Real-time tracking of multiple objects in space-variant vision based on magnocellular visual pathway

Abstract In this paper, we propose a space-variant image representation model based on properties of magnocellular visual pathway, which perform motion analysis, in human retina. Then, we present an algorithm for the tracking of multiple objects in the proposed space-variant model. The proposed space-variant model has two effective image representations for object recognition and motion analysis, respectively. Each image representation is based on properties of two types of ganglion cell, which are the beginning of two basic visual pathways; one is parvocellular and the other is magnocellular. Through this model, we can get the efficient data reduction capability with no great loss of important information. And, the proposed multiple objects tracking method is restricted in space-variant image. Typically, an object-tracking algorithm consists of several processes such as detection, prediction, matching, and updating. In particular, the matching process plays an important role in multiple objects tracking. In traditional vision, the matching process is simple when the target objects are rigid. In space-variant vision, however, it is very complicated although the target is rigid, because there may be deformation of an object region in the space-variant coordinate system when the target moves to another position. Therefore, we propose a deformation formula in order to solve the matching problem in space-variant vision. By solving this problem, we can efficiently implement multiple objects tracking in space-variant vision.

[1]  Andrew B. Watson,et al.  Detection and Recognition of Simple Spatial Forms , 1983 .

[2]  Frédéric Jurie,et al.  A new log-polar mapping for space variant imaging.: Application to face detection and tracking , 1999, Pattern Recognit..

[3]  Martin D. Levine,et al.  A Real-Time Foveated Sensor with Overlapping Receptive Fields , 1997, Real Time Imaging.

[4]  A. Murat Tekalp,et al.  Digital Video Processing , 1995 .

[5]  R. W. Dltchburn Vision and the eye, 2nd edition , 1968 .

[6]  A. Cowey,et al.  Retinal ganglion cells that project to the dorsal lateral geniculate nucleus in the macaque monkey , 1984, Neuroscience.

[7]  Giulio Sandini,et al.  Space-variant vision for an active camera mount , 1995, Defense, Security, and Sensing.

[8]  François Brémond,et al.  Tracking multiple nonrigid objects in video sequences , 1998, IEEE Trans. Circuits Syst. Video Technol..

[9]  Larry S. Davis,et al.  Hydra: multiple people detection and tracking using silhouettes , 1999, Proceedings 10th International Conference on Image Analysis and Processing.

[10]  Yehoshua Y. Zeevi,et al.  Reorganization and diversification of signals in vision , 1985, IEEE Transactions on Systems, Man, and Cybernetics.

[11]  Stewart W. Wilson On the Retino-Cortical Mapping , 1983, Int. J. Man Mach. Stud..

[12]  Svetha Venkatesh,et al.  Tracking in a space variant active vision system , 1996, Proceedings of 13th International Conference on Pattern Recognition.

[13]  M. H. Pirenne,et al.  VISION AND THE EYE , 1949 .

[14]  Seong-Whan Lee,et al.  Multiple Object Tracking in Multiresolution Image Sequences , 2000, Biologically Motivated Computer Vision.

[15]  HIROYUKI YAMAMOTO,et al.  An Active Foveated Vision System: Attentional Mechanisms and Scan Path Covergence Measures , 1996, Comput. Vis. Image Underst..