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Particle swarm optimization for parameter determination and feature selection of support vector machines

Particle swarm optimization for parameter determination and feature selection of support vector machines. Shih-Wei Lin, Kuo-Ching Ying, Shih-Chieh Chen, Zne-Jung Lee. Expert Systems with Applications 2008 . Introduction. Classification problems have been extensively studied.

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Particle swarm optimization for parameter determination and feature selection of support vector machines

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  1. Particle swarm optimization for parameter determination and feature selection of support vector machines Shih-Wei Lin, Kuo-Ching Ying, Shih-Chieh Chen, Zne-Jung Lee Expert Systemswith Applications 2008

  2. Introduction • Classification problems have been extensively studied. • Support vector machine (SVM) is a popular pattern classification method with many diverse applications. • Kernel parameter setting in the SVM training procedure, along with the feature selection, significantly influences the classification accuracy.

  3. Introduction How to choose the optimal input feature subset for SVM? How to set the best kernel parameters? • Hybridizing the particle swarm optimization (PSO) and SVM to improve the classification accuracy with a small and appropriate feature subset. • This makes the optimal separating hyper-plane obtainable in both linear and non-linear classification problems 1. 2.

  4. Support Vector Machine (SVM) • Support vector machine (SVM) is a new technique for data classification were first suggested by Vapnik in 1995. • SVM is using Separating Hyperplane to distinguish the data of two or several different Class that deal with the data mining problem of classification.

  5. Kernel Function • Several kernel functions help the SVM in obtaining the optimal solution. • For example: Linear, Polynomial, RBF, Sigmoid • The RBF is generally applied most frequently, because it can classify multi-dimensional data, unlike a linear kernel function. • The RBF has fewer parameters to set than other kernel. • RBF is an effective option for kernel function.

  6. SVM Parameters Setting • Proper parameters setting can improve the classification accuracy of SVM. • The parameters that should be optimized include penalty parameter C and the parameters with different kernel function (gamma of RBF). • Grid Algorithm is an alternative to find the best C and the gamma parameter, however it is time consuming and does not perform well.

  7. Feature Selection • Feature selection is used to identify a powerfully predictive subset of fields within the database and to reduce the number of fields presented to the mining process. • Affects several aspects of pattern classification: 1.The accuracy of classification algorithm learned 2.The time needed for learning a classification function 3.The number of examples needed for learning 4.The cost associated with feature

  8. Feature Selection • Filter • Wrapper

  9. Particle swarm optimization • Particle swarm optimization (PSO) (Kennedy & Eberhart,1995) is an emerging population-based meta-heuristic • The new position of a particle is calculated using the following formula:

  10. Particle swarm optimization • rnd( ) is a random function in the range[0, 1] • Positive constant c1 and c2 are personal and social learning factors. • w is the inertia weight and inertia weight balances the global exploration and local exploitation. • Pi,d denote the best previous position encountered by the ith particle. • Pg,d denotes the global best position thus far. • t denotes the iteration counter.

  11. Search concept of PSO.

  12. Grid-Search Algorithm

  13. Particle representation

  14. The flowchart of PSO algorithm. Fitness = Accuracy

  15. Platform • The platform adopted to develop the PSO + SVM approach is a PC with the following features: • Intel Pentium IV 3.0 GHz CPU • 512 MB RAM • Windows XP operating system • Visual C++ 6.0 development environment

  16. Dataset

  17. Cross-Validation • To guarantee that the present results are valid and can be generalized for making predictions regarding new data • Using k-fold-cross-validation • This study used k = 10, meaning that all of the data will be divided into ten parts, each of which will take turns at being the testing data set.

  18. PSO-based parameters determinationand feature selection approach for SVM

  19. Comparison between the PSO + SVM, NSVM, SVM, LSVM Fung & Mangasarian (2003) and Liao et al (2004)

  20. PSO+SVM VS PSO+GA

  21. PSO + SVM approach with and without feature selection and grid search

  22. PSO + SVM approach with and without feature selection

  23. Conclusions • We proposed a PSO-based strategy to select features subset and to set the parameters for SVM classification. • We have conducted two experiments to evaluate the classification accuracy of the proposed PSO-based approach with RBF kernel and the grid search method on 17 real-world datasets from UCI database. • Generally, compared with the grid search approach, the proposed PSO-based approach has good accuracy performance with fewer features.

  24. Future research • Other kernel parameters can also be optimized using the same approach. • Experimental results obtained from UCI datasets, other public datasets and real-world problems can be tested in the future to verify and extend this approach.

  25. Thank YouQ & A

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