User:Atry/特征选择

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在机器学习和统计学中，特征选择 也被称为变量选择 , 属性选择 或变量子集选择 。它是指：为了构建模型而选择相关特征（即属性、指标）子集的过程。使用特征选择技术有三个原因：

• 简化模型，使之更易于被研究人员或用户理解，^[1]
• 缩短训练时间，
• 改善通用性、降低过拟合^[2]（即降低方差^[1] ）

要使用特征选择技术的关键假设是：训练数据包含许多冗余 或无关 的特征，因而移除这些特征并不会导致丢失信息。^[2] 冗余 或无关 特征是两个不同的概念。如果一个特征本身有用，但如果这个特征与另一个有用特征强相关，且那个特征也出现在数据中，那么这个特征可能就变得多余。^[3]

特征选择技术与特征提取有所不同。特征提取是从原有特征的功能中创造新的特征，而特征选择则只返回原有特征中的子集。 特征选择技术的常常用于许多特征但样本（即数据点）相对较少的领域。特征选择应用的典型用例包括：解析书面文本和微阵列数据，这些场景下特征成千上万，但样本只有几十到几百个。

介绍[编辑]

特征选择算法可以被视为搜索技术和评价指标的结合。前者提供候选的新特征子集，后者为不同的特征子集打分。 最简单的算法是测试每个特征子集，找到究竟哪个子集的错误率最低。这种算法需要穷举搜索空间，难以算完所有的特征集，只能涵盖很少一部分特征子集。 选择何种评价指标很大程度上影响了算法。而且，通过选择不同的评价指标，可以吧特征选择算法分为三类：包装类、过滤类和嵌入类方法^[3]

包装类方法使用预测模型给特征子集打分。每个新子集都被用来训练一个模型，然后用验证数据集来测试。通过计算验证数据集上的错误次数（即模型的错误率）给特征子集评分。由于包装类方法为每个特征子集训练一个新模型，所以计算量很大。不过，这类方法往往能为特定类型的模型找到性能最好的特征集。

过滤类方法采用代理指标，而不根据特征子集的错误率计分。所选的指标算得快，但仍然能估算出特征集好不好用。常用指标包括互信息、^[3]逐点互信息,^[4] 皮尔逊积矩相关系数、每种分类/特征的组合的帧间/帧内类距离或显著性测试评分。^[4][5]

过滤类方法计算量一般比包装类小，但这类方法找到的特征子集不能为特定类型的预测模型调校。由于缺少调校，过滤类方法所选取的特征集会比包装类选取的特征集更为通用，往往会导致比包装类的预测性能更为低下。不过，由于特征集不包含对预测模型的假设，更有利于暴露特征之间的关系。许多过滤类方法提供特征排名，而非显式提供特征子集。要从特征列表的哪个点切掉特征，得靠交叉验证来决定。过滤类方法也常常用于包装方法的预处理步骤，以便在问题太复杂时依然可以用包装方法。

嵌入类方法包括了所有构建模型过程中庸道德特征选择技术。这类方法的典范是构建线性模型的LASSO方法。该方法给回归系数加入了L1惩罚，导致其中的许多参数趋于零。任何回归系数不为零的特征都会被LASSO算法“选中”。LASSO的改良算法有Bolasso^[6]和FeaLect^[7]。Bolasso改进了样本的初始过程。FeaLect根据回归系数组合分析给所有特征打分。 另外一个流行的做法是递归特征消除（Recursive Feature Elimination）算法，通常用于支持向量机，通过反复构建同一个模型移除低权重的特征。这些方法的计算复杂度往往在过滤类和包装类之间。

传统的统计学中，特征选择的最普遍的形式是逐步回归，这是一个包装类技术。它属于贪心算法，每一轮添加该轮最优的特征或者删除最差的特征。主要的调控因素是决定何时停止算法。在机器学习领域，这个时间点通常通过交叉验证找出。在统计学中，某些条件已经优化。因而会导致嵌套引发问题。此外，还有更健壮的方法，如分支和约束和分段线性网络。

Subset selection[编辑]

Subset selection evaluates a subset of features as a group for suitability. Subset selection algorithms can be broken up into Wrappers, Filters and Embedded. Wrappers use a search algorithm to search through the space of possible features and evaluate each subset by running a model on the subset. Wrappers can be computationally expensive and have a risk of over fitting to the model. Filters are similar to Wrappers in the search approach, but instead of evaluating against a model, a simpler filter is evaluated. Embedded techniques are embedded in and specific to a model.

Many popular search approaches use greedy hill climbing, which iteratively evaluates a candidate subset of features, then modifies the subset and evaluates if the new subset is an improvement over the old. Evaluation of the subsets requires a scoring metric that grades a subset of features. Exhaustive search is generally impractical, so at some implementor (or operator) defined stopping point, the subset of features with the highest score discovered up to that point is selected as the satisfactory feature subset. The stopping criterion varies by algorithm; possible criteria include: a subset score exceeds a threshold, a program's maximum allowed run time has been surpassed, etc.

Alternative search-based techniques are based on targeted projection pursuit which finds low-dimensional projections of the data that score highly: the features that have the largest projections in the lower-dimensional space are then selected.

Search approaches include:

• Exhaustive
• Best first
• Simulated annealing
• 这些理论包括：
• Greedy forward selection
• Greedy backward elimination^[8][9][10]
• Particle swarm optimization^[11]
• Targeted projection pursuit
• Scatter Search^[12]
• Variable Neighborhood Search^[13][14]

Two popular filter metrics for classification problems are correlation and mutual information, although neither are true metrics or 'distance measures' in the mathematical sense, since they fail to obey the triangle inequality and thus do not compute any actual 'distance' – they should rather be regarded as 'scores'. These scores are computed between a candidate feature (or set of features) and the desired output category. There are, however, true metrics that are a simple function of the mutual information;^[15] see here.

Other available filter metrics include:

• Class separability
  • Error probability
  • Inter-class distance
  • Probabilistic distance
  • Entropy
• Consistency-based feature selection
• Correlation-based feature selection

Optimality criteria[编辑]

The choice of optimality criteria is difficult as there are multiple objectives in a feature selection task. Many common ones incorporate a measure of accuracy, penalised by the number of features selected (e.g. the Bayesian information criterion). The oldest are Mallows's C_p statistic and Akaike information criterion (AIC). These add variables if the t -statistic is bigger than ${\displaystyle {\sqrt {2}}}$.

Other criteria are Bayesian information criterion (BIC) which uses ${\displaystyle {\sqrt {\log {n}}}}$, minimum description length (MDL) which asymptotically uses ${\displaystyle {\sqrt {\log {n}}}}$, Bonferroni / RIC which use ${\displaystyle {\sqrt {2\log {p}}}}$, maximum dependency feature selection, and a variety of new criteria that are motivated by false discovery rate (FDR) which use something close to ${\displaystyle {\sqrt {2\log {\frac {p}{q}}}}}$.

Structure Learning[编辑]

Filter feature selection is a specific case of a more general paradigm called Structure Learning. Feature selection finds the relevant feature set for a specific target variable whereas structure learning finds the relationships between all the variables, usually by expressing these relationships as a graph. The most common structure learning algorithms assume the data is generated by a Bayesian Network, and so the structure is a directed graphical model. The optimal solution to the filter feature selection problem is the Markov blanket of the target node, and in a Bayesian Network, there is a unique Markov Blanket for each node.^[16]

Minimum-redundancy-maximum-relevance (mRMR) feature selection[编辑]

Peng et al. ^[17] proposed a feature selection method that can use either mutual information, correlation, or distance/similarity scores to select features. The aim is to penalise a feature's relevancy by its redundancy in the presence of the other selected features. The relevance of a feature set S for the class c is defined by the average value of all mutual information values between the individual feature f_i and the class c as follows:

${\displaystyle D(S,c)={\frac {1}{|S|}}\sum _{f_{i}\in S}I(f_{i};c)}$.

The redundancy of all features in the set S is the average value of all mutual information values between the feature f_i and the feature f_j:

${\displaystyle R(S)={\frac {1}{|S|^{2}}}\sum _{f_{i},f_{j}\in S}I(f_{i};f_{j})}$

The mRMR criterion is a combination of two measures given above and is defined as follows:

${\displaystyle \mathrm {mRMR} =\max _{S}\left[{\frac {1}{|S|}}\sum _{f_{i}\in S}I(f_{i};c)-{\frac {1}{|S|^{2}}}\sum _{f_{i},f_{j}\in S}I(f_{i};f_{j})\right].}$

Suppose that there are n full-set features. Let x_i be the set membership indicator function for feature f_i, so that x_i=1 indicates presence and x_i=0 indicates absence of the feature f_i in the globally optimal feature set. Let ${\displaystyle c_{i}=I(f_{i};c)}$ and ${\displaystyle a_{ij}=I(f_{i};f_{j})}$. The above may then be written as an optimization problem:

${\displaystyle \mathrm {mRMR} =\max _{x\in \{0,1\}^{n}}\left[{\frac {\sum _{i=1}^{n}c_{i}x_{i}}{\sum _{i=1}^{n}x_{i}}}-{\frac {\sum _{i,j=1}^{n}a_{ij}x_{i}x_{j}}{(\sum _{i=1}^{n}x_{i})^{2}}}\right].}$

The mRMR algorithm is an approximation of the theoretically optimal maximum-dependency feature selection algorithm that maximizes the mutual information between the joint distribution of the selected features and the classification variable. As mRMR approximates the combinatorial estimation problem with a series of much smaller problems, each of which only involves two variables, it thus uses pairwise joint probabilities which are more robust. In certain situations the algorithm may underestimate the usefulness of features as it has no way to measure interactions between features which can increase relevancy. This can lead to poor performance^[18] when the features are individually useless, but are useful when combined (a pathological case is found when the class is a parity function of the features). Overall the algorithm is more efficient (in terms of the amount of data required) than the theoretically optimal max-dependency selection, yet produces a feature set with little pairwise redundancy.

mRMR is an instance of a large class of filter methods which trade off between relevancy and redundancy in different ways.^[18][19]

Global optimization formulations[编辑]

mRMR is a typical example of an incremental greedy strategy for feature selection: once a feature has been selected, it cannot be deselected at a later stage. While mRMR could be optimized using floating search to reduce some features, it might also be reformulated as a global quadratic programming optimization problem as follows:^[20]

${\displaystyle \mathrm {QPFS} :\min _{\mathbf {x} }\left\{\alpha \mathbf {x} ^{T}H\mathbf {x} -\mathbf {x} ^{T}F\right\}\quad {\mbox{s.t.}}\ \sum _{i=1}^{n}x_{i}=1,x_{i}\geq 0}$

where ${\displaystyle F_{n\times 1}=[I(f_{1};c),\ldots ,I(f_{n};c)]^{T}}$ is the vector of feature relevancy assuming there are n features in total, ${\displaystyle H_{n\times n}=[I(f_{i};f_{j})]_{i,j=1\ldots n}}$ is the matrix of feature pairwise redundancy, and ${\displaystyle \mathbf {x} _{n\times 1}}$ represents relative feature weights. QPFS is solved via quadratic programming. It is recently shown that QFPS is biased towards features with smaller entropy,^[21] due to its placement of the feature self redundancy term ${\displaystyle I(f_{i};f_{i})}$ on the diagonal of H.

Another global formulation for the mutual information based feature selection problem is based on the conditional relevancy:^[21]

${\displaystyle \mathrm {SPEC_{CMI}} :\max _{\mathbf {x} }\left\{\mathbf {x} ^{T}Q\mathbf {x} \right\}\quad {\mbox{s.t.}}\ \|\mathbf {x} \|=1,x_{i}\geq 0}$

where ${\displaystyle Q_{ii}=I(f_{i};c)}$ and ${\displaystyle Q_{ij}=I(f_{i};c|f_{j}),i\neq j}$.

An advantage of SPEC_CMI is that it can be solved simply via finding the dominant eigenvector of Q, thus is very scalable. SPEC_CMI also handles second-order feature interaction.

For high-dimensional and small sample data (e.g., dimensionality > 10^{7000500000000000000♠5} and the number of samples < 10^{7000300000000000000♠3}), the Hilbert-Schmidt Independence Criterion Lasso (HSIC Lasso) is useful.^[22] HSIC Lasso optimization problem is given as

${\displaystyle \mathrm {HSIC_{Lasso}} :\min _{\mathbf {x} }{\frac {1}{2}}\sum _{k,l=1}^{n}x_{k}x_{l}{\mbox{HSIC}}(f_{k},f_{l})-\sum _{k=1}^{n}x_{k}{\mbox{HSIC}}(f_{k},c)+\lambda \|\mathbf {x} \|_{1},\quad {\mbox{s.t.}}\ x_{1},\ldots ,x_{n}\geq 0,}$

where ${\displaystyle {\mbox{HSIC}}(f_{k},c)={\mbox{tr}}({\bar {\mathbf {K} }}^{(k)}{\bar {\mathbf {L} }})}$ is a kernel-based independence measure called the (empirical) Hilbert-Schmidt independence criterion (HSIC), ${\displaystyle {\mbox{tr}}(\cdot )}$ denotes the trace, ${\displaystyle \lambda }$ is the regularization parameter, ${\displaystyle {\bar {\mathbf {K} }}^{(k)}=\mathbf {\Gamma } \mathbf {K} ^{(k)}\mathbf {\Gamma } }$ and ${\displaystyle {\bar {\mathbf {L} }}=\mathbf {\Gamma } \mathbf {L} \mathbf {\Gamma } }$ are input and output centered Gram matrices, ${\displaystyle K_{i,j}^{(k)}=K(u_{k,i},u_{k,j})}$ and ${\displaystyle L_{i,j}=L(c_{i},c_{j})}$ are Gram matrices, ${\displaystyle K(u,u')}$ and ${\displaystyle L(c,c')}$ are kernel functions, ${\displaystyle \mathbf {\Gamma } =\mathbf {I} _{m}-{\frac {1}{m}}\mathbf {1} _{m}\mathbf {1} _{m}^{T}}$ is the centering matrix, ${\displaystyle \mathbf {I} _{m}}$ is the m-dimensional identity matrix (m: the number of samples), ${\displaystyle \mathbf {1} _{m}}$ is the m-dimensional vector with all ones, and ${\displaystyle \|\cdot \|_{1}}$ is the ${\displaystyle \ell _{1}}$-norm. HSIC always takes a non-negative value, and is zero if and only if two random variables are statistically independent when a universal reproducing kernel such as the Gaussian kernel is used.

The HSIC Lasso can be written as

${\displaystyle \mathrm {HSIC_{Lasso}} :\min _{\mathbf {x} }{\frac {1}{2}}\left\|{\bar {\mathbf {L} }}-\sum _{k=1}^{n}x_{k}{\bar {\mathbf {K} }}^{(k)}\right\|_{F}^{2}+\lambda \|\mathbf {x} \|_{1},\quad {\mbox{s.t.}}\ x_{1},\ldots ,x_{n}\geq 0,}$

where ${\displaystyle \|\cdot \|_{F}}$ is the Frobenius norm. The optimization problem is a Lasso problem, and thus it can be efficiently solved with a state-of-the-art Lasso solver such as the dual augmented Lagrangian method.

Correlation feature selection[编辑]

The Correlation Feature Selection (CFS) measure evaluates subsets of features on the basis of the following hypothesis: "Good feature subsets contain features highly correlated with the classification, yet uncorrelated to each other".^[23][24] The following equation gives the merit of a feature subset S consisting of k features:

${\displaystyle Merit_{S_{k}}={\frac {k{\overline {r_{cf}}}}{\sqrt {k+k(k-1){\overline {r_{ff}}}}}}.}$

Here, ${\displaystyle {\overline {r_{cf}}}}$ is the average value of all feature-classification correlations, and ${\displaystyle {\overline {r_{ff}}}}$ is the average value of all feature-feature correlations. The CFS criterion is defined as follows:

${\displaystyle \mathrm {CFS} =\max _{S_{k}}\left[{\frac {r_{cf_{1}}+r_{cf_{2}}+\cdots +r_{cf_{k}}}{\sqrt {k+2(r_{f_{1}f_{2}}+\cdots +r_{f_{i}f_{j}}+\cdots +r_{f_{k}f_{1}})}}}\right].}$

The ${\displaystyle r_{cf_{i}}}$ and ${\displaystyle r_{f_{i}f_{j}}}$ variables are referred to as correlations, but are not necessarily Pearson's correlation coefficient or Spearman's ρ. Dr. Mark Hall's dissertation uses neither of these, but uses three different measures of relatedness, minimum description length (MDL), symmetrical uncertainty, and relief.

Let x_i be the set membership indicator function for feature f_i ; then the above can be rewritten as an optimization problem:

${\displaystyle \mathrm {CFS} =\max _{x\in \{0,1\}^{n}}\left[{\frac {(\sum _{i=1}^{n}a_{i}x_{i})^{2}}{\sum _{i=1}^{n}x_{i}+\sum _{i\neq j}2b_{ij}x_{i}x_{j}}}\right].}$

The combinatorial problems above are, in fact, mixed 0–1 linear programming problems that can be solved by using branch-and-bound algorithms.^[25]

Regularized trees[编辑]

The features from a decision tree or a tree ensemble are shown to be redundant. A recent method called regularized tree^[26] can be used for feature subset selection. Regularized trees penalize using a variable similar to the variables selected at previous tree nodes for splitting the current node. Regularized trees only need build one tree model (or one tree ensemble model) and thus are computationally efficient.

Regularized trees naturally handle numerical and categorical features, interactions and nonlinearities. They are invariant to attribute scales (units) and insensitive to outliers, and thus, require little data preprocessing such as normalization. Regularized random forest (RRF)^[27] is one type of regularized trees. The guided RRF is an enhanced RRF which is guided by the importance scores from an ordinary random forest.

Overview on metaheuristics methods[编辑]

A metaheuristic is a general description of an algorithm dedicated to solve difficult (typically NP-hard problem) optimization problems for which there is no classical solving methods. Generally, a metaheuristic is a stochastics algorithm tending to reach a global optima. There are many metaheuristics, from a simple local search to a complex global search algorithm.

Main principles[编辑]

The feature selection methods are typically presented in three classes based on how they combine the selection algorithm and the model building.

Filter Method[编辑]

Filter-based feature selection has become crucial in many classification settings, especially object recognition, recently faced with feature learning strategies that originate thousands of cues.^[28] Filter methods analyze intrinsic properties of data, ignoring the classifier. Most of these methods can perform two operations, ranking and subset selection: in the former, the importance of each individual feature is evaluated, usually by neglecting potential interactions among the elements of the joint set; in the latter, the final subset of features to be selected is provided. In some cases, these two operations are performed sequentially (first the ranking, then the selection); in other cases, only the selection is carried out.^[28] Filter methods suppress the least interesting variables. These methods are particularly effective in computation time and robust to overfitting.^[29]

However, filter methods tend to select redundant variables because they do not consider the relationships between variables. Therefore, they are mainly used as a pre-process method.

Wrapper Method[编辑]

Wrapper methods evaluate subsets of variables which allows, unlike filter approaches, to detect the possible interactions between variables.^[30] The two main disadvantages of these methods are :

• The increasing overfitting risk when the number of observations is insufficient.
• The significant computation time when the number of variables is large.

Embedded Method[编辑]

Recently, embedded methods have been proposed to reduce the classification of learning. They try to combine the advantages of both previous methods. The learning algorithm takes advantage of its own variable selection algorithm. So, it needs to know preliminary what a good selection is, which limits their exploitation.^[31]

Application of feature selection metaheuristics[编辑]

This is a survey of the application of feature selection metaheuristics lately used in the literature. This survey was realized by J. Hammon in her thesis.^[29]

应用领域	算法	我们的工作方式	classifier	Evaluation Function	{0}参考号{1}：016596{/1}{/0}
SNPs	Feature Selection using Feature Similarity	过滤		ŕ	Phuong 2005 [30]
SNPs	这些理论包括：	{0}wrapper{/0}{1}.{/1}	Decision Tree	Classification accuracy (10-fold)	Shah 2004 [32]
SNPs	HillClimbing	Filter + Wrapper	Naive Bayesian	Predicted residual sum of squares	长
SNPs	Simulated Annealing		Naive bayesian	Classification accuracy (5-fold)	Ustunkar 2011 [33]
Segments parole	Ants colony	{0}wrapper{/0}{1}.{/1}	Artificial Neural Network	MSE	Al-ani 2005 [來源請求]
营销	Simulated Annealing	{0}wrapper{/0}{1}.{/1}	回归	AIC, r2	Meiri 2006 [34]
经济	Simulated Annealing, Genetic Algorithm	{0}wrapper{/0}{1}.{/1}	回归	BIC	Kapetanios 2005 [35]
Spectral Mass	这些理论包括：	{0}wrapper{/0}{1}.{/1}	Multiple Linear Regression, Partial Least Squares	root-mean-square error of prediction	Broadhurst 2007 [36]
Microarray	Tabu Search + PSO	{0}wrapper{/0}{1}.{/1}	Support Vector Machine, K Nearest Neighbors	Euclidean Distance	Chuang 2009 [37]
Microarray	PSO + Genetic Algorithm	{0}wrapper{/0}{1}.{/1}	Support Vector Machine	Classification accuracy (10-fold)	Alba 2007 [38]
Microarray	Genetic Algorithm + Iterated Local Search	EMBEDDED	Support Vector Machine	Classification accuracy (10-fold)	Duval 2009 [31]
Microarray	Iterated Local Search	{0}wrapper{/0}{1}.{/1}	回归	Posterior Probability	Hans 2007 [39]
Microarray	这些理论包括：	{0}wrapper{/0}{1}.{/1}	K Nearest Neighbors	Classification accuracy (Leave-one-out cross-validation)	Jirapech-Umpai 2005 [40]
Microarray	Hybrid Genetic Algorithm	{0}wrapper{/0}{1}.{/1}	K Nearest Neighbors	Classification accuracy (Leave-one-out cross-validation)	我
Microarray	这些理论包括：	{0}wrapper{/0}{1}.{/1}	Support Vector Machine	Sensitivity and specificity	Xuan 2011 [41]
Microarray	这些理论包括：	{0}wrapper{/0}{1}.{/1}	All paired Support Vector Machine	Classification accuracy (Leave-one-out cross-validation)	Peng 2003 [42]
Microarray	这些理论包括：	EMBEDDED	Support Vector Machine	Classification accuracy (10-fold)	Hernandez 2007 [43]
Microarray	这些理论包括：	混合式	Support Vector Machine	Classification accuracy (Leave-one-out cross-validation)	Huerta 2006 [44]
Microarray	这些理论包括：		Support Vector Machine	Classification accuracy (10-fold)	Muni 2006 [45]
Microarray	这些理论包括：	{0}wrapper{/0}{1}.{/1}	Support Vector Machine	EH-DIALL, CLUMP	Jourdan 2004 [46]
Object Recognition	Infinite Feature Selection	过滤	Support Vector Machine	Mean Average Precision (mAP)	Roffo 2015 [28]

Feature selection embedded in learning algorithms[编辑]

Some learning algorithms perform feature selection as part of their overall operation. 这些心理素质包括:

• ${\displaystyle l_{1}}$-regularization techniques, such as sparse regression, LASSO, and ${\displaystyle l_{1}}$-SVM
• Regularized trees,^[26] e.g. regularized random forest implemented in the RRF package^[27]
• Decision tree^{[來源請求]}
• Memetic algorithm
• Random multinomial logit (RMNL)
• Auto-encoding networks with a bottleneck-layer
• Submodular feature selection^[47][48][49]

参见[编辑]

• 群集分析
• Dimensionality reduction
• Feature extraction
• · 数据挖掘

此條目已列出參考資料，但文內引註不足，部分內容的來源仍然不明。 (2010年7月) 请加上合适的文內引註加以改善。

参考文献[编辑]

扩展阅读[编辑]

外部链接[编辑]

• A comprehensive package for Mutual Information based feature selection in Matlab
• Infinite Feature Selection (Source Code) in Matlab
• Feature Selection Package, Arizona State University (Matlab Code)
• NIPS challenge 2003 (see also NIPS)
• Naive Bayes implementation with feature selection in Visual Basic (includes executable and source code)
• Minimum-redundancy-maximum-relevance (mRMR) feature selection program
• FEAST (Open source Feature Selection algorithms in C and MATLAB)

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