DocumentCode
1213100
Title
Single-channel user-capacity calculations for self-organizing cellular systems
Author
Cimini, Leonard J., Jr. ; Foschini, Gerard J. ; Shepp, Lany A.
Author_Institution
AT&T Bell Labs., Holmdel, NJ, USA
Volume
42
Issue
12
fYear
1994
fDate
12/1/1994 12:00:00 AM
Firstpage
3137
Lastpage
3143
Abstract
One important quantity in assessing the viability of local, autonomous, dynamic channel allocation for microcellular systems is user capacity, defined as the average number of users per channel per cell. Here, we determine the capacity for infinite linear and planar arrays of microcells using a very idealized environment. In particular, propagation and interference considerations are simply represented by the constraint that, if a channel is used in a given cell, it cannot be used in R-consecutive rings of cells around that cell. We investigate the elementary case where there is only a single channel available for use in the system. Using this representation, we compute the best and worst user capacities as well as the capacity achieved by random channel placement. While the environment under which these capacities are derived is highly idealized, the results are useful in two important ways. First, the best capacity and the random channel placement capacity we find here for single-channel, self-organized access are fundamental for computing the traffic characteristics of important multichannel dynamic channel allocation algorithms. Second, the random channel placement capacity is close enough to the best that can be achieved to suggest that local, autonomously implemented, dynamic channel allocation loses little capacity when compared with centrally administered fixed channel allocation
Keywords
cellular radio; channel capacity; frequency allocation; land mobile radio; radio spectrum management; telecommunication traffic; centrally administered fixed channel allocation; dynamic channel allocation; interference considerations; linear arrays; local autonomous dynamic channel allocation; microcells; microcellular systems; multichannel dynamic channel allocation algorithms; planar arrays; propagation; random channel placement; self-organizing cellular systems; single-channel user-capacity; traffic characteristics; viability; Channel allocation; Channel capacity; Communications Society; Distributed control; Heuristic algorithms; Interference constraints; Microcell networks; Planar arrays; Stress; Switches;
fLanguage
English
Journal_Title
Communications, IEEE Transactions on
Publisher
ieee
ISSN
0090-6778
Type
jour
DOI
10.1109/26.339834
Filename
339834
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