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人脸微表情识别综述

徐峰 张军平

徐峰, 张军平. 人脸微表情识别综述. 自动化学报, 2017, 43(3): 333-348. doi: 10.16383/j.aas.2017.c160398
引用本文: 徐峰, 张军平. 人脸微表情识别综述. 自动化学报, 2017, 43(3): 333-348. doi: 10.16383/j.aas.2017.c160398
XU Feng, ZHANG Jun-Ping. Facial Microexpression Recognition: A Survey. ACTA AUTOMATICA SINICA, 2017, 43(3): 333-348. doi: 10.16383/j.aas.2017.c160398
Citation: XU Feng, ZHANG Jun-Ping. Facial Microexpression Recognition: A Survey. ACTA AUTOMATICA SINICA, 2017, 43(3): 333-348. doi: 10.16383/j.aas.2017.c160398

人脸微表情识别综述

doi: 10.16383/j.aas.2017.c160398
基金项目: 

浦江人才计划 16PJD009

国家自然科学基金 61273299

国家自然科学基金 61673118

详细信息
    作者简介:

    徐峰复旦大学计算机科学技术学院硕士研究生.主要研究方向为计算机视觉, 人脸表情识别.E-mail:fengxu@fudan.edu.cn

    通讯作者:

    张军平复旦大学计算机科学技术学院教授.主要研究方向为机器学习, 智能交通, 生物认证与图像识别.本文通信作者.E-mail:jpzhang@fudan.edu.cn

Facial Microexpression Recognition: A Survey

Funds: 

Shanghai Pujiang Program 16PJD009

National Natural Science Foundation of China 61273299

National Natural Science Foundation of China 61673118

More Information
    Author Bio:

    Master student at the School of Computer Science, Fudan University. His research interest covers computer vision and facial expression recognition

    Corresponding author: ZHANG Jun-PingProfessor at the School of Computer Science, Fudan University. His research interest covers machine learning, intelligent transportation systems, biometric authentication, and image processing. Corresponding author of this paper
  • 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.
    1)  本文责任编委 赖剑煌
  • 图  1  微表情识别中的具体任务

    Fig.  1  Specific tasks in microexpression recognition

    图  2  微表数据集示例

    Fig.  2  Examples of microexpression datasets

    图  3  一个3×3的图像块及其对应的像素值

    Fig.  3  A 3×3 image patch and the corresponding pixel values

    图  4  局部二值模式计算过程

    Fig.  4  Calculation process of local binary pattern

    图  5  LBP-TOP示例[34]

    Fig.  5  Illustration of LBP-TOP[34]

    图  6  LBP-SIP示例

    Fig.  6  Illustration of LBP-SIP

    图  7  中心化二值模式计算过程

    Fig.  7  Calculation process of centralized binary pattern

    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
    下载: 导出CSV

    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)
    下载: 导出CSV

    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
    下载: 导出CSV
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出版历程
  • 收稿日期:  2016-05-15
  • 录用日期:  2016-07-28
  • 刊出日期:  2017-03-20

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