Seyyed Abed Hosseini

Work place: Control Field Islamic Azad University-Mashhad Branch, Mashhad, Iran

E-mail: abed_hosseyni@yahoo.com

Website:

Research Interests: Human-Computer Interaction, Analysis of Algorithms, Program Analysis and Transformation

Biography

Seyyed Abed Hosseini was born in 1984 in Quchan, Iran. He received the B.S. degree in electronics from the Sadjad Institute of higher education, Mashhad, Iran, in 2006, and the M.S. degree in biomedical engineering from the Islamic Azad University of Mashhad, Mashhad, Iran, in 2009. He is currently Ph.D. student at the Control Engineering of the Ferdowsi University of Mashhad, Iran. His research interests include recognition of emotional stress states based on the analysis of EEG and psychophysiological signals in order to improve human–computer interaction, biomedical signal processing, functional brain modeling, nonlinear and chaos analysis and digital design with FPGA and CPLD. He is a member of the Iranian Society for Biomedical Engineering, Tehran, Iran. He has authored over 30 journal and conference papers.

Author Articles
Nonlinear Analysis of EEG Dynamics in Different Epilepsy States Using Lagged PoincarÉ Maps

By Seyyed Abed Hosseini

DOI: https://doi.org/10.5815/ijigsp.2018.08.07, Pub. Date: 8 Aug. 2018

The Poincaré map and its width and length are known as a criterion for short-term variations of electroencephalogram (EEG) signals. This study evaluates the effect of time delay on changes in the width of the Poincaré map in the EEG signal during different epilepsy states. The Poincaré map is quantified by measuring the standard deviation over   (SD1) and the standard deviation over   (SD2). Poincaré maps are drawn with one to six delay in three sets, including normal, inter-ictal, and ictal. The results indicate that the width of the Poincaré map increases with increasing latency in the ictal state. During ictal state, the width of the Poincaré map is achieved by applying a unit delay of 102 ± 8.7 and a six-unit delay of 305 ± 13.6. The Poincaré map is shifted to lower values during ictal state. Also, the results indicate that with increasing delay in the ictal state, the increasing rate of SD1 value is higher than the previous ones, such as inter-ictal and normal. The Poincaré map of the EEG signal can discover the meaningful changes in the different epilepsy states. 

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Classification of Brain Activity in Emotional States Using HOS Analysis

By Seyyed Abed Hosseini

DOI: https://doi.org/10.5815/ijigsp.2012.01.03, Pub. Date: 8 Feb. 2012

This paper proposes an emotion recognition system using EEG signals and higher order spectra. A visual induction based acquisition protocol is designed for recording the EEG signals in five channels (FP1, FP2, T3, T4 and Pz) under two emotional states of participants, calm-neutral and negatively exited. After pre-processing the signals, higher order spectra are employed to extract the features for classifying human emotions. We used Genetic Algorithm (GA) and Support vector machine (SVM) for optimum features selection for the classifier. In this research, we achieved an average accuracy of 82.32% for the two emotional states using Linear Discriminant Analysis (LDA) classifier. We concluded that, HOS analysis could be an accurate tool in the assessment of human emotional states. We achieved to same results compared to our previous studies.

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Emotion recognition method using entropy analysis of EEG signals

By Seyyed Abed Hosseini Mohammad Bagher Naghibi-Sistani

DOI: https://doi.org/10.5815/ijigsp.2011.05.05, Pub. Date: 8 Aug. 2011

This paper proposes an emotion recognition system using EEG signals, therefore a new approach to emotion state analysis by approximate (ApEn) and wavelet entropy (WE) is described. We have used EEG signals recorded during emotion in five channels (FP1, FP2, T3, T4 and Pz), under pictures induction environment (calm-neutral and negative excited) for participants. After a brief introduction to the concept, the ApEn and WE were extracted from two different EEG time series. The result showed that, the classification accuracy in two emotion states was 73.25% using the support vector machine (SVM) classifier. The simulations showed that the classification accuracy is good and the proposed methods are effective. During an emotion, the EEG is less complex compared to the normal, indicating reduction in active neuronal process in the brain.

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