State diagram connectivity and its effects on the decoding of shift-register-based codes

Author

Collins, Oliver M.

Author_Institution

Dept. of Electr. & Comput. Eng., Johns Hopkins Univ., Baltimore, MD, USA

Volume

41

Issue

3

fYear

1995

fDate

5/1/1995 12:00:00 AM

Firstpage

756

Lastpage

761

Abstract

Coding performance is limited not only by Shannon´s (1950) bounds but also by the complexity of decoders. Decoder complexity is in turn governed by the need for the different pieces of the machine to communicate with one another. This paper calculates lower limits on the intra-system information flow for the Viterbi decoding of shift-register-based codes, e.g., convolutional codes. These limits provide practical guidance for the construction of decoders for the current generation of convolutional and trellis codes. In particular, these bounds prove that a very specialized decoder family, called graph partition decoders, have an asymptotically optimum communications growth rate. The techniques used in this paper can, moreover, be applied to the design of new (non-shift-register-based) codes which may possibly circumvent the limits derived in the paper and to the design of parallel processors

Keywords

Viterbi decoding; binary sequences; computational complexity; convolutional codes; graph theory; trellis codes; Shannon´s bounds; Viterbi decoding; coding performance; convolutional codes; decoder complexity; decoding; graph partition decoders; intra-system information flow; lower limits; non-shift-register-based codes; optimum communications growth rate; parallel processors; shift-register-based codes; state diagram connectivity; trellis codes; Buildings; Convolutional codes; Costs; Decoding; Graph theory; Process design; Shift registers; Telephony; Viterbi algorithm; Wiring;

fLanguage

English

Journal_Title

Information Theory, IEEE Transactions on

Publisher

ieee

ISSN

0018-9448

Type

jour

DOI

10.1109/18.382021

Filename

382021