模拟初级视皮层注意机制的运动对象检测模型

doi:10.3969/j.issn.1000-3428.2014.06.031

计算机工程

模拟初级视皮层注意机制的运动对象检测模型

曾杰，谌先敢，高智勇，刘海华

(中南民族大学生物医学工程学院，武汉 430074)

收稿日期:2013-08-15 出版日期:2014-06-15 发布日期:2014-06-13
作者简介:曾杰(1988－)，男，硕士研究生，主研方向：计算机视觉；谌先敢，讲师、博士；高智勇，副教授；刘海华(通讯作者)，教授。
基金资助:
国家自然科学基金资助项目(60972158)；湖北省自然科学基金资助重点项目(2011CDA078)。

Motion Object Detection Model Simulating Primary Visual Cortex Attention Mechanism

ZENG Jie, SHEN Xian-gan, GAO Zhi-yong, LIU Hai-hua

(College of Biomedical Engineering, South Central University for Nationalities, Wuhan 430074, China)

Received:2013-08-15 Online:2014-06-15 Published:2014-06-13

摘要/Abstract

摘要： 视频监控的广泛应用使运动对象检测成为研究热点，但运动的不确定性增加了检测难度。鉴于人类视觉系统能高效地感知运动对象，研究者从神经生理学和心理学的角度提出了运动检测的生物学模型。根据上述研究成果，提出模拟初级视皮层的运动对象检测模型。使用三维Gabor时空滤波器模拟人类初级视皮层中简单细胞的经典感受野，通过非线性组合获取复杂细胞对运动对象刺激响应的运动能量，应用细胞的中心环绕作用及相关性运动检测增强运动信息并抑制环境干扰，采用信息融合获取运动对象的显著性图，并利用WTA神经网络模型实现对运动目标的感知。实验结果表明，该模型能有效检测到视频中的运动目标，运算速度较其他仿视神经加工的视觉注意模型更快。

关键词: 运动对象检测, 时空显著性, Gabor滤波器, 神经网络, 初级视皮层

Abstract: With the wide application of video surveillance, motion detection becomes a research focus. However, it becomes more difficult due to a lot of uncertainty in motion. Based on the human visual system more efficiently to perceive moving objects, researchers construct the model of motion perception based on the view of physiology and psychology. According to these studies, this paper proposes a moving object detection model simulating primary visual cortex. In this model, Classical Receptive Field(CRF) of simple cells in primary visual cortex is simulated by the three-dimensional Gabor spatial-temporal filter, and the motion energy as complex cells response is obtained by a nonlinear combination. Two characteristics: center-surround of cells and correlation motion detection is used to enhance motion information and suppress environment interference, and more information is fused to obtain a saliency map of moving object. WTA neural network model is used to achieve the perception of motion object. Experimental results show that the model can effectively detect the moving object in the video, and compute faster than other visual attention models based on visual neurons processing.

Key words: motion object detection, spatial-temporal saliency, Gabor filter, neural network, primary visual cortex

中图分类号:

TP18

曾杰，谌先敢，高智勇，刘海华. 模拟初级视皮层注意机制的运动对象检测模型[J]. 计算机工程, doi: 10.3969/j.issn.1000-3428.2014.06.031.

ZENG Jie, SHEN Xian-gan, GAO Zhi-yong, LIU Hai-hua. Motion Object Detection Model Simulating Primary Visual Cortex Attention Mechanism[J]. Computer Engineering, doi: 10.3969/j.issn.1000-3428.2014.06.031.

http://www.ecice06.com/CN/Y2014/V40/I6/142

参考文献

参考文献 [1] 张娟, 毛晓波, 陈铁军. 运动目标跟踪算法研究综述[J]. 计算机应用研究, 2009, 26(12): 4407-4410. [2] Stauffer C, Eric W, Grimson L. Learning Patterns of Activity Using Real-time Tracking[J]. IEEE Transactions on Pattern Analysis and Machine Intelligence, 2000, 22(8): 747-756. [3] 叶勇, 管业鹏, 李晶晶. 融合高斯模型的编码本前景检测方法[J]. 计算机工程, 2012, 38(21): 1-4. [4] Itti L, Koch C, Niebur E. A Model of Saliency-based Visual Attention for Rapid Scene Analysis[J]. IEEE Transactions on Pattern Analysis and Machine Intelligence, 1998, 20(11): 1254-1259. [5] Itti L, Baldi P. A Principled Approach to Detecting Surprising Events in Video[C]//Proc. of IEEE Computer Society Conference on Computer Vision and Pattern Recognition. San Diego, USA: IEEE Computer Society, 2005: 631-637. [6] Zhai Yun, Shah M. Visual Attention Detection in Video Sequence Using Spatiotemporal Cues[C]//Proc. of the 14th ACM International Conference on Multimedia. Santa Barbara, USA: ACM Press, 2006: 815-824. [7] Liu Chang, Yuen P C, Qiu Guoping. Object Motion Detection Using Information Theoretic Spatio-temporal Saliency[J]. Pattern Recognition, 2009, 42(11): 2897-2906. [8] Guo Wen, Xu Changsheng, Ma Songde, et al. Visual Attention Based Motion Object Detection and Trajectory Tracking[C]// Proc. of 2010 Pacific-Rim Conference on Multimedia. Berlin, Germany: Springer-Verlag, 2010: 462-470. [9] Petkov N, Subramanian E. Motion Detection, Noise Reduction, Texture Suppresion and Contour Enhancement by Spatio- temporal Gabor Filters with Surround Inhibition[J]. Biological Cybernetics, 2007, 97(5/6): 423-439. [10] Reichardt W. Autocorrelation, a Principle for Evaluation of Sensory Information by the Central Nervous System[M]// Rosenblith W A. Sensory Communications. Cambridge, USA: MIT Press, 1961: 303-317. [11] Adelson H, Bergen J R. Spatiotemporal Energy Models for the Perception for Motion[J]. Journal of the Optical Society of America, 1985, 2(2): 284-299. [12] Hubel D H, Wiesel T N. Receptive Fields, Binocular Interaction and Functional Architecture in the Cat’s Visual Cortex[J]. Physiol, 1962, 160: 106-154. [13] Bayerl P, Neumann H. Disambiguating Visual Motion by Form-motion Interaction——A Computational Model[J]. Inter- national Journal of Computer Vision, 2007, 72(1): 27-45. [14] Jones H, Grieve K L, Wang W, et al. Surround Suppression in Primate V1[J]. Artificial Intelligence, 2003, 146(1): 77-123. [15] Raiguel S, van Hulle M M, Xiao D K, et al. Shape and Spatial Distribution of Receptive Fields and Antagonistic Motion Surrounds in the Middle Temporal Area(V5) of the Macaque[J]. European Journal of Neuroscience, 1995, 7(10): 2064-2082. [16] Koch C, Ulman S. Shifts in Selective Visual Attention: Towards the Underlying Neural Circuitry[J]. Human Neuro- biology, 1985, 4(4): 219-227. [17] Wauthier F. Motion Tracking Project Synopsis[EB/OL]. [2013-07-12]. http://www.cs.berkeley.edu/~flw/tracker/. [18] Harel J, Koch C, Perona P. Graph-based Visual Saliency[J]. Advances in Neural Information Processing Systems, 2007, 19: 545-552. 编辑金胡考

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