LS-SVMLab-v1.7(R2006a-R2009a).rar_LSSVMC++_LSSVM仿真_lssvmc

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LS-SVMLab-v1.7(R2006a-R2009a) 是一个基于C++和MATLAB的库，专门用于支持向量机（Support Vector Machine, SVM）的实现，特别是线性可分支持向量机（Linearly Separable Support Vector Machine, LSSVM）。这个库支持R2006a到R2009a版本的MATLAB，覆盖了多个MATLAB版本，展示了其兼容性和持久性。LSSVM是一种在机器学习领域广泛应用的监督学习模型，它主要用于分类和回归任务。 LSSVM的基本原理是将数据映射到高维空间，寻找一个超平面，使得不同类别的数据点在这个超平面上有最大的间隔。LSSVM的核心在于它的优化问题，即最小化训练误差和惩罚项的组合，这个优化问题可以通过拉格朗日乘子法转换为求解一个凸二次规划问题。在LSSVM中，线性不可分的数据可以被非线性映射到高维，使得在新的空间里变得线性可分。 LS-SVMLab库提供了C++接口，使得用户能够高效地在C++环境中进行LSSVM的计算，这对于大规模数据集的处理尤为重要，因为C++通常比MATLAB更高效。同时，MATLAB接口使得用户能够利用其丰富的图形界面和数据分析工具，方便地进行模型的构建、训练和验证。在MATLAB环境中，LSSVM仿真通常包括以下步骤： 1. 数据预处理：收集和清洗数据，可能需要进行归一化或标准化操作，以便于模型训练。 2. 模型训练：选择合适的核函数（如线性、多项式、高斯等），设置参数（如正则化参数C和核函数的宽度γ），用LSSVMLab库训练模型。 3. 模型评估：使用交叉验证或其他方法评估模型的性能，例如准确率、精确率、召回率、F1分数等。 4. 预测与应用：将训练好的模型应用于新数据，进行预测，并分析结果。此压缩包中的文件很可能是LSSVMLab库的源代码、MATLAB接口文件、示例代码、用户手册等资源。通过这些资源，用户不仅可以了解LSSVM的基本理论，还能学习如何在实际项目中应用LSSVM进行数据预测和挖掘。在使用LSSVMLab时，需要注意以下几点： - 参数调优：LSSVM的性能很大程度上取决于参数的选择，需要通过网格搜索或其他优化方法找到最优参数组合。 - 计算效率：对于大数据集，要关注模型训练的时间复杂度，可能需要使用SVM的近似算法或分布式计算。 - 过拟合与欠拟合：要监控训练和验证集的性能，防止模型过于复杂导致过拟合，或者过于简单导致欠拟合。 LS-SVMLab是一个强大的工具，它使得研究人员和工程师能够方便地利用LSSVM技术进行数据预测和挖掘。通过理解和应用这个库，用户可以深入理解SVM的原理，并将其应用于实际的机器学习问题中。

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LS-SVMLab-v1.7(R2006a-R2009a).rar （80个子文件）

LS-SVMLab v1.7(R2006a-R2009a)

tunelssvm.m 22KB

postlssvm.m 5KB

mse.m 285B

code_MOC.m 550B

simlssvm.m 6KB

crossvalidatelssvm.m 4KB

lssvm.m 2KB

tbform.m 2KB

misclass.m 693B

windowizeNARX.m 2KB

gcrossvalidate.m 3KB

code_OneVsOne.m 579B

crossvalidate.m 5KB

simplex.m 10KB

gridsearch.m 7KB

cilssvm.m 4KB

gcrossvalidatelssvm.m 2KB

medae.m 311B

prelssvm.m 6KB

windowize.m 2KB

progress.m 1KB

bay_rr.m 4KB

range.m 173B

predict.m 3KB

denoise_kpca.m 4KB

latentlssvm.m 2KB

rsimplex.m 10KB

preimage_rbf.m 4KB

robustlssvm.m 3KB

plotlssvm.m 10KB

demo_fixedclass.m 2KB

trainlssvm.m 9KB

linesearch.m 4KB

smootherlssvm.m 1KB

leaveoneout.m 4KB

ridgeregress.m 1KB

codedist_loss.m 2KB

demofun.m 4KB

simann.m 6KB

initlssvm.m 3KB

MLP_kernel.m 608B

demo_fixedsize.m 3KB

demomodel.m 5KB

eign.m 4KB

bay_errorbar.m 6KB

bay_modoutClass.m 9KB

demo_yinyang.m 3KB

kpca.m 6KB

codelssvm.m 4KB

changelssvm.m 5KB

codedist_hamming.m 756B

demomulticlass.m 2KB

AFEm.m 3KB

bay_lssvm.m 10KB

RBF_kernel.m 1KB

democonfint.m 2KB

codedist_bay.m 2KB

linf.m 313B

kernel_matrix.m 3KB

kentropy.m 2KB

lin_kernel.m 531B

poly_kernel.m 623B

democlass.m 3KB

bay_initlssvm.m 2KB

csa.m 3KB

leaveoneoutlssvm.m 2KB

bay_optimize.m 6KB

trimmedmse.m 2KB

ripley.mat 4KB

rcrossvalidatelssvm.m 4KB

kernel_matrix2.m 477B

code_ECOC.m 5KB

weightingscheme.m 794B

rcrossvalidate.m 6KB

code_OneVsAll.m 364B

roc.m 7KB

predlssvm.m 5KB

lssvmMATLAB.m 2KB

code.m 4KB

bay_lssvmARD.m 8KB

function [model,cost,O3] = tunelssvm(model, varargin) % Tune the hyperparameters of the model with respect to the given performance measure % % 1. Using the functional interface: % % >> [gam, sig2, cost] = tunelssvm({X,Y,type,[],[],kernel,preprocess}, optfun, costfun, costargs) % % Outputs % gam : Optimal regularization parameter % sig2 : Optimal kernel parameter(s) % cost(*) : Estimated cost of the optimal hyperparameters % Inputs % X : N x d matrix with the inputs of the training data % Y : N x 1 vector with the outputs of the training data % type : 'function estimation' ('f') or 'classifier' ('c') % kernel(*) : Kernel type (by default 'RBF_kernel') % preprocess(*) : 'preprocess'(*) or 'original' % optfun : Optimization function: 'simplex' or 'gridsearch' % costfun : Function estimating the cost-criterion: 'crossvalidatelssvm', 'leaveoneoutlssvm', 'gcrossvalidatelssvm' % costargs(*) : Cell with extra cost function arguments % % 2. Using the object oriented interface: % % >> model = tunelssvm(model, optfun, costfun, costargs) % % Outputs % model : Object oriented representation of the LS-SVM model with optimal hyperparameters % Inputs % model : Object oriented representation of the LS-SVM model with initial hyperparameters % optfun(*) : Optimization function (by default 'gridsearch') % costfun : Function estimating the cost-criterion: 'crossvalidatelssvm', 'leaveoneoutlssvm', 'gcrossvalidatelssvm' % optfun(*) : Cell with extra cost function arguments % % See also: % trainlssvm, crossvalidate, gridsearch, linesearch, simplex, csa % Copyright (c) 2010, KULeuven-ESAT-SCD, License & help @ http://www.esat.kuleuven.ac.be/sista/lssvmlab % % initiate variables % if iscell(model), model = initlssvm(model{:}); func=1; else func=0; end % % defaults % if length(varargin)>=1, optfun = varargin{1}; else optfun='gridsearch';end if length(varargin)>=2, costfun = varargin{2}; else costfun ='crossvalidatelssvm'; end if length(varargin)>=3, costargs = varargin{3}; else costargs ={}; end if strcmp(costfun,'crossvalidatelssvm') || strcmp(costfun,'rcrossvalidatelssvm') || strcmp(costfun,'crossvalidatesparselssvm') if size(costargs,2)==1, error('Specify the number of folds for CV'); end [Y,omega] = helpkernel(model.xtrain,model.ytrain,model.kernel_type,costargs{2},0); costargs = {Y,costargs{1},omega,costargs{2}}; end if strcmp(costfun,'crossvalidate2lp1') fprintf('\n') disp('-->> Cross-Validation for Correlated Errors: Determine optimal ''l'' for leave (2l+1) out CV') % if user specifies 'l' if numel(costargs)==1, luser = NaN; else luser = costargs{2};end [l,index] = cvl(model.xtrain,model.ytrain,luser); % First determine the 'l' for the CV fprintf(['\n -->> Optimal l = ' num2str(l)]); fprintf('\n') [Y,omega] = helpkernel(model.xtrain,model.ytrain,model.kernel_type,[],1); costargs = {Y,index,omega,costargs{1}}; end if strcmp(costfun,'gcrossvalidatelssvm') || strcmp(costfun,'leaveoneoutlssvm') [Y,omega] = helpkernel(model.xtrain,model.ytrain,model.kernel_type,[],0); costargs = {Y,omega,costargs{1}}; end if strcmp(costfun,'rcrossvalidatelssvm') eval('model.weights = varargin{4};','model.weights = ''wmyriad''; ') end % if strcmp(costfun,'crossvalidatelssvm_SIM') % [Y,omega] = helpkernel(model.xtrain,model.ytrain,model.kernel_type,[],1); % costargs = {model.xtrain,Y,costargs{1},omega,costargs{2}}; % end % change the coding type for multiclass and set default 'OneVsOne' if no % coding type specified %if length(varargin)>=5 && ~isempty(varargin{5}) if model.type(1) =='c' && ~(sum(unique(model.ytrain))==1 || sum(unique(model.ytrain))==0) eval('coding = varargin{4};','coding = ''code_OneVsOne''; ') varargin{5}= coding; model = changelssvm(model,'codetype',coding); [yc,cb,oldcb] = code(model.ytrain,coding); y_dimold = model.y_dim; model.ytrain = yc; model.y_dim = size(yc,2); varargin{end} = []; clear yc end % % multiple outputs if (model.y_dim>1)% & (size(model.kernel_pars,1)==model.y_dim |size(model.gam,1)==model.y_dim |prod(size(model.kernel_type,1))==model.y_dim)) disp('-->> tune individual outputs'); if model.type(1) == 'c' fprintf('\n') disp(['-->> Encoding scheme: ',coding]); end costs = zeros(model.y_dim,1); gamt = zeros(1,model.y_dim); for d=1:model.y_dim, sel = ~isnan(model.ytrain(:,d)); fprintf(['\n\n -> dim ' num2str(d) '/' num2str(model.y_dim) ':\n']); try kernel = model.kernel_type{d}; catch, kernel=model.kernel_type;end [g,s,c] = tunelssvm({model.xtrain(sel,:),model.ytrain(sel,d),model.type,[],[],kernel,'original'},varargin{:}); gamt(:,d) = g; try kernel_part(:,d) = s; catch, kernel_part = [];end costs(d) = c; end model.gam = gamt; model.kernel_pars = kernel_part; if func, O3 = costs; cost = model.kernel_pars; model = model.gam; end % decode to the original model.yfull try if model.code(1) == 'c'; % changed model.ytrain = code(model.ytrain, oldcb, [], cb, 'codedist_hamming'); model.y_dim = y_dimold; end end return end %-------------------------------------------------------------------------% if strcmp(model.kernel_type,'lin_kernel'), if ~strcmp(model.weights,'wmyriad') && ~strcmp(model.weights,'whuber') [par,fval] = csa(rand(1,5),@(x)simanncostfun1(x,model,costfun,costargs)); else [par,fval] = csa(rand(2,5),@(x)simanncostfun1(x,model,costfun,costargs)); model.delta = exp(par(2)); end model = changelssvm(changelssvm(model,'gam',exp(par(1))),'kernel_pars',[]); clear par fprintf('\n') disp([' 1. Coupled Simulated Annealing results: [gam] ' num2str(model.gam)]); disp([' F(X)= ' num2str(fval)]); disp(' ') elseif strcmp(model.kernel_type,'RBF_kernel'), if ~strcmp(model.weights,'wmyriad') && ~strcmp(model.weights,'whuber') [par,fval] = csa(rand(2,5),@(x)simanncostfun2(x,model,costfun,costargs)); else [par,fval] = csa(rand(3,5),@(x)simanncostfun2(x,model,costfun,costargs)); model.delta = exp(par(3)); end model = changelssvm(changelssvm(model,'gam',exp(par(1))),'kernel_pars',exp(par(2))); fprintf('\n') disp([' 1. Coupled Simulated Annealing results: [gam] ' num2str(model.gam)]); disp([' [sig2] ' num2str(model.kernel_pars)]); disp([' F(X)= ' num2str(fval)]); disp(' ') elseif strcmp(model.kernel_type,'poly_kernel'), warning off if ~strcmp(model.weights,'wmyriad') && ~strcmp(model.weights,'whuber') [par,fval] = simann(@(x)simanncostfun3(x,model,costfun,costargs),[0.5;0.5;1],[-5;0.1;1],[10;3;1.9459],1,0.9,5,20,2); else [par,fval] = simann(@(x)simanncostfun3(x,model,costfun,costargs),[0.5;0.5;1;0.2],[-5;0.1;1;eps],[10;3;1.9459;1.5],1,0.9,5,20,2); model.delta = exp(par(4)); end warning on %[par,fval] = csa(rand(3,5),@(x)simanncostfun3(x,model,costfun,costargs)); model = changelssvm(changelssvm(model,'gam',exp(par(1))),'kernel_pars',[exp(par(2));round(exp(par(3)))]); fprintf('\n\n') disp([' 1. Simulated Annealing results: [gam] ' num2str(model.gam)]); disp([' [t] ' num2str(model.kernel_pars(1))]); disp([' [degree] ' num2str(round(

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