Title :
An Upper Bound to the Rate of Ideal Distributed Lossy Source Coding of Densely Sampled Data
Author :
Neuhoff, David L. ; Pradhan, S. Sandeep
Author_Institution :
Dept. of Electr. Eng. & Comput. Sci., Michigan Univ., Ann Arbor, MI
Abstract :
Motivated by the question of the efficiency of dense sensor networks for sampling, encoding and reconstructing spatial random fields, this paper uses the Berger-Tung upper bound to the discrete-time distributed rate-distortion function and Grenander-Szego asymptotic eigenvalue theory to obtain an upper bound to the smallest possible rate when using distributed lossy encoding of densely spaced samples that is tighter than the bound recently obtained by Kashyap et al. Both bounds indicate that with ideal distributed lossy coding, dense sensor networks can efficiently sense and convey a field, in contrast to the negative result obtained by Marco et al. for encoders based on time- and space-invariant scalar quantization and ideal Slepian-Wolf distributed lossless coding
Keywords :
distributed sensors; eigenvalues and eigenfunctions; quantisation (signal); signal reconstruction; signal sampling; source coding; Berger-Tung upper bound; Grenander-Szego asymptotic eigenvalue theory; Slepian-Wolf distributed lossless coding; dense sensor networks; densely sampled data; densely spaced samples; discrete-time distributed rate-distortion function; distributed lossy encoding; ideal distributed lossy source coding; space-invariant scalar quantization; spatial random field sampling; time-invariant scalar quantization; Decoding; Eigenvalues and eigenfunctions; Encoding; Propagation losses; Quantization; Random processes; Rate-distortion; Sampling methods; Source coding; Upper bound;
Conference_Titel :
Acoustics, Speech and Signal Processing, 2006. ICASSP 2006 Proceedings. 2006 IEEE International Conference on
Conference_Location :
Toulouse
Print_ISBN :
1-4244-0469-X
DOI :
10.1109/ICASSP.2006.1661481
