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摘要: 人脸表情是人际交往的重要渠道,识别人脸表情可促进对人心理状态和情感的理解.不同于常规的人脸表情,微表情是一种特殊的面部微小动作,可以作为判断人主观情绪的重要依据,在公共安防和心理治疗领域有广泛的应用价值.由于微表情具有动作幅度小、持续时间短的特点,对微表情的人工识别需要专业的培训,且识别正确率较低.近年来不少研究人员开始利用计算机视觉技术自动识别微表情,极大地提高了微表情的应用可行性.本文综述人脸微表情识别的定义和研究现状,总结微表情识别中的一些关键技术,探讨潜在的问题和可能的研究方向.Abstract: Facial expression is an important channel in social interaction. Reading facial expression can improve understanding of psychological condition and emotional status. Different from normal expressions, microexpression is a special kind of subtle facial action. It serves as a vital clue for affective estimation, and has broad applications in public security and psychological treatment. Recognizing microexpression requires professional training for human due to its short duration and subtle movement. So far a low recognition accuracy has been reported in the literature. In recent years, researchers have been studying microexpression recognition based on computer vision, which can largely improve the feasibility of such recognition. In this article, we introduce problem definition and current research status of microexpression, survey several representative techniques in this topic, and discuss some underlying issues and potential research directions.1) 本文责任编委 赖剑煌
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表 1 现有微表情数据集
Table 1 Existing datasets of microexpressions
数据集 帧率 #被试 #微表情 #非微表情 诱导方式 标注方法 SMIC 100 6 76 76 自发 情绪 SMIC2/HS 100 20 164 164 自发 情绪 SMIC2/VIS 25 10 71 71 自发 情绪 SMIC2/NIR 25 10 71 71 自发 情绪 CASME 60 35 195 / 自发 情绪/FACS CASMEⅡ 200 35 247 / 自发 情绪/FACS USF-HD 29.7 / 100 181 模仿 微/非微表情 Polikovsky 200 10 / / 模仿 FACS 
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表 2 现有微表情识别方法的识别准确率 (%) 对比
Table 2 Recognition accuracy (%) of existing approaches on common datasets
方法 CASME CASMEⅡ LBP-TOP[23] 37.43(4类) 46.46(5类) STCLQP[36] 57.31(4类) 58.39(5类) LBP-SIP[37] 36.84(4类) 46.56(5类) DTCM[38] 64.95(4类) N/A TICS[43-44] 61.86(4类) 62.30(4类) STLBP-IP[45] N/A 59.51(5类) FDM[47] 56.14(5类) 45.93(5类) MDMO[48] 64.07(4类) 57.16(4类) DTSA[51] 46.90(5类) N/A MMPTR[54] N/A 80.2(4类) RPCA+LSDF[55] N/A 65.45(4类) Riesz小波[58] N/A 46.15(4类) EVM[59] N/A 67.21(4类)
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表 3 现有微表情识别方法
Table 3 Existing approaches for microexpression recognition
方法 预处理方法 特征表达 学习算法 解决问题 文献[23] ASM、LWM、TIM LBP-TOP SVM、RF、MKL 检测/分类 文献[27, 70] ASM Strain tensor 阈值 检测 文献[28] ASM、面部分块 时空梯度 近邻投票 检测/分类 文献[36] ASM、TIM STCLQP SVM 检测/分类 文献[37] N/A LBP-SIP SVM 检测/分类 文献[38] AAM DTCM SVM、RF 检测/分类 文献[41] ASM Gabor GentlSVM 检测/分类 文献[42] N/A Gabor LDA、PCA、SVM 分类 文献[43-44] ASM TICS+LBP-TOP SVM 检测/分类 文献[45] N/A STLBP-IP SVM 检测/分类 文献[47] 光流场修正 FDM SVM 检测/分类 文献[48] DRMF、光流场对齐 MDMO SVM 检测/分类 文献[51] N/A DTSA变换 ELM 检测/分类 文献[53] ASM STCCA 最近邻 检测/分类 文献[54] N/A MMPTR变换 最近邻 检测/分类 文献[55] ASM、面部分块 RPCA+LSDF SVM 检测/分类 文献[57] 面部检测、分割 CBP-TOP ELM 分类 文献[58] N/A Riesz小波 MKL 分类 文献[59] ASM、LWM、TIM EVM处理后提前特征 SVM 分类 文献[62] N/A 特征点追踪 MKL 特定AU识别 文献[64] STASM、Procuste分析 几何形变特征 随机过程计算概率 检测 文献[66] 特征点定位 基于LBP的差异特征 阈值 检测 文献[67] DRMF 光流场 基于规则 阶段分割 文献[68] CLM CLM、LBP 基于规则 顶点定位 文献[71] N/A 时间平滑的Optical Strain SVM 检测/分类
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