A novel approach to signal classification with an application to identifying the alcoholic brain

Graphical abstractDisplay Omitted HighlightsEvolving temporal pattern detectors for signal classification.We make no assumptions regarding the spectral characteristics of the data.The classification accuracies are comparable to the conventional techniques.Located EEG-sensors that showed abnormal electrical behavior for the alcoholics.Evolutionary learning paradigm unified feature extraction and classification steps. We introduce a novel approach to signal classification based on evolving temporal pattern detectors (TPDs) that can find the occurrences of embedded temporal structures in discrete time signals and illustrate its application to characterizing the alcoholic brain using visually evoked response potentials. In contrast to conventional techniques used for most signal classification tasks, this approach unifies the feature extraction and classification steps. It makes no prior assumptions regarding the spectral characteristics of the data; it merely assumes that some temporal patterns exist that distinguish two classes of signals and therefore could be applied to new signal classification tasks where a body of prior work identifying important features does not exist. Evolutionary computation (EC) discovers a classifier by simply learning from the time series samples.The alcoholic classification (AC) problem consists of 2 sub-tasks, one spatial and one temporal: choosing a subset of electroencephalogram leads used to create a composite signal (the spatial task), and detecting temporal patterns in this signal that are more prevalent in the alcoholics than the controls (the temporal task). To accomplish this, a novel representation and crossover operator were devised that enable multiple feature subset tasks to be solved concurrently. Three TPD techniques are presented that differ in the mechanism by which partial credit is assigned to temporal patterns that deviate from the specified pattern. An EC approach is used for evolving a subset of sensors and the TPD specifications. We found evidence that partial credit does help evolutionary discovery. Regions on the skull of an alcoholic subject that produced abnormal electrical activity compared to the controls were located. These regions were consistent with prior findings in the literature. The classification accuracy was measured as the area under the receiver operator characteristic curve (ROC); the ROC area for the training set varied from 90.32% to 98.83% and for the testing set it varied from 87.17% to 95.9%.

[1]  Syed Amjad Ali,et al.  A GA based Window Selection Methodology to Enhance Window based Multi wavelet transformation and thresholding aided CT image denoising technique , 2010, ArXiv.

[2]  Nicholas J. Radcliffe,et al.  Genetic Set Recombination , 1992, FOGA.

[3]  J. David Schaffer,et al.  New crossover operators for multiple subset selection tasks , 2014, ArXiv.

[4]  Arnab Roy Evolving spike neural network based spatio-temporal pattern classifiers with an application to identifying the alcoholic brain , 2014 .

[5]  H. Begleiter,et al.  Do chronic alcoholics have intact implicit memory? An ERP study. , 1997, Electroencephalography and clinical neurophysiology.

[6]  Ramaswamy Palaniappan Improved Automated Classification of Alcoholics and Non-alcoholics , 2008 .

[7]  Byung Ro Moon,et al.  Hybrid Genetic Algorithms for Feature Selection , 2004, IEEE Trans. Pattern Anal. Mach. Intell..

[8]  N. Sriraam,et al.  EEG based detection of alcoholics using spectral entropy with neural network classifiers , 2012, 2012 International Conference on Biomedical Engineering (ICoBE).

[9]  Jack Sklansky,et al.  A note on genetic algorithms for large-scale feature selection , 1989, Pattern Recognit. Lett..

[10]  Mark Simpson,et al.  A Genetic Algorithm Approach for Discovering Diagnostic Patterns in Molecular Measurement Data , 2005, 2005 IEEE Symposium on Computational Intelligence in Bioinformatics and Computational Biology.

[11]  Larry J. Eshelman,et al.  The CHC Adaptive Search Algorithm: How to Have Safe Search When Engaging in Nontraditional Genetic Recombination , 1990, FOGA.

[12]  R. Boggia,et al.  Genetic algorithms as a strategy for feature selection , 1992 .

[13]  Raveendran Paramesran,et al.  Using genetic algorithm to identify the discriminatory subset of multi-channel spectral bands for visual response , 2002, Appl. Soft Comput..

[14]  Chong-Yaw Wee,et al.  Selection of a Subset of EEG Channels using PCA to classify Alcoholics and Non-alcoholics , 2005, 2005 IEEE Engineering in Medicine and Biology 27th Annual Conference.

[15]  Ramaswamy Palaniappan Screening for Chronic Alcoholic Subjects Using Multiple Gamma Band EEG: A Pilot Study , 2007 .

[16]  R. Stolzenberg,et al.  Multiple Regression Analysis , 2004 .

[17]  Jihoon Yang,et al.  Feature Subset Selection Using a Genetic Algorithm , 1998, IEEE Intell. Syst..

[18]  Gerrit Kateman,et al.  Towards Solving Subset Selection Problems with the Aid of the Genetic Algorithm , 1992, PPSN.

[19]  Hongbin Zhang,et al.  Feature selection using tabu search method , 2002, Pattern Recognit..

[20]  J. David Schaffer,et al.  Evolving Spike Neural Network Sensors to Characterize the Alcoholic Brain Using Visually Evoked Response Potential , 2013, Complex Adaptive Systems.

[21]  Reza Azmi,et al.  Fabric Textile Defect Detection, By Selecting A Suitable Subset Of Wavelet Coefficients, Through Genetic Algorithm , 2011 .

[22]  Jason Weston,et al.  Gene Selection for Cancer Classification using Support Vector Machines , 2002, Machine Learning.

[23]  Paul F. Hoogendijk,et al.  Code Compaction Using Genetic Algorithms , 2000, GECCO.

[24]  Keith E. Mathias,et al.  Convergence Controlled Variation , 1996, FOGA.

[25]  Ramaswamy Palaniappan Discrimination of Alcoholic Subjects using Second Order Autoregressive Modelling of Brain Signals Evoked during Visual Stimulus Perception , 2005, IEC.

[26]  Natarajan Sriraam,et al.  EEG Based Detection of Alcoholics: A Selective Review , 2012 .