fmincon nonlinear constrain problem set-up

5 visualizzazioni (ultimi 30 giorni)
Alec Jeffery
Alec Jeffery il 18 Ago 2016
Modificato: Matt J il 19 Ago 2016
One of my initial conditions is leaving me scratching my head. Since R & C are defined by summing functions (R will have w components and C will have d components), it may be simpliest to represent R & C as functions. Since there is a function f embedded in R, I run in to problems. I can see how to establish the A,b,Aeq and beq inputs, but I have no clue how to represent the nonlinear constraint of f and pass it in to R. Any help would be much appreciated.
P=R-C; % Objective Function
-P <= 0;
R= sum(U*f(sum(sqrt(((Xb+X)-Xw)^2)));
C= sum(Md*(X-Xb)+B);
f=@d h*exp(1/d);

Accedi per rispondere a questa domanda.

Risposta accettata

Matt J
Matt J il 18 Ago 2016
Modificato: Matt J il 18 Ago 2016
Something like the following, perhaps?
Pfun=@(X) objectiveFull(X, Xb,Xw, U Md,B,h);
nonlcon=@(X) nonlconFull(X,Pfun);
Xopt = fmincon(Pfun,X0, A,b,Aeq,beq,[],[],nonlcon)
function P=objectiveFull(X,Xb,Xw, U Md,B,h)
f=@(d) h*exp(1/d);
R= sum(U*f( norm(X-(Xw-Sb) ) ) );
C= sum(Md*(X-Xb)+B);
P=R-C;
function [c,ceq]=nonlconFull(X,Pfun)
ceq=[];
c=-Pfun(X);
  3 Commenti
Mostra 1 commento meno recente
Alec Jeffery
Alec Jeffery il 19 Ago 2016
Modificato: Matt J il 19 Ago 2016
Great suggestions. I ended up using your nested functions with some modifications (code below). I changed the sign on the constraint function and the objective function. The results seem to be what I want.
% X=x
% Xb=tempBeePos
% Xw=tempWalkerPos
% U=UnitRewards;
% M=BeeAdj(:,1)
% B=BeeAdj(:,2)
% DistRewardFunc
function [Profit,Xopt]=newOptiCode(tempBeePos,tempWalkerPos,UnitRewards,BeeAdj,DistRewardFunc)
M=BeeAdj(:,1);
B=BeeAdj(:,2);
Pfun=@(x) -objectiveFull(x,tempBeePos,tempWalkerPos,UnitRewards,M,B,DistRewardFunc);
% Threw a '-' before function so that you are finding the minimum of -Max
nonlcon=@(x) nonlconFull(x,Pfun);
options = optimoptions('fmincon','Display','off');
Xopt = fmincon(Pfun,tempBeePos, [],[],[],[],[],[],nonlcon,options);
% Xopt = fmincon(Pfun,tempBeePos, A,b,Aeq,beq,[],[],nonlcon)
function P=objectiveFull(x,tempBeePos,tempWalkerPos,UnitRewards,M,B,DistRewardFunc)
R=[];
for w=1:size(tempWalkerPos,1)
f=DistRewardFunc{w};
BWdist=sum(sqrt(((tempBeePos+x)-tempWalkerPos(w,:)).^2));
R(w,1)=UnitRewards(w)*f(BWdist);
end
R=sum(R);
% R= sum(U*f( norm(X-(Xw-Xb) ) ) );
% C= sum(Md*(X-Xb)+B);
C=[];
for d=1:size(tempBeePos,2)
if x(d) > 0;
C(d,1)=M(d)*(x(d)-tempBeePos(d))+B(d);
else
C(d,1)=B(d);
end
end
C=sum(C);
P=R-C;
end
function [c,ceq]=nonlconFull(x,Pfun)
ceq=[];
c=Pfun(x);
% changed the sign on c=-Pfun(x)
end
Profit=objectiveFull(Xopt,tempBeePos,tempWalkerPos,UnitRewards,M,B,DistRewardFunc);
end
Matt J
Matt J il 19 Ago 2016
Modificato: Matt J il 19 Ago 2016
Glad it worked out, but the purpose of my suggestion to use nested functions was to spare you the long argument lists. Below, the nested functions Pfun and nonlcon both share access to the workspace of newOptiCode, so there is no longer any need to pass extra arguments to them (like tempWalkerPos, etc...).
function [Profit,Xopt]=newOptiCode(tempBeePos,tempWalkerPos,...
UnitRewards,BeeAdj,DistRewardFunc)
M=BeeAdj(:,1);
B=BeeAdj(:,2);
Xopt = fmincon(@(x) -Pfun(x),tempBeePos, [],[],[],[],...
[],[],@nonlcon,options);
Profit=Pfun(Xopt);
function P=Pfun(x)
R=[];
for w=1:size(tempWalkerPos,1)
f=DistRewardFunc{w};
BWdist=sum(sqrt(((tempBeePos+x)-tempWalkerPos(w,:)).^2));
R(w,1)=UnitRewards(w)*f(BWdist);
end
R=sum(R);
% R= sum(U*f( norm(X-(Xw-Xb) ) ) );
% C= sum(Md*(X-Xb)+B);
C=[];
for d=1:size(tempBeePos,2)
if x(d) > 0;
C(d,1)=M(d)*(x(d)-tempBeePos(d))+B(d);
else
C(d,1)=B(d);
end
end
C=sum(C);
P=R-C;
end
function [c,ceq]=nonlcon(x)
ceq=[];
c=-Pfun(x);
% changed the sign on c=-Pfun(x)
end
end

Accedi per commentare.

Più risposte (0)

Categorie

Scopri di più su Surrogate Optimization in Help Center e File Exchange

Tag

Community Treasure Hunt

Find the treasures in MATLAB Central and discover how the community can help you!

Start Hunting!

Translated by