在电脑文件夹E:\other\matlab 2007a\work\SVM\libsvm-mat-3.0-1 ,这个是已经编译好的,到64位机上要重新编译(不要利用别人传的,因为可能改过SVM程序,例如Libing wang他改过其中程序,最原始版本:E:\other\matlab 2007a\work\SVM\libsvm-mat-3.0-1.zip,从http://www.csie.ntu.edu.tw/~cjlin/libsvm/matlab/libsvm-mat-3.0-1.zip下载)svmtrainmatlab自带的工具箱中也有这个函数, libing 讲libsvm-mat-3.0-1放到C:\Program Files\MATLAB\R2010a\toolbox\目录,再adddpathsavepath即可。如果产生以下问题:每次都要 adddpathsavepath ,在matlab重新启动后要重新
adddpathsavepath。解决方案:可以在要运行的程序前面添加如下语句即可:  
addpath('C:\Program Files\MATLAB\R2010a\toolbox\libsvm-mat-3.0-1');

README文件写得很好,其中的Examples完全理解(包括Precomputed Kernels.Constructing a linear kernel matrix and then using the precomputed kernel gives exactly the same testing error as using the LIBSVM built-in linear kernel.核就是相似度,自己想定义什么相似度都可以)

 

(1) model = svmtrain(training_label_vector, training_instance_matrix [, 'libsvm_options']);

libsvm_options的设置:

Examples of options: -s 0 -c 10 -t 1 -g 1 -r 1 -d 3 
Classify a binary data with polynomial kernel (u'v+1)^3 and C = 10

 

options:

-s svm_type : set type of SVM (default 0)

    0 -- C-SVC

    1 -- nu-SVC

    2 -- one-class SVM

    3 -- epsilon-SVR

    4 -- nu-SVR
C-SVC全称是什么?
C-SVC(C-support vector classification),nu-SVC(nu-support vector classification),one-class SVM(distribution estimation),epsilon-SVR(epsilon-support vector regression),nu-SVR(nu-support vector regression)


-t kernel_type : set type of kernel function (default 2)

    0 -- linear: u'*v

    1 -- polynomial: (gamma*u'*v + coef0)^degree

    2 -- radial basis function: exp(-gamma*|u-v|^2)

    3 -- sigmoid: tanh(gamma*u'*v + coef0)

-d degree : set degree in kernel function (default 3)

-g gamma : set gamma in kernel function (default 1/num_features)

-r coef0 : set coef0 in kernel function (default 0)

-c cost : set the parameter C of C-SVC, epsilon-SVR, and nu-SVR (default 1)

-n nu : set the parameter nu of nu-SVC, one-class SVM, and nu-SVR (default 0.5)

-p epsilon : set the epsilon in loss function of epsilon-SVR (default 0.1)

-m cachesize : set cache memory size in MB (default 100)

-e epsilon : set tolerance of termination criterion (default 0.001)

-h shrinking: whether to use the shrinking heuristics, 0 or 1 (default 1)

-b probability_estimates: whether to train a SVC or SVR model for probability estimates, 0 or 1 (default 0)
-wi weight: set the parameter C of class i to weight*C, for C-SVC (default 1)

The k in the -g option means the number of attributes in the input data.

 

(2)如何采用线性核?

matlab> % Linear Kernel

matlab> model_linear = svmtrain(train_label, train_data, '-t 0');

 严格讲,线性核也要像高斯核一样调整c这个参数,Libing wang讲一般C=1效果比较好,可能调整效果差异不大,当然要看具体的数据集。c大,从SVM目标函数可以看出,c越大,相当于惩罚松弛变量,希望松弛变量接近0,即都趋向于对训练集全分对的情况,这样对训练集测试时准确率很高,但推广能力未必好,即在测试集上未必好。c小点,相当于边界的有些点容许分错,将他们当成噪声点,这样外推能力比较好。

(3)如何采用高斯核?

matlab> load heart_scale.mat

matlab> model = svmtrain(heart_scale_label, heart_scale_inst, '-c 1 -g 0.07');

高斯的SVM比线性SVM效果要差,为什么?
20150420 libing讨论,可能的解释:样本少,不适合高斯核。范围有限,也许更广泛的参数范围会有更好的效果

 

(4)如何实现交叉验证?

README文件有如下一句话:If the '-v' option is specified, cross validation is

conducted and the returned model is just a scalar: cross-validation

accuracy for classification and mean-squared error for regression.

 

(5) 如何调整高斯核的两个参数?

思路1在训练集上调整两个参数使在训练集上测试错误率最低,就选这样的参数来测试测试集

思路1的问题:Libing Wang讲这样很容易过学习,因为在训练集上很容易达到100%准确率,但在测试集上未必好,即过学习。用思路2有交叉验证,推广性能比较好(交叉验证将训练集随机打乱,推广性能很好)

 

思路2% E:\other\matlab 2007a\work\DCT\DCT_original\network.m

思路2的问题:针对不同的数据集,这两个参数分别在什么范围内调整,有没有什么经验?
方式1:就是network.m中gamma的取值
方式2:http://www.cppblog.com/guijie/archive/2010/12/02/135243.html.
其他答案:除了在训练集上做交叉验证,还有另外一种思路:类似A Regularized Approach to Feature Selection for Face Detection (ACCV 2007)的4.2节:训练集、验证集和测试集,Libing讲该文4.2节调参数除了分成训练集、验证集和测试集,没有其他什么的。Libing讲在训练集上交叉验证也相当于训练集挑了一部分做验证,原理一样。

(6)如何采用预定义核?

To use precomputed kernel, you must include sample serial number asthe first column of the training and testing data (assume your kernel matrix is K, # of instances is n):
matlab> K1 = [(1:n)', K]; % include sample serial number as first column
matlab> model = svmtrain(label_vector, K1, '-t 4');
matlab> [predict_label, accuracy, dec_values] = svmpredict(label_vector, K1, model); % test the training data

We give the following detailed example by splitting heart_scale into 150 training and 120 testing data.  Constructing a linear kernel matrix and then using the precomputed kernel gives exactly the same testing error as using the LIBSVM built-in linear kernel.
matlab> load heart_scale.mat
matlab>
matlab> % Split Data
matlab> train_data = heart_scale_inst(1:150,:);
matlab> train_label = heart_scale_label(1:150,:);
matlab> test_data = heart_scale_inst(151:270,:);
matlab> test_label = heart_scale_label(151:270,:);
matlab>
matlab> % Linear Kernel
matlab> model_linear = svmtrain(train_label, train_data, '-t 0');
matlab> [predict_label_L, accuracy_L, dec_values_L] = svmpredict(test_label, test_data, model_linear);
matlab>
matlab> % Precomputed Kernel
matlab> model_precomputed = svmtrain(train_label, [(1:150)', train_data*train_data'], '-t 4');
matlab> [predict_label_P, accuracy_P, dec_values_P] = svmpredict(test_label, [(1:120)', test_data*train_data'], model_precomputed);
matlab>
matlab> accuracy_L % Display the accuracy using linear kernel
matlab> accuracy_P % Display the accuracy using precomputed kernel

(7)如何实现概率估计?
For probability estimates, you need '-b 1' for training and testing:
matlab> load heart_scale.mat
matlab> model = svmtrain(heart_scale_label, heart_scale_inst, '-c 1 -g 0.07 -b 1');
matlab> load heart_scale.mat
matlab> [predict_label, accuracy, prob_estimates] = svmpredict(heart_scale_label, heart_scale_inst, model, '-b 1');

非概率估计
matlab> load heart_scale.mat
matlab> model = svmtrain(heart_scale_label, heart_scale_inst, '-c 1 -g 0.07');
matlab> [predict_label, accuracy, dec_values] = svmpredict(heart_scale_label, heart_scale_inst, model); % test the training data

(8) svmpredict的用法(摘自libsvm-mat-2.9-1的README)
[predicted_label, accuracy, decision_values/prob_estimates] = svmpredict(testing_label_vector, testing_instance_matrix, model [, 'libsvm_options']);
输入:testing_label_vector, If labels of test data are unknown, simply use any random values. (type must be double)。模型一旦确定,预测的标记就确定了,如果不利用第二个输出accuracy,则testing_label_vector随便设置,当然如果要利用accuracy,就要将testing_label_vector设置成测试标记了。(Action recognition\ASLAN database中的代码CLSlibsvmC,第九行用到svmpredict,testing_label_vector设置成ones(size(Samples,2),1),是无所谓的)。
svmpredict输出的含义:
predictd_label, is a vector of predicted labels(故CLSlibsvmC的12到14行没用);
胥志伟I-Rising(285308540) 2015/5/31 21:56:30
各位老师,同学。请问有人研究过svm 中predict的decision value吗?麻烦帮忙解释下怎么计算的。谢谢。
苏松志-T-厦大(14291414) 2015/5/31 22:04:40
指的是libsvm?优化完之后得到每个支持向量的alph_i,然后,计算输入的x和各个支持向量的核函数距离ki,sum(ki*alph_i*yi) for all SUPPORT VECTORS,+b,就是按照教科书上的公式
说明:以上understand completely,对应杨光正教材P28公式(2.54)
胥志伟I-Rising(285308540) 2015/5/31 22:08:30
多类的问题也是这样吗?
苏松志-T-厦大(14291414) 2015/5/31 22:13:41
是的,多类采用的是1vs1,所有里面的sv_coef是一个mxn的矩阵,m:支持向量的数目,n: 类别数目-1,然后有一个rho向量,套用公式,计算

摘自libsvm-mat-3.0-1的README
The function 'svmpredict' has three outputs. The first one, predictd_label, is a vector of predicted labels. The second output, accuracy, is a vector including accuracy (for classification), mean squared error, and squared correlation coefficient (for regression). The third is a matrix containing decision values or probability estimates (if '-b 1' is specified). If k is the number of classes, for decision values, each row includes results of predicting k(k-1)/2 binary-class SVMs. For probabilities, each row contains k values indicating the probability that the testing instance is in each class. Note that the order of classes here is the same as 'Label' field in the model structure.

(9)LibSVM是如何采用one-versus-rest和one-verse-one实现多类分类的?
one-versus-rest和one-verse-one的定义见模式识别笔记第四页反面(同时见孙即祥教材P47)。找libing wang和junge zhang,他们都讲没对这个深究过。根据“If k is the number of classes, for decision values, each row includes results of predicting k(k-1)/2 binary-class SVMsFor probabilities, each row contains k values indicating the probability that the testing instance is in each class. ”,我觉得应该是probabilities实现的是one-versus-rest,即采用-b 1这个选项,他俩都觉得我理解应该是正确的。junge讲参加pascal竞赛和imagenet,他们都是训练k个SVM(即one-versus-rest,没用one-versus-one,后者太慢,而且估计效果差不多),没有直接采用SVM做多类问题。
20130910 LibSVM作者回信:
Libsvm implements only 1vs1.
For 1vsrest, you can check the following
libsvm faq

Q: LIBSVM supports 1-vs-1 multi-class classification. If instead I would
like to use 1-vs-rest, how to implement it using MATLAB interface?
网址:
http://www.csie.ntu.edu.tw/~cjlin/libsvm/faq.html#f808
Q: LIBSVM supports 1-vs-1 multi-class classification. If instead I would like to use 1-vs-rest, how to implement it using MATLAB interface? 

Please use code in the following directory. The following example shows how to train and test the problem dna (training and testing).

Load, train and predict data:

[trainY trainX] = libsvmread('./dna.scale');
[testY testX] = libsvmread('./dna.scale.t');
model = ovrtrain(trainY, trainX, '-c 8 -g 4');
[pred ac decv] = ovrpredict(testY, testX, model);
fprintf('Accuracy = %g%%\n', ac * 100);
Conduct CV on a grid of parameters
bestcv = 0; 
for log2c = -1:2:3,
for log2g = -4:2:1,
cmd = ['-q -c ', num2str(2^log2c), ' -g ', num2str(2^log2g)];
cv = get_cv_ac(trainY, trainX, cmd, 3);
if (cv >= bestcv),
bestcv = cv; bestc = 2^log2c; bestg = 2^log2g;
end
fprintf('%g %g %g (best c=%g, g=%g, rate=%g)\n', log2c, log2g, cv, bestc, bestg, bestcv);
end
end

(9)如何实现验证模式下的准确率?
见我写的程序RVM\code\Yale\SVM\TestYale_SVM_2classes
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http://blog.sina.com.cn/s/blog_64b046c701018c8n.html
MATLAB自带的svm实现函数与libsvm差别小议 

1 MATLAB自带的svm实现函数仅有的模型是C-SVC(C-support vector classification); 而libsvm工具箱有C-SVC(C-support vector classification),nu-SVC(nu-support vector classification),one-class SVM(distribution estimation),epsilon-SVR(epsilon-support vector regression),nu-SVR(nu-support vector regression)等多种模型可供使用。 
2 MATLAB自带的svm实现函数仅支持分类问题,不支持回归问题;而libsvm不仅支持分类问题,亦支持回归问题。 
3 MATLAB自带的svm实现函数仅支持二分类问题,多分类问题需按照多分类的相应算法编程实现;而libsvm采用1v1算法支持多分类。 
4 MATLAB自带的svm实现函数采用RBF核函数时无法调节核函数的参数gamma,貌似仅能用默认的;而libsvm可以进行该参数的调节。 
5 libsvm中的二次规划问题的解决算法是SMO;而MATLAB自带的svm实现函数中二次规划问题的解法有三种可以选择:经典二次方法;SMO;最小二乘。(这个是我目前发现的MATLAB自带的svm实现函数唯一的优点~)
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 SVM 理论部分

SVM下面推导核化形式(Eric Xing教材)+M. Belkin, P. Niyogi, and V. Sindhwani, “Manifold Regularization: AGeometric Framework for Learning from Labeled and Unlabeled Examples,” J. Machine Learning Research, vol. 7, pp. 2399-2434, 2006的4.3和4.4节.+Ensemble Manifold Regularization (TPAMI 2012)

电脑里的"
ZhuMLSS14.pdf"是很好的入门材料