EEG-Based Learning System for Online Motion Sickness Level Estimation in a Dynamic Vehicle Environment

Motion sickness is a common experience for many people. Several previous researches indicated that motion sickness has a negative effect on driving performance and sometimes leads to serious traffic accidents because of a decline in a person's ability to maintain self-control. This safety issue...

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Veröffentlicht in:	IEEE transaction on neural networks and learning systems 2013-10, Vol.24 (10), p.1689-1700
Hauptverfasser:	LIN, Chin-Teng, TSAI, Shu-Fang, KO, Li-Wei
Format:	Artikel
Sprache:	eng
Schlagworte:	Algorithms Applied sciences Artificial intelligence Automobile Driving Brain - physiopathology Brain modeling Computer science control theory systems Computer systems and distributed systems. User interface Connectionism. Neural networks Driving cognition Electroencephalography electroencephalography (EEG) Electroencephalography - statistics & numerical data Estimation Exact sciences and technology Feature extraction Ground, air and sea transportation, marine construction Humans learning system Learning systems Monitoring systems Motion sickness Motion Sickness - physiopathology online estimation Pattern recognition. Digital image processing. Computational geometry Road transportation and traffic Signal Processing, Computer-Assisted Software Studies Task Performance and Analysis Time-frequency analysis User-Computer Interface
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creator	LIN, Chin-Teng TSAI, Shu-Fang KO, Li-Wei
description	Motion sickness is a common experience for many people. Several previous researches indicated that motion sickness has a negative effect on driving performance and sometimes leads to serious traffic accidents because of a decline in a person's ability to maintain self-control. This safety issue has motivated us to find a way to prevent vehicle accidents. Our target was to determine a set of valid motion sickness indicators that would predict the occurrence of a person's motion sickness as soon as possible. A successful method for the early detection of motion sickness will help us to construct a cognitive monitoring system. Such a monitoring system can alert people before they become sick and prevent them from being distracted by various motion sickness symptoms while driving or riding in a car. In our past researches, we investigated the physiological changes that occur during the transition of a passenger's cognitive state using electroencephalography (EEG) power spectrum analysis, and we found that the EEG power responses in the left and right motors, parietal, lateral occipital, and occipital midline brain areas were more highly correlated to subjective sickness levels than other brain areas. In this paper, we propose the use of a self-organizing neural fuzzy inference network (SONFIN) to estimate a driver's/passenger's sickness level based on EEG features that have been extracted online from five motion sickness-related brain areas, while either in real or virtual vehicle environments. The results show that our proposed learning system is capable of extracting a set of valid motion sickness indicators that originated from EEG dynamics, and through SONFIN, a neuro-fuzzy prediction model, we successfully translated the set of motion sickness indicators into motion sickness levels. The overall performance of this proposed EEG-based learning system can achieve an average prediction accuracy of ~82%.
doi_str_mv	10.1109/TNNLS.2013.2275003
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Several previous researches indicated that motion sickness has a negative effect on driving performance and sometimes leads to serious traffic accidents because of a decline in a person's ability to maintain self-control. This safety issue has motivated us to find a way to prevent vehicle accidents. Our target was to determine a set of valid motion sickness indicators that would predict the occurrence of a person's motion sickness as soon as possible. A successful method for the early detection of motion sickness will help us to construct a cognitive monitoring system. Such a monitoring system can alert people before they become sick and prevent them from being distracted by various motion sickness symptoms while driving or riding in a car. In our past researches, we investigated the physiological changes that occur during the transition of a passenger's cognitive state using electroencephalography (EEG) power spectrum analysis, and we found that the EEG power responses in the left and right motors, parietal, lateral occipital, and occipital midline brain areas were more highly correlated to subjective sickness levels than other brain areas. In this paper, we propose the use of a self-organizing neural fuzzy inference network (SONFIN) to estimate a driver's/passenger's sickness level based on EEG features that have been extracted online from five motion sickness-related brain areas, while either in real or virtual vehicle environments. The results show that our proposed learning system is capable of extracting a set of valid motion sickness indicators that originated from EEG dynamics, and through SONFIN, a neuro-fuzzy prediction model, we successfully translated the set of motion sickness indicators into motion sickness levels. The overall performance of this proposed EEG-based learning system can achieve an average prediction accuracy of ~82%.</description><identifier>ISSN: 2162-237X</identifier><identifier>EISSN: 2162-2388</identifier><identifier>DOI: 10.1109/TNNLS.2013.2275003</identifier><identifier>PMID: 24808604</identifier><identifier>CODEN: ITNNAL</identifier><language>eng</language><publisher>New York, NY: IEEE</publisher><subject>Algorithms ; Applied sciences ; Artificial intelligence ; Automobile Driving ; Brain - physiopathology ; Brain modeling ; Computer science; control theory; systems ; Computer systems and distributed systems. User interface ; Connectionism. 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Several previous researches indicated that motion sickness has a negative effect on driving performance and sometimes leads to serious traffic accidents because of a decline in a person's ability to maintain self-control. This safety issue has motivated us to find a way to prevent vehicle accidents. Our target was to determine a set of valid motion sickness indicators that would predict the occurrence of a person's motion sickness as soon as possible. A successful method for the early detection of motion sickness will help us to construct a cognitive monitoring system. Such a monitoring system can alert people before they become sick and prevent them from being distracted by various motion sickness symptoms while driving or riding in a car. 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The results show that our proposed learning system is capable of extracting a set of valid motion sickness indicators that originated from EEG dynamics, and through SONFIN, a neuro-fuzzy prediction model, we successfully translated the set of motion sickness indicators into motion sickness levels. The overall performance of this proposed EEG-based learning system can achieve an average prediction accuracy of ~82%.</description><subject>Algorithms</subject><subject>Applied sciences</subject><subject>Artificial intelligence</subject><subject>Automobile Driving</subject><subject>Brain - physiopathology</subject><subject>Brain modeling</subject><subject>Computer science; control theory; systems</subject><subject>Computer systems and distributed systems. User interface</subject><subject>Connectionism. 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User interface</topic><topic>Connectionism. Neural networks</topic><topic>Driving cognition</topic><topic>Electroencephalography</topic><topic>electroencephalography (EEG)</topic><topic>Electroencephalography - statistics & numerical data</topic><topic>Estimation</topic><topic>Exact sciences and technology</topic><topic>Feature extraction</topic><topic>Ground, air and sea transportation, marine construction</topic><topic>Humans</topic><topic>learning system</topic><topic>Learning systems</topic><topic>Monitoring systems</topic><topic>Motion sickness</topic><topic>Motion Sickness - physiopathology</topic><topic>online estimation</topic><topic>Pattern recognition. Digital image processing. 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Several previous researches indicated that motion sickness has a negative effect on driving performance and sometimes leads to serious traffic accidents because of a decline in a person's ability to maintain self-control. This safety issue has motivated us to find a way to prevent vehicle accidents. Our target was to determine a set of valid motion sickness indicators that would predict the occurrence of a person's motion sickness as soon as possible. A successful method for the early detection of motion sickness will help us to construct a cognitive monitoring system. Such a monitoring system can alert people before they become sick and prevent them from being distracted by various motion sickness symptoms while driving or riding in a car. In our past researches, we investigated the physiological changes that occur during the transition of a passenger's cognitive state using electroencephalography (EEG) power spectrum analysis, and we found that the EEG power responses in the left and right motors, parietal, lateral occipital, and occipital midline brain areas were more highly correlated to subjective sickness levels than other brain areas. In this paper, we propose the use of a self-organizing neural fuzzy inference network (SONFIN) to estimate a driver's/passenger's sickness level based on EEG features that have been extracted online from five motion sickness-related brain areas, while either in real or virtual vehicle environments. The results show that our proposed learning system is capable of extracting a set of valid motion sickness indicators that originated from EEG dynamics, and through SONFIN, a neuro-fuzzy prediction model, we successfully translated the set of motion sickness indicators into motion sickness levels. The overall performance of this proposed EEG-based learning system can achieve an average prediction accuracy of ~82%.</abstract><cop>New York, NY</cop><pub>IEEE</pub><pmid>24808604</pmid><doi>10.1109/TNNLS.2013.2275003</doi><tpages>12</tpages></addata></record>
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subjects	Algorithms Applied sciences Artificial intelligence Automobile Driving Brain - physiopathology Brain modeling Computer science control theory systems Computer systems and distributed systems. User interface Connectionism. Neural networks Driving cognition Electroencephalography electroencephalography (EEG) Electroencephalography - statistics & numerical data Estimation Exact sciences and technology Feature extraction Ground, air and sea transportation, marine construction Humans learning system Learning systems Monitoring systems Motion sickness Motion Sickness - physiopathology online estimation Pattern recognition. Digital image processing. Computational geometry Road transportation and traffic Signal Processing, Computer-Assisted Software Studies Task Performance and Analysis Time-frequency analysis User-Computer Interface
title	EEG-Based Learning System for Online Motion Sickness Level Estimation in a Dynamic Vehicle Environment
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