Low-Complexity Scheduling Algorithms for Multichannel Downlink Wireless Networks

This paper considers the problem of designing scheduling algorithms for multichannel (e.g., OFDM-based) wireless downlink networks, with a large number of users and proportionally large bandwidth. For this system, while the classical MaxWeight algorithm is known to be throughput-optimal, its buffer-...

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Vydané v:IEEE/ACM transactions on networking Ročník 20; číslo 5; s. 1608 - 1621
Hlavní autori: Bodas, S., Shakkottai, S., Lei Ying, Srikant, R.
Médium: Journal Article
Jazyk:English
Vydavateľské údaje: New York IEEE 01.10.2012
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Predmet:
Algorithm design and analysis
Algorithms
Arrivals
Buffers
Channels
Complexity
Complexity theory
Downlink
Large deviations
low complexity
Mathematical analysis
Mathematical models
Resource management
Scheduling
Scheduling algorithms
Servers
small buffer
Studies
Throughput
Wireless networks
ISSN:1063-6692, 1558-2566
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Shrnutí:This paper considers the problem of designing scheduling algorithms for multichannel (e.g., OFDM-based) wireless downlink networks, with a large number of users and proportionally large bandwidth. For this system, while the classical MaxWeight algorithm is known to be throughput-optimal, its buffer-overflow performance is very poor (formally, it is shown that it has zero rate function in our setting). To address this, a class of algorithms called iterated Heaviest matching with Longest Queues First (iHLQF) is proposed. The algorithms in this class are shown to be throughput-optimal for a general class of arrival/channel processes, and also rate-function-optimal (i.e., exponentially small buffer overflow probability) for certain arrival/channel processes. iHLQF, however, has higher complexity than MaxWeight ( n 4 versus n 2 , respectively). To overcome this issue, a new algorithm called Server-Side Greedy (SSG) is proposed. It is shown that SSG is throughput-optimal, results in a much better per-user buffer overflow performance than the MaxWeight algorithm (positive rate function for certain arrival/channel processes), and has a computational complexity ( n 2 ) that is comparable to the MaxWeight algorithm. Thus, it provides a nice tradeoff between buffer-overflow performance and computational complexity. These results are validated by both analysis and simulations.
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ISSN:1063-6692
1558-2566
DOI:10.1109/TNET.2012.2185709