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Linear Network Coding for Dynamic Rate Adaptation with Global Resource Tradeoff in Distributed 5G LAA Network

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Abstract

5G cellular network will drive towards higher energy efficiency, lower latency and higher reliable wireless networks. The key contributions can summarize as follows: (1) this paper proposes a feasible method to compute the expected rate and approach the optimal capacity region by upper and lower bounds in 5G cellular network, (2) develops linear network coding and dynamic rate adaptation to improve the throughput and reliability of LAA network, (3) proposes a new E-PDP-MNLC (Efficient Protocol Priority-based Distributed Paired Multicast Network Linear Coding) scheme for LAA network coding. • Networks → Network layer protocols → Routing protocols • Networks → Network algorithms → Data path algorithms → Packet scheduling → Control path algorithms → Network control algorithms.

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  1. Department of Computer Science and Information Engineering, National Taiwan University, Taipei, Taiwan

    Dan Ye

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  1. Dan Ye
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Correspondence to Dan Ye.

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Ye, D. Linear Network Coding for Dynamic Rate Adaptation with Global Resource Tradeoff in Distributed 5G LAA Network. Wireless Pers Commun 117, 2027–2039 (2021). https://doi.org/10.1007/s11277-020-07956-1

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