Affect recognition using EEG signal

2012 IEEE 14th International Workshop on Multimedia Signal Processing (MMSP) Pub Date : 2012-11-12 DOI:10.1109/MMSP.2012.6343458

Haiyan Xu, K. Plataniotis

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引用次数: 44

Abstract

Emotion states greatly influence many areas in our daily lives, such as: learning, decision making and interaction with others. Therefore, the ability to detect and recognize one's emotional states is essential in intelligence Human Machine Interaction (HMI). The aim of this study was to develop a new system that can sense and communicate emotion changes expressed by the Central Nervous System (CNS) through the use of EEG signals. More specifically, this study was carried out to develop an EEG-based subject-dependent affect recognition system to quantitatively measure and categorize three affect states: Positively excited, neutral and negatively excited. In this paper, we discussed implementation issues associated with each key stage of a fully automated affect recognition system: emotion elicitation protocol, feature extraction and classification. EEG recordings from 5 subjects with IAPS images as stimuli from the eNTERFACE06 database were used for simulation purposes. Discriminating features were extracted in both time and frequency domains (statistical, narrow-band, HOC, and wavelet entropy) to better understand the oscillatory nature of the brain waves. Through the use of k Nearest Neighbor classifier (kNN), we obtained mean correct classification rates of 90.77% on the three emotion classes when K equals 5. This demonstrated the feasibility of brain waves as a mean to categorize a user's emotion state. Secondly, we also assessed the suitability of commercially available EEG headsets such as Emotive Epoc for emotion recognition applications. This study was carried out by comparing the sensor location, signal integrity with those of Biosemi Active II. A new set of recognition performance was presented with reduced number of channels.

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利用脑电信号影响识别

情绪状态极大地影响着我们日常生活的许多领域，例如:学习、决策和与他人的互动。因此，检测和识别一个人的情绪状态的能力在智能人机交互(HMI)中是必不可少的。本研究的目的是开发一种新的系统，可以通过脑电图信号感知和交流中枢神经系统(CNS)表达的情绪变化。更具体地说，本研究开发了一个基于脑电图的受试者依赖情感识别系统，定量测量和分类三种情感状态:积极兴奋、中性和消极兴奋。在本文中，我们讨论了与全自动情感识别系统的每个关键阶段相关的实现问题:情感激发协议，特征提取和分类。5名受试者的脑电图记录以eNTERFACE06数据库中的IAPS图像作为刺激进行模拟。在时域和频域(统计、窄带、HOC和小波熵)提取判别特征，以更好地理解脑电波的振荡性质。通过使用k最近邻分类器(kNN)，当k = 5时，我们获得了三种情绪类别的平均正确分类率为90.77%。这证明了脑电波作为一种对用户情绪状态进行分类的手段的可行性。其次，我们还评估了商用脑电图耳机(如Emotive Epoc)在情绪识别应用中的适用性。本研究将传感器的位置、信号完整性与Biosemi Active II进行了比较。通过减少信道数，提出了一套新的识别性能。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

2012 IEEE 14th International Workshop on Multimedia Signal Processing (MMSP)

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