On separation of source and channel coding in the finite block length regime

Author

Ho, Jason ; Jin Meng ; En-Hui Yang

Author_Institution

Dept. of Electr. & Comput. Eng., Univ. of Waterloo, Waterloo, ON, Canada

fYear

2013

fDate

18-21 June 2013

Firstpage

92

Lastpage

95

Abstract

This paper investigates the validity of Shannon´s separation theorem in the finite block length regime. Under optimal tradeoffs between source rate and channel block error probability obtained from finite block length analysis, noisy channel quantizers based on joint source-channel coding principles are shown to outperform the separate quantizer designed via Lloyd-Max in terms of end-to-end distortion. Numerical results for the scalar case under the binary symmetric channel and discrete-input memoryless channel demonstrate that the separation of source and channel coding no longer holds in the finite block length regime, but the advantages of joint designs may be large or small depending on the system configuration.

Keywords

binary codes; block codes; combined source-channel coding; error statistics; source separation; Shannon separation theorem; binary symmetric channel; channel block error probability; discrete-input memoryless channel; end-to-end distortion; finite block length regime; joint source-channel coding principle; noisy channel quantizer; source separation; Channel coding; Error probability; Gain; Joints; Noise measurement; PSNR; end-to-end distortion; finite block length regime; joint source-channel coding; lossy source coding;

fLanguage

English

Publisher

ieee

Conference_Titel

Information Theory (CWIT), 2013 13th Canadian Workshop on

Conference_Location

Toronto, ON

Type

conf

DOI

10.1109/CWIT.2013.6621599

Filename

6621599