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Least-squares support vector machine

Least-squares support-vector machines (LS-SVM) for statistics and in statistical modeling, are least-squares versions of support-vector machines (SVM), which are a set of related supervised learning methods that analyze data and recognize patterns, and which are used for classification and regression analysis. In this version one finds the solution by solving a set of linear equations instead of a convex quadratic programming (QP) problem for classical SVMs. Least-squares SVM classifiers were proposed by Johan Suykens and Joos Vandewalle.[1] LS-SVMs are a class of kernel-based learning methods.

From support-vector machine to least-squares support-vector machine

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Given a training set   with input data   and corresponding binary class labels  , the SVM[2] classifier, according to Vapnik's original formulation, satisfies the following conditions:

 
The spiral data:   for blue data point,   for red data point
 

which is equivalent to

 

where   is the nonlinear map from original space to the high- or infinite-dimensional space.

Inseparable data

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In case such a separating hyperplane does not exist, we introduce so-called slack variables   such that

 
 
The result of the SVM classifier

According to the structural risk minimization principle, the risk bound is minimized by the following minimization problem:

 
 

To solve this problem, we could construct the Lagrangian function:

 

where   are the Lagrangian multipliers. The optimal point will be in the saddle point of the Lagrangian function, and then we obtain

  (1)

By substituting   by its expression in the Lagrangian formed from the appropriate objective and constraints, we will get the following quadratic programming problem:

 

where   is called the kernel function. Solving this QP problem subject to constraints in (1), we will get the hyperplane in the high-dimensional space and hence the classifier in the original space.

Least-squares SVM formulation

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The least-squares version of the SVM classifier is obtained by reformulating the minimization problem as

 

subject to the equality constraints

 

The least-squares SVM (LS-SVM) classifier formulation above implicitly corresponds to a regression interpretation with binary targets  .

Using  , we have

 

with   Notice, that this error would also make sense for least-squares data fitting, so that the same end results holds for the regression case.

Hence the LS-SVM classifier formulation is equivalent to

 

with   and  

 
The result of the LS-SVM classifier

Both   and   should be considered as hyperparameters to tune the amount of regularization versus the sum squared error. The solution does only depend on the ratio  , therefore the original formulation uses only   as tuning parameter. We use both   and   as parameters in order to provide a Bayesian interpretation to LS-SVM.

The solution of LS-SVM regressor will be obtained after we construct the Lagrangian function:

 

where   are the Lagrange multipliers. The conditions for optimality are

 

Elimination of   and   will yield a linear system instead of a quadratic programming problem:

 

with  ,   and  . Here,   is an   identity matrix, and   is the kernel matrix defined by  .

Kernel function K

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For the kernel function K(•, •) one typically has the following choices:

  • Linear kernel :  
  • Polynomial kernel of degree  :  
  • Radial basis function RBF kernel :  
  • MLP kernel :  

where  ,  ,  ,   and   are constants. Notice that the Mercer condition holds for all   and   values in the polynomial and RBF case, but not for all possible choices of   and   in the MLP case. The scale parameters  ,   and   determine the scaling of the inputs in the polynomial, RBF and MLP kernel function. This scaling is related to the bandwidth of the kernel in statistics, where it is shown that the bandwidth is an important parameter of the generalization behavior of a kernel method.

Bayesian interpretation for LS-SVM

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A Bayesian interpretation of the SVM has been proposed by Smola et al. They showed that the use of different kernels in SVM can be regarded as defining different prior probability distributions on the functional space, as  . Here   is a constant and   is the regularization operator corresponding to the selected kernel.

A general Bayesian evidence framework was developed by MacKay,[3][4][5] and MacKay has used it to the problem of regression, forward neural network and classification network. Provided data set  , a model   with parameter vector   and a so-called hyperparameter or regularization parameter  , Bayesian inference is constructed with 3 levels of inference:

  • In level 1, for a given value of  , the first level of inference infers the posterior distribution of   by Bayesian rule
 
  • The second level of inference determines the value of  , by maximizing
 
  • The third level of inference in the evidence framework ranks different models by examining their posterior probabilities
 

We can see that Bayesian evidence framework is a unified theory for learning the model and model selection. Kwok used the Bayesian evidence framework to interpret the formulation of SVM and model selection. And he also applied Bayesian evidence framework to support vector regression.

Now, given the data points   and the hyperparameters   and   of the model  , the model parameters   and   are estimated by maximizing the posterior  . Applying Bayes’ rule, we obtain

 

where   is a normalizing constant such the integral over all possible   and   is equal to 1. We assume   and   are independent of the hyperparameter  , and are conditional independent, i.e., we assume

 

When  , the distribution of   will approximate a uniform distribution. Furthermore, we assume   and   are Gaussian distribution, so we obtain the a priori distribution of   and   with   to be

 

Here   is the dimensionality of the feature space, same as the dimensionality of  .

The probability of   is assumed to depend only on   and  . We assume that the data points are independently identically distributed (i.i.d.), so that:

 

In order to obtain the least square cost function, it is assumed that the probability of a data point is proportional to:

 

A Gaussian distribution is taken for the errors   as:

 

It is assumed that the   and   are determined in such a way that the class centers   and   are mapped onto the target -1 and +1, respectively. The projections   of the class elements   follow a multivariate Gaussian distribution, which have variance  .

Combining the preceding expressions, and neglecting all constants, Bayes’ rule becomes

 

The maximum posterior density estimates   and   are then obtained by minimizing the negative logarithm of (26), so we arrive (10).

References

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  1. ^ Suykens, J. A. K.; Vandewalle, J. (1999) "Least squares support vector machine classifiers", Neural Processing Letters, 9 (3), 293–300.
  2. ^ Vapnik, V. The nature of statistical learning theory. Springer-Verlag, New York, 1995.
  3. ^ MacKay, D. J. C. Bayesian Interpolation. Neural Computation, 4(3): 415–447, May 1992.
  4. ^ MacKay, D. J. C. A practical Bayesian framework for backpropagation networks. Neural Computation, 4(3): 448–472, May 1992.
  5. ^ MacKay, D. J. C. The evidence framework applied to classification networks. Neural Computation, 4(5): 720–736, Sep. 1992.

Bibliography

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  • J. A. K. Suykens, T. Van Gestel, J. De Brabanter, B. De Moor, J. Vandewalle, Least Squares Support Vector Machines, World Scientific Pub. Co., Singapore, 2002. ISBN 981-238-151-1
  • Suykens J. A. K., Vandewalle J., Least squares support vector machine classifiers, Neural Processing Letters, vol. 9, no. 3, Jun. 1999, pp. 293–300.
  • Vladimir Vapnik. The Nature of Statistical Learning Theory. Springer-Verlag, 1995. ISBN 0-387-98780-0
  • MacKay, D. J. C., Probable networks and plausible predictions—A review of practical Bayesian methods for supervised neural networks. Network: Computation in Neural Systems, vol. 6, 1995, pp. 469–505.
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  • www.esat.kuleuven.be/sista/lssvmlab/ "Least squares support vector machine Lab (LS-SVMlab) toolbox contains Matlab/C implementations for a number of LS-SVM algorithms".
  • www.kernel-machines.org "Support Vector Machines and Kernel based methods (Smola & Schölkopf)".
  • www.gaussianprocess.org "Gaussian Processes: Data modeling using Gaussian Process priors over functions for regression and classification (MacKay, Williams)".
  • www.support-vector.net "Support Vector Machines and kernel based methods (Cristianini)".
  • dlib: Contains a least-squares SVM implementation for large-scale datasets.