DocumentCode
1399109
Title
Compact Image Representation Model Based on Both nCRF and Reverse Control Mechanisms
Author
Hui Wei ; Xiao-Mei Wang ; Loi Lei Lai
Author_Institution
Dept. of Comput. Sci., Fudan Univ., Shanghai, China
Volume
23
Issue
1
fYear
2012
Firstpage
150
Lastpage
162
Abstract
The aim of this paper is to construct a bio-inspired hierarchical neural network that could accurately represent visual images and facilitate follow-up processing. Our computational model adopted a ganglion cell (GC) mechanism with a receptive field that dynamically self-adjusts according to the characteristics of an input image. For each GC, a micro neural circuit and a reverse control circuit were developed to self-adaptively resize the receptive field. An array was also designed to imitate the layer of GCs that perform image representation. Results revealed that this GC array could represent images from the external environment with a low processing cost, and this nonclassical receptive field mechanism could substantially improve both segmentation and integration processing. This model enables automatic extraction of blocks from images, which makes multiscale representation feasible. Importantly, once an original pixel-level image was reorganized into a GC array, semantic-level features emerged. Because GCs, like symbols, are discrete and separable, this GC-grained compact representation is open to operations that can manipulate images partially and selectively. Thus, the GC-array model provides a basic infrastructure and allows for high-level image processing.
Keywords
feature extraction; image representation; image segmentation; neural nets; GC-array model; bio-inspired hierarchical neural network; block automatic extraction; compact image representation model; computational model; ganglion cell mechanism; integration processing; micro neural circuit; nCRF; nonclassical receptive field mechanism; pixel-level image; reverse control circuit; reverse control mechanisms; segmentation processing; Image color analysis; Image representation; Integrated circuit modeling; Radio frequency; Retina; Semantics; Visualization; Bidirectional processing; image representation; neural computing; nonclassical receptive field;
fLanguage
English
Journal_Title
Neural Networks and Learning Systems, IEEE Transactions on
Publisher
ieee
ISSN
2162-237X
Type
jour
DOI
10.1109/TNNLS.2011.2178472
Filename
6104230
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