Sign of lambda.eqlin

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Aidan
Aidan el 14 de Nov. de 2025 a las 18:06
Editada: David Goodmanson el 15 de Nov. de 2025 a las 20:35
I am trying to understand the sign of the lambdas for my equality constraints - and can't seem to find how this is encoded in the documentation.
My assumption is that Aeq*x = beq is encoded either:
transpose(lambda) * (Aeq * x - b)
OR
transpose(lambda) * (b - Aeq * x)
Can someone help me confirm? Or show me a way I could check?
Thank you!!
  1 comentario
Walter Roberson
Walter Roberson el 14 de Nov. de 2025 a las 19:33
Does it matter? Those details are handled internally, in code that you have no access to

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Respuestas (2)

William Rose
William Rose el 14 de Nov. de 2025 a las 20:03
Editada: William Rose el 15 de Nov. de 2025 a las 1:42
Ran in:
@Aidan,
[edit: fix typos; code not affected]
[Edit 2: Fix errors in code which @David Goodmanson pointed out - thank you. Conclusion is not changed.]
It seems that lambda is used as follows:
I say this because I used fmincon to minimize a constrained function, and then I evaluated the derivatives of the Lagrangian defined both ways:
and
The derivatives of the Lagrangian with respect to x1, x2, ..., and λ should equal zero at the minimum. They do for Lplus, but not for Lminus.
See script below. In this script,
f(x)=x1^2+x2^2
i.e. f(x)=paraboloid with a minimum at x1=x2=0. The constraint is
x1+x2=1
i.e. a line with slope -45 degrees which goes through x=(1,0) and x=(0,1).
% Define constants
x0=[2,2]; % initial guess
Aeq=[1,1]; % equality constraint
beq=1; % equality constraint
% Next: minimize function subject to constraint
[x,fval,~,~,lambda,grad,hessn] = fmincon(@myfun,x0,[],[],Aeq,beq);
Local minimum found that satisfies the constraints. Optimization completed because the objective function is non-decreasing in feasible directions, to within the value of the optimality tolerance, and constraints are satisfied to within the value of the constraint tolerance.
L=lambda.eqlin; % lambda at solution point
% Display results of minimization
fprintf('x1=%.3f, x2=%.3f, f(x)=%.3f, λ=%.3f.\n',x,fval,L)
x1=0.500, x2=0.500, f(x)=0.500, λ=-1.000.
% Display derivatives with respect to x1, x2, λ
fprintf('d(LaGr+)/dx1=%.3f\n',(LaGrPlus(x+[.001,0],L,Aeq,beq)-LaGrPlus(x,L,Aeq,beq))/.001)
d(LaGr+)/dx1=0.001
fprintf('d(LaGr+)/dx2=%.3f\n',(LaGrPlus(x+[0,.001],L,Aeq,beq)-LaGrPlus(x,L,Aeq,beq))/.001)
d(LaGr+)/dx2=0.001
fprintf('d(LaGr+)/dλ=%.3f\n',(LaGrPlus(x,L+.001,Aeq,beq)-LaGrPlus(x,L,Aeq,beq))/.001)
d(LaGr+)/dλ=0.000
fprintf('d(LaGr-)/dx1=%.3f\n',(LaGrMinus(x+[.001,0],L,Aeq,beq)-LaGrMinus(x,L,Aeq,beq))/.001)
d(LaGr-)/dx1=2.001
fprintf('d(LaGr-)/dx2=%.3f\n',(LaGrMinus(x+[0,.001],L,Aeq,beq)-LaGrMinus(x,L,Aeq,beq))/.001)
d(LaGr-)/dx2=2.001
fprintf('d(LaGr-)/dλ=%.3f\n',(LaGrMinus(x,L+.001,Aeq,beq)-LaGrMinus(x,L,Aeq,beq))/.001)
d(LaGr-)/dλ=0.000
function f=myfun(x)
f=norm(x)^2;
end
function y=LaGrPlus(x,lambda,Aeq,beq)
y=myfun(x)+lambda*(Aeq*x'-beq);
end
function y=LaGrMinus(x,lambda,Aeq,beq)
y=myfun(x)-lambda*(Aeq*x'-beq);
end
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David Goodmanson
David Goodmanson el 14 de Nov. de 2025 a las 23:26
Hi William,
in your last three fprintf lines you have, e.g.
(LaGrMinus(x+[.001,0],L,Aeq,beq)-LaGrPlus(x,L,Aeq,beq))/.001)
instead of
(LaGrMinus(x+[.001,0],L,Aeq,beq)-LaGrMinus(x,L,Aeq,beq))/.001)
^
William Rose
William Rose el 15 de Nov. de 2025 a las 1:43
Editada: William Rose el 15 de Nov. de 2025 a las 1:45
@David Goodmanson, thank you for pointing out the error in my code. I have fixed it above now. The conclusion is not altered.

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David Goodmanson
David Goodmanson el 15 de Nov. de 2025 a las 0:13
Editada: David Goodmanson el 15 de Nov. de 2025 a las 20:35
Hi Aiden,
William's example is
f(x) = x^2+y^2 Aeq=[1,1] beq = 1
L(x,lambda) = f(x) + lambda*(Aeq*x'-beq) % convention is plus sign on second term.
Using the the ancient technique of pencil and paper I came up with lambda = -1, which is what fmincon produces.
So (Aeq*x-beq) appears to be the correct form.
It's consistent with what Matt suggested and WIlliam has.

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