www.gusucode.com > MATLAB——三维空间映射源码程序 > MATLAB——三维空间映射源码程序/spMODE/spMODE.m
%% spMODEparam
% Generates the required parameters to run the spMODE optimization
% algorithm.
%
%%
%% Beta version
% Copyright 2006 - 2012 - CPOH
%
% Predictive Control and Heuristic Optimization Research Group
% http://cpoh.upv.es
%
% ai2 Institute
% http://www.ai2.upv.es
%
% Universitat Polit鑓nica de Val鑞cia - Spain.
% http://www.upv.es
%
%%
%% Author
% Gilberto Reynoso-Meza
% gilreyme@upv.es
% http://cpoh.upv.es/en/gilberto-reynoso-meza.html
% http://www.mathworks.es/matlabcentral/fileexchange/authors/289050
%%
%% For new releases and bug fixing of this Tool Set please visit:
% 1) http://cpoh.upv.es/en/research/software.html
% 2) Matlab Central File Exchange
%%
%% Overall Description
% This code implements a version of the multi-objective differential
% evolution algorithm with spherical pruning described in:
%
% Gilberto Reynoso-Meza, Javier Sanchis, Xavier Blasco, Miguel Mart韓ez.
% Design of Continuous Controllers Using a Multiobjective Differential
% Evolution Algorithm with Spherical Pruning. Applications of Evolutionary
% Computation. LNCS Volume 6024, 2010, pp 532-541.
%
%% Main Function
function OUT=spMODE(spMODEDat)
%% Reading variables form spMODEDat
Generations = spMODEDat.MAXGEN; % Generations.
Xpop = spMODEDat.Xpop; % Population size.
SubXpop = spMODEDat.SubXpop; % SubPopulation Size.
Obj = spMODEDat.NOBJ; % Number of objectives.
Nvar = spMODEDat.NVAR; % Number of decision variables.
Limits = spMODEDat.FieldD; % Optimization Limits.
Initial = spMODEDat.Initial; % Initialization Limits.
ScalingFactor = spMODEDat.ScalingFactor;% Scaling Factor
CRrate = spMODEDat.CRrate; % Crossover rate
Strategy = spMODEDat.Strategy; % Strategy to prune
mop = spMODEDat.mop; % CostFunction
OUT.Ini = datestr(now);
%% Population initialization
Parent = zeros(Xpop, Nvar);
for xpop=1:Xpop %Uniform distribution
for nvar=1:Nvar
Parent(xpop,nvar) = Initial(nvar,1) + ...
(Initial(nvar,2) - Initial(nvar,1))*rand();
end
end
[JxParent Parent] = mop(Parent,spMODEDat); %Calling CostFunction.m
FES = Xpop; % Function Evaluations
PFront = JxParent; % The approximated Pareto Front
PSet = Parent; % The approximated Pareto Set
if size(spMODEDat.PobInitial,1) >= 1 % If we include members in the Pop.
InitialPS = spMODEDat.PobInitial;
InitialPF = mop(InitialPS,spMODEDat);
FES=FES+size(spMODEDat.PobInitial,1);
[PFront PSet spMODEDat] = ...
Dominance([PFront;InitialPF],[PSet;InitialPS],spMODEDat);
% Calling Dominance Filter
else
[PFront PSet spMODEDat]=Dominance(PFront,PSet,spMODEDat);
%Calling Dominance Filter
end
if size(PFront,1)>1
spMODEDat.ExtremesPFront=[max(PFront);min(PFront)]; % Extremes
end
[AnchorsY, AnchorsX] = Look4Anchors(PFront,PSet); % Anchor points
spMODEDat.AnchorsY = AnchorsY;
spMODEDat.AnchorsX = AnchorsX;
%% Evolutionary Process
SubParent = zeros(SubXpop,Nvar);
JxSubParent = zeros(SubXpop,Obj);
for n=1:Generations
%% Selection of subpopulation
revSubXpop=randperm(Xpop);
refPFront=randperm(size(PFront,1));
if strcmp(Strategy,'Push')
Elite=0;
else
Elite=spMODEDat.CarElite+size(AnchorsX,1); % Anchor points are
% always used in the
% evolutionary process
end
SizeOld=0;
if size(PFront,1)+size(AnchorsX,1) < Elite % If we have too few Pareto
% optimal points.
for subxpop=1:SubXpop-size(PFront,1)-size(AnchorsX,1)
SubParent(subxpop,:)=Parent(revSubXpop(1,subxpop),:);
JxSubParent(subxpop,:)=JxParent(revSubXpop(1,subxpop),:);
end
SubParent(SubXpop-size(PFront,1)-size(AnchorsX)+1:SubXpop,:) = ...
[AnchorsX;PSet];
JxSubParent(SubXpop-size(PFront,1)-size(AnchorsX)+1:SubXpop,:)= ...
[AnchorsY;PFront];
SizeOld=size(PFront,1)+size(AnchorsX,1);
elseif size(PFront,1)+size(AnchorsX,1) >= Elite % If we have several
% Pareto optimal
% solutions, we select
% a few of them.
for subxpop=1:SubXpop-Elite
SubParent(subxpop,:)=Parent(revSubXpop(1,subxpop),:);
JxSubParent(subxpop,:)=JxParent(revSubXpop(1,subxpop),:);
end
for subxpop=SubXpop-Elite+1:SubXpop-size(AnchorsX,1)
SubParent(subxpop,:)=PSet(refPFront(1,subxpop-Elite),:);
JxSubParent(subxpop,:)=PFront(refPFront(1,subxpop-Elite),:);
end
SubParent(SubXpop-size(AnchorsX,1)+1:end,:) = AnchorsX;
JxSubParent(SubXpop-size(AnchorsX,1)+1:end,:) = AnchorsY;
% Anchor points are always used in the optimization process!
elseif Elite==0 % If spMODEDat.Strategy=='Push' (Basic MODE)
for subxpop=1:SubXpop
SubParent(subxpop,:)=Parent(revSubXpop(1,subxpop),:);
JxSubParent(subxpop,:)=JxParent(revSubXpop(1,subxpop),:);
end
end
Mutant = zeros(SubXpop, Nvar);
Child = zeros(SubXpop, Nvar);
JxChild = zeros(SubXpop,Obj);
%% Differential Evolution algorithm
for subxpop=1:SubXpop
rev = randperm(SubXpop);
Mutant(subxpop,:) = SubParent(rev(1,1),:) + ...
ScalingFactor*(SubParent(rev(1,2),:)-SubParent(rev(1,3),:));
for nvar=1:Nvar % Bounds are always preserved.
if Mutant(subxpop,nvar) < Limits(nvar,1)
Mutant(subxpop,nvar) = Limits(nvar,1);
elseif Mutant(subxpop,nvar) > Limits(nvar,2)
Mutant(subxpop,nvar) = Limits(nvar,2);
end
end
flagCr=0; %Counter for 緾hild == Parent?
if Nvar > 1
for j=1:Nvar
if rand() > CRrate
Child(subxpop,j) = SubParent(subxpop,j);
else
Child(subxpop,j) = Mutant(subxpop,j);
flagCr=1;
end
end
end
if flagCr==0 % IF Child == Parent, we take at least one decision
% variable from the mutant.
revCr=randperm(Nvar);
Child(subxpop,revCr(1,1)) = Mutant(subxpop,revCr(1,1));
end
for nvar=1:Nvar % Bounds are always preserved.
if Child(subxpop,nvar) < Limits(nvar,1)
Child(subxpop,nvar) = Limits(nvar,1);
elseif Child(subxpop,nvar) > Limits(nvar,2)
Child(subxpop,nvar) = Limits(nvar,2);
end
end
[JxChild(subxpop,:) Child(subxpop,:)] = ...
mop(Child(subxpop,:),spMODEDat); %We evaluate the child
FES=FES+1;
end
for subxpop=1:SubXpop % Pure dominance is used for selection process.
if JxChild(subxpop,:) <= JxSubParent(subxpop,:)
SubParent(subxpop,:) = Child(subxpop,:);
JxSubParent(subxpop,:) = JxChild(subxpop,:);
end
end
[PFront,PSet] = ... % Dominance Filter.
Dominance([PFront; JxChild],[PSet; Child],spMODEDat);
[AnchorsY, AnchorsX] = ... % Updating Anchors.
Look4Anchors([AnchorsY;PFront],[AnchorsX;PSet]);
spMODEDat.AnchorsY = AnchorsY;
spMODEDat.AnchorsX = AnchorsX;
if SizeOld>0 % Updating Population with new subpopulation
for subxpop=1:SubXpop-SizeOld
Parent(revSubXpop(1,subxpop),:)=SubParent(subxpop,:);
JxParent(revSubXpop(1,subxpop),:)=JxSubParent(subxpop,:);
end
elseif SizeOld==0 && Elite>0
for subxpop=1:SubXpop-Elite
Parent(revSubXpop(1,subxpop),:)=SubParent(subxpop,:);
JxParent(revSubXpop(1,subxpop),:)=JxSubParent(subxpop,:);
end
elseif Elite==0
for subxpop=1:SubXpop
Parent(revSubXpop(1,subxpop),:)=SubParent(subxpop,:);
JxParent(revSubXpop(1,subxpop),:)=JxSubParent(subxpop,:);
end
end
if strcmp(Strategy,'SphP') %Noting to prune in a basic MODE
[PFront PSet spMODEDat] = SphPruning(PFront,PSet,spMODEDat);
elseif strcmp(Strategy,'Push') % Spherical Pruning
PFront = JxParent;
PSet = SubParent;
end
if size(PFront,1)>spMODEDat.StopSize
disp('Maximum number of solutions exceeded!')
break;
end
% Updating output results
OUT.PSet = PSet;
OUT.PFront = PFront;
OUT.SubParent = SubParent;
OUT.Parent = Parent;
OUT.JxParent = JxParent;
OUT.JxSubParent = JxSubParent;
% Updating counter
spMODEDat.CounterGEN = n;
spMODEDat.CounterFES = FES;
% Displaying information
[OUT spMODEDat]=PrinterDisplay(OUT,spMODEDat);
if FES>spMODEDat.MAXFUNEVALS || n>spMODEDat.MAXGEN
disp('Finish.')
break;
end
end
if strcmp(Strategy,'Push')
[PFront PSet spMODEDat] = Dominance(PFront,PSet,spMODEDat);
end
% Updating output results
OUT.PSet = PSet;
OUT.PFront = PFront;
OUT.SubParent = SubParent;
OUT.Parent = Parent;
OUT.JxParent = JxParent;
OUT.JxSubParent = JxSubParent;
OUT.Param = spMODEDat;
OUT.Fin = datestr(now);
if strcmp(spMODEDat.SaveResults,'yes')
save(['OUT_spMODE_' datestr(now,30)],'OUT'); %Results are saved
end
disp('+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++')
if strcmp(spMODEDat.SaveResults,'yes')
disp(['Check out OUT_' datestr(now,30) ...
' variable on folder for results.'])
end
disp('+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++')
%% Looking for Anchor points
function [AnchorsY, AnchorsX]=Look4Anchors(Y,X)
Xpop=size(Y,1);
Nobj=size(Y,2);
Nvar=size(X,2);
AnchorsX=zeros(Nobj,Nvar);
AnchorsY=zeros(Nobj,Nobj);
if size(Y,1)==1
Jideal=Y;
else
Jideal=min(Y);
end
for nobj=1:Nobj
Habemus=0;
for xpop=1:Xpop
if Habemus==0
if Y(xpop,nobj)==Jideal(1,nobj)
AnchorsY(nobj,:)=Y(xpop,:);
AnchorsX(nobj,:)=X(xpop,:);
Habemus=1;
end
elseif Habemus==1
if Y(xpop,nobj)==AnchorsY(nobj,nobj)
if Y(xpop,:)<=AnchorsY(nobj,:)
AnchorsY(nobj,:)=Y(xpop,:);
AnchorsX(nobj,:)=X(xpop,:);
end
end
end
end
end
%% Dominance Filter
function [PFront PSet Dat]=Dominance(F,C,Dat)
Xpop=size(F,1);
Nobj=Dat.NOBJ;
Nvar=size(C,2);
PFront=zeros(Xpop,Nobj);
PSet=zeros(Xpop,Nvar);
k=0;
for xpop=1:Xpop
Dominado=0;
for compare=1:Xpop
if F(xpop,:)==F(compare,:)
if xpop > compare
Dominado=1;
break;
end
else
if F(xpop,:)>=F(compare,:)
Dominado=1;
break;
end
end
end
if Dominado==0
k=k+1;
PFront(k,:)=F(xpop,:);
PSet(k,:)=C(xpop,:);
end
end
PFront=PFront(1:k,:);
PSet=PSet(1:k,:);
Ordena =sortrows([PFront PSet],[Nobj+1:Nobj 1:Nobj]);
PFront = Ordena(:,1:Nobj);
PSet = Ordena(:,Nobj+1:Nobj+Nvar);
%% Printer Display
function [OUT Dat]=PrinterDisplay(OUT,Dat)
if strcmp(Dat.SeeProgress,'yes')
disp('------------------------------------------------')
disp(['Generation: ' num2str(Dat.CounterGEN)]);
disp(['Evaluations: ' num2str(Dat.CounterFES)]);
disp(['Front size: ' mat2str(size(OUT.PFront,1))]);
disp(['Minimum values: ' num2str(min(Dat.AnchorsY))]);
disp('------------------------------------------------')
end
if strcmp(Dat.Plotter,'yes')
F=[OUT.PFront;Dat.AnchorsY];
if Dat.NOBJ==2
plot(OUT.PFront(:,1),OUT.PFront(:,2),'dr'); grid on;
pause(0.01)
elseif Dat.NOBJ==3
plot3(F(:,1),F(:,2),F(:,3),'dr'); grid on;
pause(0.01)
end
end
%%
%% Release and bug report:
%
% November 2012: Initial release