ANALYSIS OF DIFFERENT WAVELETS FOR BRAIN IMAGE CLASSIFICATION USING SUPPORT VECTOR MACHINE
DOI:
https://doi.org/10.29284/ijasis.2.1.2016.1-4Keywords:
Brain Tumor, DWT, Db8, Sym8, bio3.7, SVMAbstract
Automated classification of medical images with high accuracy is crucial when dealing with human life. In this paper, Discrete Wavelet Transform (DWT) based classification of Magnetic Resonance Images (MRI) of the brain is presented. The given input images are de-noised using a median filter in the preprocessing stage. Then, the de-noised images are given as inputs to the wavelet transform. The wavelet transform is used for feature extraction purpose. Most transformation techniques produce coefficient values with their dimension same as the original image. Further processing of the coefficient values must be applied to extract the image feature vectors. Predefined families of wavelets such as Daubechies (db8), Symlets (sym8) and Biorthogonal (bio3.7) are used. From that energy information's are extracted and provided as input to the recognition or classification stage. Finally, the brain images are classified by Support Vector Machine (SVM) classifier whether it is normal or abnormal. Results show that db8 filter provides higher accuracy than other wavelets.
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G. Shobana, and R. Balakrishnan, Brain tumor diagnosis from MRI feature analysis-A comparative study, IEEE International Conference on Innovations in Information, Embedded and Communication Systems, 2015, pp. 1-4.
S.D.S. Al-Shaikhli, M.Y. Yang, and B. Rosenhahn, Brain tumor classification using sparse coding and dictionary learning, IEEE International Conference on Image Processing, 2014, pp. 2774-2778.
S.N. Deepa, and B.A. Devi, Artificial neural networks design for classification of brain tumour, IEEE International Conference on Computer Communication and Informatics, 2012, pp. 1-6.
A. Kharrat, M.B. Halima, and M.B. Ayed, MRI brain tumor classification using support vector machines and meta-heuristic method, IEEE 15th International Conference on Intelligent Systems Design and Applications, 2015, pp. 446-451.
D. Lu, Y. Sun, and S. Wan, Brain tumor classification using non-negative and local non-negative matrix factorization, IEEE International Conference on Signal Processing, Communication and Computing, 2013, pp. 1-4.
T. Martinez-Cortes, M.A. Fernandez-Torres, A. Jimenez-Moreno, I. Gonzalez-Diaz, F. Diaz-de-Maria, J.A. Guzman-De-Villoria, and P. Fernandez, A Bayesian model for brain tumor classification using clinical-based features, IEEE International Conference on Image Processing, 2014, pp. 2779-2783.
J. Sachdeva, V. Kumar, I. Gupta, N. Khandelwal, and C.K. Ahuja, Multiclass brain tumor classification using GA-SVM, IEEE Developments in E-systems Engineering, 2011, pp. 182-187.
D. Sridhar, and I.M. Krishna, Brain tumor classification using discrete cosine transform and probabilistic neural network, IEEE International Conference on Signal Processing Image Processing & Pattern Recognition, 2013, pp. 92-96.
K. Sudharani, T.C. Sarma, and K.S. Rasad, Intelligent Brain Tumor lesion classification and identification from MRI images using k-NN technique, IEEE International Conference on Control, Instrumentation, Communication and Computational Technologies, 2015, pp. 777-780.
G.K. Sundararaj, and V. Balamurugan, Robust classification of primary brain tumor in Computer Tomography images using K-NN and linear SVM, IEEE International Conference on Contemporary Computing and Informatics, 2014, pp. 1315-1319.
L. Wang, S. Wan, Y. Sun, B. Zhang, and X. Zhang, Automatic Classification of Brain Tumor by in Vivo MRS Data based on LDA and SVM, IEEE Seventh International Conference on Measuring Technology and Mechatronics Automation, 2015, pp. 213-216.
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