Error-resilient coding of 3-D graphic models via adaptive mesh segmentation

Current coding techniques for 3-D graphic models mainly focus on coding efficiency, which makes them extremely sensitive to channel errors due to the irregular mesh structure. We introduce a new approach for error-resilient coding of arbitrary 3-D graphic models by extending the error-free construct...

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Vydané v:IEEE transactions on circuits and systems for video technology Ročník 11; číslo 7; s. 860 - 873
Hlavní autori: Zhidong Yan, Kumar, S., Kuo, C.-C.J.
Médium: Journal Article
Jazyk:English
Vydavateľské údaje: New York, NY IEEE 01.07.2001
Institute of Electrical and Electronics Engineers
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Predmet:
Application software
Applied sciences
Boundaries
Channels
Coding
Compressing
Computer graphics
Decoding
Error analysis
Error correction codes
Errors
Exact sciences and technology
Finite element method
Image processing
Information geometry
Information, signal and communications theory
Permissible error
Protection
Quantization
Signal processing
Telecommunications and information theory
Topology
Tree graphs
Segmentation
Image processing
Coding
Data compression
Quantization
Error detection
Tridimensional image
Error correction
Topology
Mesh method
Adaptive method
ISSN:1051-8215, 1558-2205
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Popis
Shrnutí:Current coding techniques for 3-D graphic models mainly focus on coding efficiency, which makes them extremely sensitive to channel errors due to the irregular mesh structure. We introduce a new approach for error-resilient coding of arbitrary 3-D graphic models by extending the error-free constructive traversal compression scheme proposed by Li and Kuo (see MPEG-4 Tokyo Meeting, 1998, Contribution Doc. M3324, and Proc. IEEE, vol.86, p.1052-63, 1998). A 3-D mesh of an arbitrary structure is partitioned into pieces of a smaller uniform size with joint boundaries. The size of a piece is determined adaptively based on the channel error rate. The topology and geometry information of each joint boundary and each piece of a connected component is coded independently. The coded topology and first several important bit-planes of the joint-boundary data are protected against channel errors by using the Bose-Chaudhuri-Hocquenghem error-correcting code. At the decoder, each piece is decoded and checked for channel errors. The decoded joint-boundary information is used to perform data recovery and error concealment on the corrupted piece data. All decoded pieces are combined together according to their configuration to reconstruct all connected components of the complete 3-D model. Our experiments demonstrate that the proposed approach has excellent error resiliency at a reasonable bit-rate overhead. The techniques is also capable of incrementally rendering one connected component of the 3-D model at a time.
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ISSN:1051-8215
1558-2205
DOI:10.1109/76.931112