Delay analysis of random scheduling and round robin in small cell networks

Howard H. Yang; Ying Wang; Tony Q.S. Quek

doi:10.1109/LWC.2018.2843372

Delay analysis of random scheduling and round robin in small cell networks

Howard H. Yang
, Ying Wang
, Tony Q.S. Quek

Department of Computer Science and Information Engineering

Research output: Contribution to journal › Article › peer-review

41 Citations (Scopus)

Abstract

We analyze the delay performance of small cell networks operating under random scheduling (RS) and round Robin (RR) protocols. Based on stochastic geometry and queuing theory, we derive accurate and tractable expressions for the distribution of mean delay, which accounts for the impact of random traffic arrivals, queuing interactions, and failed packet retransmissions. Our analysis asserts that RR outperforms RS in terms of mean delay, regardless of traffic statistic. Moreover, the gain from RR is more pronounced in the presence of heavy traffic, which confirms the importance of accounting fairness in the design of scheduling policy. We also find that constrained on the same delay outage probability, RR is able to support more user equipments than that of RS, demonstrating it as an appropriate candidate for the traffic scheduling policy of Internet-of-Things network.

Original language	English
Article number	8371220
Pages (from-to)	978-981
Number of pages	4
Journal	IEEE Wireless Communications Letters
Volume	7
Issue number	6
DOIs	https://doi.org/10.1109/LWC.2018.2843372
Publication status	Published - 2018 Dec

All Science Journal Classification (ASJC) codes

Control and Systems Engineering
Electrical and Electronic Engineering

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10.1109/LWC.2018.2843372

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abstract = "We analyze the delay performance of small cell networks operating under random scheduling (RS) and round Robin (RR) protocols. Based on stochastic geometry and queuing theory, we derive accurate and tractable expressions for the distribution of mean delay, which accounts for the impact of random traffic arrivals, queuing interactions, and failed packet retransmissions. Our analysis asserts that RR outperforms RS in terms of mean delay, regardless of traffic statistic. Moreover, the gain from RR is more pronounced in the presence of heavy traffic, which confirms the importance of accounting fairness in the design of scheduling policy. We also find that constrained on the same delay outage probability, RR is able to support more user equipments than that of RS, demonstrating it as an appropriate candidate for the traffic scheduling policy of Internet-of-Things network.",

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AB - We analyze the delay performance of small cell networks operating under random scheduling (RS) and round Robin (RR) protocols. Based on stochastic geometry and queuing theory, we derive accurate and tractable expressions for the distribution of mean delay, which accounts for the impact of random traffic arrivals, queuing interactions, and failed packet retransmissions. Our analysis asserts that RR outperforms RS in terms of mean delay, regardless of traffic statistic. Moreover, the gain from RR is more pronounced in the presence of heavy traffic, which confirms the importance of accounting fairness in the design of scheduling policy. We also find that constrained on the same delay outage probability, RR is able to support more user equipments than that of RS, demonstrating it as an appropriate candidate for the traffic scheduling policy of Internet-of-Things network.

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Delay analysis of random scheduling and round robin in small cell networks

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