DocumentCode
1334468
Title
Contractive Interference Functions and Rates of Convergence of Distributed Power Control Laws
Author
Feyzmahdavian, Hamid Reza ; Johansson, Mikael ; Charalambous, Themistoklis
Author_Institution
ACCESS Linnaeus Center, KTH-R. Inst. of Technol., Stockholm, Sweden
Volume
11
Issue
12
fYear
2012
fDate
12/1/2012 12:00:00 AM
Firstpage
4494
Lastpage
4502
Abstract
The standard interference functions introduced by Yates have been very influential on the analysis and design of distributed power control laws. While powerful and versatile, the framework has some drawbacks: the existence of fixed-points has to be established separately, and no guarantees are given on the rate of convergence of the iterates. This paper introduces contractive interference functions, a slight reformulation of the standard interference functions that guarantees the existence and uniqueness of fixed-points along with linear convergence of iterates. We show that many power control laws from the literature are contractive and derive, sometimes for the first time, analytical convergence rate estimates for these algorithms. We also prove that contractive interference functions converge when executed totally asynchronously and, under the assumption that the communication delay is bounded, derive an explicit bound on the convergence time penalty due to increased delay. Finally, we demonstrate that although standard interference functions are, in general, not contractive, they are all para-contractions with respect to a certain metric. Similar results for two-sided scalable interference functions are also derived.
Keywords
convergence; estimation theory; interference suppression; power control; radio networks; telecommunication control; analytical convergence rate estimates; communication delay; contractive interference functions; convergence rates; convergence time penalty; distributed power control laws; explicit bound; fixed-points; linear convergence; scalable interference functions; standard interference functions; Base stations; Convergence; Interference; Power control; Scalability; Standards; Vectors; Interference function; contraction mapping; power control; wireless networks;
fLanguage
English
Journal_Title
Wireless Communications, IEEE Transactions on
Publisher
ieee
ISSN
1536-1276
Type
jour
DOI
10.1109/TWC.2012.102512.120101
Filename
6353394
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