Kumar N, Alam K, Siddiqi A. H. Wavelet Transform for Classification of EEG Signal using SVM and ANN. Biomed Pharmacol J 2017;10(4).
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Nitendra Kumar, Khursheed Alam and Abul Hasan Siddiqi  

Department of Applied Sciences, school of Engineering and Technology, Sharda University, Greater Noida, Delhi (NCR) India,- 201306.

Corresponding Author E-mail: nkshukla.kumar4@gmail.com

DOI : https://dx.doi.org/10.13005/bpj/1328

Abstract

One of the most challenging research areas in the field of biomedical signal is feature extraction and classification of electroencephalogram (EEG) signal for normal and epileptic patients. Epileptic seizures are manifestations of epilepsy and epileptic seizures are disclosures of epilepsy. This paper illustrates the use of wavelet transform (WT) used for feature extraction of EEG signals and the classifiers used are Artificial Neural Network (ANN) and Support Vector Machine (SVM). For feature extraction the EEG signal is decomposed using Daubechies wavelet. Performances of classifiers are based on the parameters such as Accuracy, Sensitivity and Specificity.

Keywords

Artificial Neural Network(ANN) EEG Signal; Support Vector Machine (SVM); Wavelet Transform;

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Introduction

One of the most important organs of human body is brain. Brain is the vertebrate central nervous system that is enclosed within the cranium, spinal cord and also composed of gray and white matter. Brain is the prime centre for regulation and controls the functioning of the human body including heart bit and respiration. It is an extremely complex system in the entire body and exhibits rich spatiotemporal dynamics.1 And it is often affected by some disorder and malfunction. One of the most common brain disorders is Epilepsy. Today about 60 million people are affected by this disorder.

The Electroencephalogram which is abbreviated as (EEG) that is clinically used to investigate brain disorders or to diagnosis various brain functionalities.2 The first attempt at measuring this brain disorder activity was done by British Physician Richard Caton in the year 1875. Electroencephalographic record is one of the most important tools for the study of the brain electrical activity and for the diagnosis of neurological diseases.3  It is also the electrical interpretation of the heart activity. Epileptic seizures are basically the manifestations of epilepsy. Electroencephalograph (EEG) records can provide valuable insight and improved understanding of the mechanisms causing epileptic disorders by careful analysis.4  Epileptic seizure is due to the temporary electrical disturbance of the brain. Epileptic seizure sometimes, goes unnoticed and sometimes bit confused with other events prevailing depending on their presentations such as strokes, cause falls and migraines. Out of every 100 persons, one is experiencing a seizure at sometime in their whole life. Unfortunately, the occurrence of epileptic seizure seems somehow unpredictable and very little understood.5 In the diagnosis of epilepsy, the detection of epileptiform discharges in the EEG is an important component. EEG signals are non-stationary.3 The most important, useful and cost effective modality for the study of epilepsy is EEG. Also, EEG is a graphical representation of cardiac activity which uses primary measure for the identification of various heart diseases and heart abnormalities. EEG signal is basically a one-dimensional biological signal. Analyzing of EEG signal is based on its frequency content. Hence we can say that interpretation of EEG signal is based on the power of the frequencies it contains.6

Figure 1: 1D EEG Signal Figure 1: 1D EEG Signal

 

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The first remarkable work was done by Gotman in the year 1982 in the field related to seizures. Till now different methods have been proposed for the detection of epileptic seizures. Neep Hazarika et al did the classification of EEG signals using wavelet transform (WT) in the year 1997 and also described the application of an artificial neural network (ANN) technique.2 In the year 2005, Inan Guler, described the application of adaptive neuro-fuzzy interference system (ANFIS) model for the classification of EEG signals. In their work decision making was performed in two stages: feature extraction using wavelet transform and ANFIS trained with backpropagation gradient descent method in combination with the least squares method. Five different types of EEG signals were used as input patterns of the five ANFIS classifiers. For diagnostic accuracy, the sixth AFNIS classifier was trained fuzzy logic approach. The classification results as well as statistical measures were used for evaluating the ANFIS.  For ANFIS model, the total classification accuracy was obtained as 98.68%.In 2005, Abdulhamit Subasi et al in October, 2005 classified EEG signals using neural network and logical regression (LR). They introduced two fundamentally different approaches for designing classification models (classifiers) the traditional statistical method which was based on logistic regression and ANN. Logistic regression and multilayer preceptor neural network (MLPNN) based classifiers were developed and were compared in relation to their accuracy in respect to classification of EEG signals. An LBDWT coefficient of EEG signals as an input to classification system with two discrete outputs was used: epileptic seizure or non-epileptic seizure.4 Abdulhamit Subasi in 2007 developed two approaches for the identification of epileptic seizure. The first one was based on the traditional neural network that used Multi-layer perceptron neural network (MLPNN). The other one was Mixture of Expert (ME). Use of ME network structures was presented to improve the accuracy of epileptic seizure detection in EEG.5 In 2010 R. Panda et al proposed a work on classification of EEG signal using wavelet transform and support vector machine (SVM) for epileptic seizure detection. In their work, five different types of EEG signals were selected for analysis purpose. Preprocessing and decomposition of signals were done using DWT till 5th level of decomposition tree. Features like energy, entropy and standard deviation were computed and hence consequently used for classification of EEG signals. Classification accuracy of 91.2% was achieved in detection of abnormal from normal EEG signals.7 Kavita Mahajan et al in 2012 did a comparative study of ANN and SVM for EEG signal classification. In their work, various dimension reduction methods were used for reduction of decomposed data. The Classification was done using two classifiers for data as normal or abnormal. Performance of classifiers was compared to show the improved method. In their implemented system, the ANN classified the EEG signal with overall accuracy of 97% correct rate and the SVM classifier used classified the EEG signal with overall accuracy of 98.67%. The SVM gave better and improved result for LDA as compared to ICA and PCA i.e. (100 %). More consistent results were produced in combination of LDA+SVM in comparison to the combination of PCA+SVM and ICA+SVM.8 Pravin A. Kharat et al in 2012 proposed Daubechies Wavelet Neural Network classifier for the diagnosis of epilepsy. In their proposed work, wavelet transform was used feature extraction. Methods such as Generalized Feed Forward Neural Network (GFFNN), Multilayer Perceptron (MLP), Elman Neural Network (ENN) and Support Vector Machine (SVM) were used for classification. The problem of classification was modeled as three class classification problem and the three groups were: Healthy subjects (Normal EEG), Epileptic subjects during seizure free interval (Intericatal EEG) and Epileptic subjects during seizure activity (Ictal EEG). The percentage classification accuracy for MLP and SVM was found to be highest in comparison to other four neural networks. Sensitivity of 96.42% was achieved using MLP, and 94.11% was obtained for Interictal EEG and Ictal EEG respectively. 100% of classification accuracy was achieved for both Interictal EEG and Ictal EEG for SVM. For MLP and SVM, 100% specificity was obtained.9 Arslan Shahid et al in 2014 introduced a new method based on the singular values as a detector for epileptic seizures in EEG signals. Decomposition of singular values was performed on an EEG signal in epochs of 8 seconds. After the extraction from each epoch, singular values were fed into a support vector machine (SVM) for the purpose of binary classification between epileptic seizure and non-seizure events. In their work, a classification accuracy of 90%, average sensitivity 91% and specificity of 89% was achieved.10

Epilepsy

Epilepsy is one of the major fields of application of EEG and it is classified as one of the common chronic neurological disorders characterized by recurrent seizures that affect the brain. These epileptic seizures can occur in the brain locally and are seen as sudden abnormal functions of the body such as increase in muscular activities, loss of consciousness or abnormal sensations. It is mostly seen in children and adults at the age of 65 to 70. 1% of total world’s population is affected by the disease. It is curable if it is detected in initial stages. About 80% of the epileptic seizure activities can be treated or controlled, if it is diagnosed properly and remaining 20% continue to get seizures even after medical treatment.7

Seizure Detection

Seizures are transient abbreviations in the brain’s electrical activity. Basically the seizure detection is a classification between normal and seizure EEG. There are three functional modules of EEG processing systems namely, preprocessing, feature extraction and classification. Normally the EEG data gets corrupted by the artifacts. Artifacts are generally electrical signals that are picked up by the scalp electrodes. These electrodes do not originate from cortical neurons. Eye movement, blinking and muscular movements are the most common causes of artifacts. People having seizures suffer from recurrent seizures that occur at unpredictable times and that too without warnings. Sometimes it results in a lapse of attention or whole body convulsion. There is also risk of sustaining physical injuries and may even lead to death due to increment in frequent seizures. Analysis of scalp EEG that is a non-invasive, multichannel recording of the brain’s electrical activity is one of the most common way to infer the onset of a seizure before it becomes clinically manifest.11

 Figure 2: EEG Processing System Figure 2: EEG Processing System

 

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Feature Extraction Method

Signal analysis plays an important role in extracting information from signal by applying suitable method. A feature is basically a quantity that represents uniqueness between classes. In fact it is a numerical value characterizing a data or providing some information about the data. In this work, wavelet transform is used as a feature extraction method for both seizure patients and non-seizure patients. In this work, we have implemented wavelet transform and non – negative matrix factorization methods for feature extraction of EEG signal. Selection of appropriate wavelet and the number of decomposition levels is very important for analyzing signals using wavelet transform. Choosing the number of decomposition levels is based on the dominant frequency components of the signal. The levels are chosen in such a way that the parts of the signal, correlating well with the frequencies required for classification of the signal are retained in the wavelet coefficients.

Wavelet Transform

The electrical activities of the brain since 1930s has been measured by making use of surface electrodes connected to the scalp. But nowadays various mathematical tools such as Fourier Transform (FT), Fast Fourier Transform (FFT), Short Time Fourier Transform (STFT) and Wavelet Transform (WT) have been introduced for EEG signal feature extraction. However in Fast Fourier Transform, there was information loss about time domain and gave only spectral information in the frequency domain. To overcome the problems related to FFT, STFT was introduced that represented the signal in both time as well as in frequency domain using moving window function. The main problem associated with STFT is that it does not give multi-resolution information of the signals as it always has constant size.12,13 In order to overcome the problems related to Fourier transform, Fat Fourier Transform and Short Time Fourier transform, a powerful method was proposed in the late 1980s, known as Wavelet transform. Wavelet Transform can be thought as an extension to Fourier Transform and also instead of working on a single scale (time or frequency) rather it works on multi-scale basis and also addresses the problems related to non-stationary signals.  Wavelet transform theory has found many interesting many interesting applications in the field of Digital Signal Processing. In recent years, Wavelet analysis plays an important role for analyzing time – domain signals. Wavelet is a type of time-frequency analysis, which provides information about both frequency and time within signals. Analysis by wavelet represents a special type of linear transform of signals and also physical data represented by the signals about processes and physical properties of mediums and objects. Wavelet Transform has been more efficient for signal analysis in comparison to other transform methods such as Fourier transform, Short Time Fourier Transform. The main advantage of wavelet transform is that it has a varying window size which is broad at low frequencies and narrow at high frequencies leading to an optimal time frequency resolution in all frequency ranges i.e. it holds the multiresolution properties). In mathematics, a wavelet series is a representation of square integrable which can be real or complex valued function. A wavelet is a wave like oscillation with amplitude that begins at zero, increases and then decreases back to zero. Wavelets are generally crafted to have specific properties that make them useful for signal processing. Wavelets can be combined using a reverse, shift, multiply and integrate technique known as convolution.13 Wavelets transforms are broadly divided into three classes: continuous, discrete, and multiresolution-based.

Continuous Wavelet Transform (CWT)

In continuous wavelet transform, a given signal of finite energy is projected on a continuous family of frequency bands.

Equation 1

where * denotes complex conjugation.

The above equation shows a function f (t) is decomposed into a set of basis functions Ψs,τ (t), called the wavelets. The variable and τ, are scale and translation

Inverse Continuous wavelet transforms

Equation 2

The wavelets are generated from a single basic wavelet Ψ (t) , so called mother wavelet, by scaling and translation

Equation 3

In equation no. 3 ‘s’ is the scale factor, ‘τ’ is the translation factor and the factor

Vol10No4_Wav_Nit_for1

is for energy normalization across the different scales.

Wavelet properties

Admissibility condition: It is the most important property of wavelets.

Equation 4

this admissibility condition is used to first analyze and then reconstruct a signal without loss of information. In equation (4) ‘Ψ(ω)’ is the Fourier Transform of ‘Ψ(ω)’. The admissibility condition implies that the Fourier Transform of ‘Ψ(t)’ vanishes at the zero frequency i.e.

Equation 5

a zero at the zero frequency also means that the average value of the wavelet in the time domain must be zero, and it must be oscillatory.

Equation 6

also ‘Ψ(t)’ must be a wave.

The admissibility condition gave the wave, regularity and vanishing moments gave the fast decay.13

Discrete Wavelet Transform (DWT)

It is just another form of representing the signal and does not change the information content in the signal. The wavelet series is simply a sampled version of the continuous wavelet transform and the information provided by it is highly redundant as far as the reconstruction of the signal is concerned. DWT is more efficient in removing redundancy than continuous wavelet transform. It provides sufficient information both for the analysis and synthesis of the original signal. DWT is easy to implement, reduces the computation time and also resource required in comparison to CWT. To yield high computation of wavelet transform, DWT is based on sub-band coding.9

Discrete wavelets are applied to discrete data sets and produce discrete outputs. DWT decomposes the signal into mutually orthogonal set of wavelets and this is the main difference of DWT from CWT. It is a very common discretization of CWT and also a very redundant representation. It consists of setting the shift and scale value as: 13,14,15,16

Vol10No4_Wav_Nit_for2

Where and k are integers and s0 is real value >1.

Also, a practical choice of τand sconsists on setting Sto 2 and τ1 i.e.  s = 2and τ = k.2.

Hence this is called dyadic wavelet transform and in this case the wavelet transform becomes

Equation 7

On setting norm of scale and shift parameters consisting an orthonormal basis for L(R) is given as:

Equation 8

and

Equation 9

Based on low pass and high pass filters, the DWT consists of applying the discrete signal to a bank of octave band filters. The function f (t) is expressed as:

Equation 10

with

Equation 11,12

Where, Φ (t) is the scaling function associated with the wavelet function Ψ(t) that is governed by the condition:

Equation 13

 Figure 3: Sub Band Decomposition of Discrete Figure 3: Sub Band Decomposition of Discrete

 

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Wavelet Transform Implementation

The above figure shows a sub band decomposition of wavelet transform implementation or procedure (scheme) for multiresolution decomposition of a signal given by x[n]. In this scheme, each stage consists of high pass and low pass filters. These filters are basically digital filters. It also consists of two down sampler by 2. In this scheme, the first type of filter is high pass in nature and the second filter is low pass filter in nature. The second type of filter is basically a mirror version to the first filter. The down sampled outputs of first high pass filter and low pass filter helps in providing the detail D1and the A1 as the approximation. These approximations are further decomposed and the same process is being continued.

Data Set Used

The data for this work has been extracted from Kocaeli University Research Funding Center (Project Number: 2010/003).20

Classification Techniques

In this, experimental work, the artificial neural network and support vector machine are used as classifiers for the classification of EEG signal as normal or epileptic.

 Figure 4: Classification Steps Figure 4: Classification Steps

 

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Artificial Neural Network (ANN)

An artificial neural network is an interconnected group of nodes. In machine learning, ANNs are family of statistical learning algorithms. It is an electronic model based on the neural structure of the brain. Basically, ANNs are computing systems made up of large number of firmly interconnected adaptive processing elements (neurons). These elements perform massively parallel computations for data processing and knowledge representation. Learning in ANNs is accomplished through special training algorithm. ANNs can be trained to recognize the non-linear models and patterns developed during training.4 ANNs have evolved as a powerful tool for classification, pattern recognition, prediction as well as pattern completion. It is an inspiration from biological neurons.9

Support Vector Machine (SVM)

SVM is a new kind of classifier that is motivated by or based on two concepts. First concept includes transforming of data into a high dimensional space. This concept can transform complex problems (with complex decision surfaces) into simpler problems that use linear discriminant functions. And the second concept of SVMs are motivated by  training and using only those inputs that are near to the decision surface as they provide the most important information about the classification.9 The SVM algorithm is based on the statistical learning theory. SVM is used for data classification, pattern recognition, bioinformatics applications and also for regression analysis because of their accuracy and ability to deal with large number of predictors. The support vector classifier has many advantages in its own. In SVM, Nonlinear boundaries can be used without much extra computational effort. Moreover, performance of SVM is very competitive with other methods. A drawback of SVM is the problem complexity which is not of the order of the dimension of the samples, but of the order of the number of samples.8

Experimental Result and Discussion

In the present work, we have found the classification results expressed in terms of parameters such as sensitivity, specificity and accuracy; we have first extracted the features of the EEG signal. The feature extraction was done using wavelet transform. For wavelet, Discrete wavelet transform is used for feature extraction and the type of wavelet used for feature extraction application is Daubechies wavelet i.e. db3 (level=3). The EEG signal is first decomposed using wavelet decomposition scheme into wavelet coefficients using db3 (level =3) for reducing signal dimension. These decomposed coefficients are used as features wchich describes the signal.

After extracting the features of the EEG signal, classification is done. In this work, Artificial Neural Network (ANN) and Support Vector Machine (SVM) are used as classifiers normal as well as epileptic. The information obtained after feature extraction are fed to the classifiers as input to the classifiers.

Classification using Artificial Neural Network (ANN)

10 Hidden layer is created in ANN based classification of the EEG signal. Leven-berg-Marquardt function is used for training purpose and performance checking Mean squared error is used. Feed Forward net function is used to create the desired network. Train function is used to train the network using train ln function. 80:20 ratios are kept for training and testing.

Classification using Support Vector Machine (SVM)

For SVM based classification, Gaussian radial basis function which is known as kernel is used for training the dataset. The ratio of 80:20 is used for training and testing. For the final analysis confusion matrix is used to calculate the recognition rate.

Parameters such as Sensitivity which is also known as true positive ratio (TPR), Specificity also known as true negative ratio (TNR) and Accuracy are used to test the performance analysis of classifier.10

Sensitivity

Number of true positive decisions / Number of actually positive decisions

Vol10No4_Wav_Nit_for3

Specificity

Number of true negative decisions / Number of actually negative decisions

Vol10No4_Wav_Nit_for4

Accuracy

Number of correct decisions / Total number of cases

Table 1: Classification using ANN

Method (Using SVM) Accuracy Sensitivity Specificity
Wavelet 85.46 85.00 87.77

Table 2: Classification using ANN

Method (Using ANN) Accuracy Sensitivity Specificity
Wavelet 96.00 100.00 77.77

Conclusion

Visual inspection of signals does not provide much information regarding about the health of individual. We have proposed a wavelet based feature extraction technique for epileptic EEG signal classification. In our implemented work, the parameters such as accuracy, sensitivity and specificity are calculated and for these parameters we have drawn following conclusions:

ANN classified the EEG signal having accuracy 96%, sensitivity 100% and specificity 77.77% for wavelet feature extraction. For SVM classifier we have achieved accuracy 85.46%, sensitivity 90% and specificity 89% for wavelet feature extraction.

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