Distributed Long-Lived List Colouring: How to Dynamically Allocate Frequencies in Cellular Networks
Journal article, 2002

To avoid signal interference in mobile communication it is necessary that the frequencies used for communication within each cell are allocated so that no signal interference occurs with neighbouring cells. We model this channel allocation problem as a generalised list colouring problem and we show how to analytically measure and provide worst-case guarantees regarding request satisfiability. To the best of our knowledge, this has not been done before and gives a now perspective to the problem, as well as a clear direction for further investigation. We propose distributed approaches for solving the problem, which are able to adapt fast to temporal variations in channel demands in different cells, as well as to cope with crash failures, by limiting the failure-locality - the size of the network that can be affected by a faulty station, in terms of the distance from that station. Our first approach is inspired by a relatively recent theorem relating graph colourings and orientations; it achieves the equivalent of the best known sequentially achievable upper bound for request satisfiability, implied by the theorem. It also employs a powerful synchronisation mechanism to achieve worst-case response time that depends only on A - the degree of the signal interference graph - and failure locality 4. Our second proposal is a first approach towards exploring what bound in request satisfiability is achievable without the use of extra synchronisation; by employing randomisation in frequency choices, in only one round of communication, a base station can expect to pick f/(4Delta) frequencies, where f is the size of the list at the node; the failure locality of this solution is only 1.

dynamic frequency allocation

failure locality

request satisfiability

cellular networks

distributed frequency allocation

Author

N. Garg

Indian Institute of Technology Delhi

Marina Papatriantafilou

Chalmers, Department of Computing Science

Philippas Tsigas

Chalmers, Department of Computing Science

Wireless Networks

1022-0038 (ISSN) 1572-8196 (eISSN)

Vol. 8 1 49-60

Subject Categories

Computer Science

DOI

10.1023/A:1012719525108

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Latest update

8/21/2023