#技术风云榜#基于非支配排序的多目标PSO算法MATLAB实现

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#技术风云榜#基于非支配排序的多目标PSO算法MATLAB实现
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/ ]7 C& t, B- m这一篇是Xue Bing在一区cybernetics发的论文，里面提出了两个多目标PSO特征选择算法，一个是NSPSO另一个是CMDPSO。
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具体流程

• ①划分数据集为测试集和训练集
• ②初始化PSO算法
• ③迭代开始
• ④计算两个目标值（论文中是特征数和错误率）
• ⑤非支配排序
• ⑥拥挤距离度量并排序
• ⑥对每个粒子从第一前沿面选择一个粒子作为gbest，更新当前粒子
• ⑦调整粒子群
• ⑧迭代结束返回
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! ~& s' V5 \2 u" @) H' m. o. ~& KMATLAB实现：
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注意其中FSKNN是我的问题的评价函数，包含两个目标值，都存入到pfitness中
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• function [solution,time,pop,pfitness,site,LeaderAVE] = NSPSO(train_F,train_L)
• tic
• global maxFES
• dim = size(train_F,2);
• FES = 1;
• sizep = 30;
• pop = rand(sizep,dim);
• popv = rand(sizep,dim);
• pfitness = zeros(sizep,2);
• LeaderAVE = zeros(1,2);
• while FES <maxFES
•     Off_P = zeros(sizep,dim);
•     Off_V = zeros(sizep,dim);
•     ofitness = zeros(sizep,2);
•     for i=1:sizep
•         [pfitness(i,1),pfitness(i,2)] = FSKNN(pop(i,：）,i,train_F,train_L);
•     end
•     Front = NDSort(pfitness(:,1:2),sizep);
•     [~,rank] = sortrows([Front',-CrowdingDistance(pfitness,Front)']);
•     LeaderSet = rank(1:10);
•     solution = pfitness(LeaderSet,：）;
•     LeaderAVE(1) = mean(solution(:,1));
•     LeaderAVE(2) = mean(solution(:,2));
•     for i = 1:sizep
•         good = LeaderSet(randperm(length(LeaderSet),1));
•         r1 = rand(1,dim);
•         r2 = rand(1,dim);
•         Off_V(i,：） = r1.*popv(i,：） +  r2.*(pop(good,：）-pop(i,：）);
•         Off_P(i,：） = pop(i,：） + Off_V(i,：）;
•     end
•     for i=1:sizep
•             [ofitness(i,1),ofitness(i,2)] = FSKNN(Off_P(i,：）,i,train_F,train_L);
•     end
•     temppop = [pop;Off_P];
•     tempv = [popv;Off_V];
•     tempfiness = [pfitness;ofitness];
•     [FrontNO,MaxFNO] = NDSort(tempfiness(:,1:2),sizep);
•     Next = false(1,length(FrontNO));
•     Next(FrontNO<MaxFNO) = true;
•     PopObj = tempfiness;
•     fmax   = max(PopObj(FrontNO==1,：）,[],1);
•     fmin   = min(PopObj(FrontNO==1,：）,[],1);
•     PopObj = (PopObj-repmat(fmin,size(PopObj,1),1))./repmat(fmax-fmin,size(PopObj,1),1);
•     % Select the solutions in the last front
•     Last = find(FrontNO==MaxFNO);
•     del  = Truncation(PopObj(Last,：）,length(Last)-sizep+sum(Next));
•     Next(Last(~del)) = true;
•     % Population for next generation
•     pop = temppop(Next,：）;
•     popv = tempv(Next,：）;
•     pfitness = tempfiness(Next,：）;
•     fprintf('GEN: %2d   Error: %.4f  F:%.2f\n',FES,LeaderAVE(1),LeaderAVE(2));
•     FES = FES + 1;
• end
• [FrontNO,~] = NDSort(pfitness(:,1:2),sizep);
• site = find(FrontNO==1);
• solution = pfitness(site,：）;
• LeaderAVE(1) = mean(solution(:,1));
• LeaderAVE(2) = mean(solution(:,2));
• toc
• time = toc;
• end
  

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• function CrowdDis = CrowdingDistance(PopObj,FrontNO)
• % Calculate the crowding distance of each solution front by front
• % Copyright 2015-2016 Ye Tian
•     [N,M]    = size(PopObj);
•     CrowdDis = zeros(1,N);
•     Fronts   = setdiff(unique(FrontNO),inf);
•     for f = 1 : length(Fronts)
•         Front = find(FrontNO==Fronts(f));
•         Fmax  = max(PopObj(Front,：）,[],1);
•         Fmin  = min(PopObj(Front,：）,[],1);
•         for i = 1 : M
•             [~,Rank] = sortrows(PopObj(Front,i));
•             CrowdDis(Front(Rank(1)))   = inf;
•             CrowdDis(Front(Rank(end))) = inf;
•             for j = 2 : length(Front)-1
•                 CrowdDis(Front(Rank(j))) = CrowdDis(Front(Rank(j)))+(PopObj(Front(Rank(j+1)),i)-PopObj(Front(Rank(j-1)),i))/(Fmax(i)-Fmin(i));
•             end
•         end
•     end
• end
  

9 g4 o* s+ h3 \- D& q5 I4 e    Truncation.m代码：

• function Del = Truncation(PopObj,K)
• % Select part of the solutions by truncation
•     N = size(PopObj,1);
•     %% Truncation
•     Distance = pdist2(PopObj,PopObj);
•     Distance(logical(eye(length(Distance)))) = inf;
•     Del = false(1,N);
•     while sum(Del) < K
•         Remain   = find(~Del);
•         Temp     = sort(Distance(Remain,Remain),2);
•         [~,Rank] = sortrows(Temp);
•         Del(Remain(Rank(1))) = true;
•     end
• end
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基于非支配排序的多目标PSO算法MATLAB实现