Coding and stability in frequency-hop packet radio networks

Author

Murali, Ramaswamy ; Hughes, Brian L.

Author_Institution

High Media Production, Rockwell Semicond. Syst., San Diego, CA, USA

Volume

46

Issue

2

fYear

1998

fDate

2/1/1998 12:00:00 AM

Firstpage

191

Lastpage

199

Abstract

A fully connected radio network is considered in which packets are sent using slow frequency-hop (FH) modulation, slotted ALOHA random access, and Reed-Solomon (RS) error-control coding. For this network, the dependence of throughput, delay, and drift on the code rate and block length is examined. It is shown that the drift approaches a simple limiting form as the block length becomes large. This form suggests that, in a bistable FH network, the undesirable stable point can usually be eliminated without increasing the delay or reducing the throughput at the desirable stable point. In particular, bistability can be eliminated by increasing the code block length and retransmission delay, and does not require the use of decentralized control or channel traffic estimates

Keywords

Reed-Solomon codes; access protocols; delays; frequency hop communication; packet radio networks; random processes; spread spectrum communication; stability; Reed-Solomon error-control coding; bistable FH network; block length; code block length; code rate; desirable stable point; drift; frequency hop spread spectrum; frequency-hop packet radio networks; fully connected radio network; retransmission delay; slotted ALOHA random access; slow frequency-hop modulation; throughput; undesirable stable point; Communication system traffic control; Delay estimation; Distributed control; Frequency modulation; Modulation coding; Packet radio networks; Radio network; Reed-Solomon codes; Stability; Throughput;

fLanguage

English

Journal_Title

Communications, IEEE Transactions on

Publisher

ieee

ISSN

0090-6778

Type

jour

DOI

10.1109/26.659478

Filename

659478