimplicit(@(e1,e2) abs(e1).^rho + abs(e2).^rho - E.^rho, [-1.5,1.5]); hold on
end
Matt J
Matt J el 11 de Feb. de 2024
I like it. And, in fact, because the extreme points lie at points where H(e1,e2) is not differentiable, it shows that you will never find the true solution with Lagrange multiplier analysis.

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Más respuestas (1)

Matt J
Matt J el 11 de Feb. de 2024
Ran in:
If you make rho explicit, it seems to be able to find solutions. I doubt there would be a closed-form solution for general rho.
rho=2;
syms e1 e2 p1 p2 gamma lambda
syms E H(e1,e2)
H(e1,e2) = (e1^rho +e2^rho)
H(e1, e2) = 
L(e1, e2, lambda) = p1*e1 +p2*e2 + lambda*(H(e1,e2)-E^rho)
L(e1, e2, lambda) = 
L_e1 = diff(L,e1) == 0
L_e1(e1, e2, lambda) = 
L_e2 = diff(L,e2) == 0
L_e2(e1, e2, lambda) = 
L_lambda = diff(L,lambda) == 0
L_lambda(e1, e2, lambda) = 
system = [L_e1,L_e2,L_lambda]
system(e1, e2, lambda) = 
[e1_s,e2_s,lambda_s]=solve(system,[e1 e2 lambda])
e1_s = 
e2_s = 
lambda_s = 
  4 comentarios
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Matt J
Matt J el 11 de Feb. de 2024
Ran in:
Even when it can be explicitly solved, the result isn't nice:
rho=sym(1/4);
syms e1 e2 p1 p2 gamma lambda
syms H(e1,e2)
H(e1,e2) = (e1^rho +e2^rho);
L(e1, e2, lambda) = p1*e1 +p2*e2 + lambda*(H(e1,e2)-1);
L_e1 = diff(L,e1) == 0;
L_e2 = diff(L,e2) == 0;
L_lambda = diff(L,lambda) == 0;
system = [L_e1,L_e2,L_lambda];
[e1_s,e2_s,lambda_s]=solve(system,[e1 e2 lambda])
Warning: Possibly spurious solutions.
e1_s = 
e2_s = 
lambda_s = 
Walter Roberson
Walter Roberson el 11 de Feb. de 2024
Ran in:
You can eliminate the root() constructs, but the result is confusing.
rho=sym(1/4);
syms e1 e2 p1 p2 gamma lambda
syms H(e1,e2)
H(e1,e2) = (e1^rho +e2^rho);
L(e1, e2, lambda) = p1*e1 +p2*e2 + lambda*(H(e1,e2)-1);
L_e1 = diff(L,e1) == 0;
L_e2 = diff(L,e2) == 0;
L_lambda = diff(L,lambda) == 0;
system = [L_e1,L_e2,L_lambda];
[e1_s,e2_s,lambda_s]=solve(system,[e1 e2 lambda], 'maxdegree', 3)
Warning: Possibly spurious solutions.
e1_s = 
e2_s = 
lambda_s = 

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