Wireless Channel Modeling Perspectives for Ultra-Reliable Communications

Ultra-reliable communication (URC) is one of the distinctive features of the upcoming 5G wireless communication, characterized by packet error rates going down to 10 −9 . In this paper, we analyze the tail of the cumulative distribution function of block fading channels in the regime of extremely ra...

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Veröffentlicht in:	IEEE transactions on wireless communications 2019-04, Vol.18 (4), p.2229-2243
Hauptverfasser:	Eggers, Patrick C. F., Angjelichinoski, Marko, Popovski, Petar
Format:	Artikel
Sprache:	eng
Schlagworte:	Channel estimation Channel models Channels Distribution functions diversity Empirical analysis fading Fading channels Optimization Power law probability tail approximations Radio transmitters rare event statistics Receivers Reliability Ultra-reliable communications ultra-reliable low latency communication (URLLC) wireless channel models Wireless communication Wireless communications
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creator	Eggers, Patrick C. F. Angjelichinoski, Marko Popovski, Petar
description	Ultra-reliable communication (URC) is one of the distinctive features of the upcoming 5G wireless communication, characterized by packet error rates going down to 10 −9 . In this paper, we analyze the tail of the cumulative distribution function of block fading channels in the regime of extremely rare events, i.e., the ultra-reliable (UR) regime of operation. Our main contribution consists of providing a unified framework for statistical description of wide range of practically important wireless channel models in the UR regime of operation. Specifically, we show that the wireless channel behavior in this regime can be approximated by a simple power law expression, whose exponent and offset depend on the actual channel model. The unification provides a channel-agnostic tool for analyzing and performance optimization of radio systems that operate in the UR regime. Furthermore, the unified model is particularly useful in the emerging measurement campaigns for empirical characterization of wireless channels in the regime of low outages. Finally, the asymptotic analysis can serve as an underlying building block for designing more elaborate, higher-layer technologies for URC. We showcase this by applying the power law results to analyze the performance of receiver diversity schemes and obtain a new simplified expression for maximum ratio combining.
doi_str_mv	10.1109/TWC.2019.2901788
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subjects	Channel estimation Channel models Channels Distribution functions diversity Empirical analysis fading Fading channels Optimization Power law probability tail approximations Radio transmitters rare event statistics Receivers Reliability Ultra-reliable communications ultra-reliable low latency communication (URLLC) wireless channel models Wireless communication Wireless communications
title	Wireless Channel Modeling Perspectives for Ultra-Reliable Communications
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