Abstract
5G New Radio (NR) is expected to support new ultra-reliable low-latency communication (URLLC) service targeting at supporting the small packets transmissions with very stringent latency and reliability requirements. Current Long Term Evolution (LTE) system has been designed based on grant-based (GB) (i.e., dynamic grant) random access, which can hardly support the URLLC requirements. Grant-free (GF) (i.e., configured grant) access is proposed as a feasible and promising technology to meet such requirements, especially for uplink transmissions, which effectively saves the time of requesting/waiting for a grant. While some basic GF access features have been proposed and standardized in NR Release-15, there is still much space to improve. Being proposed as 3GPP study items, three GF access schemes with Hybrid Automatic Repeat reQuest (HARQ) retransmissions including Reactive, K-repetition, and Proactive, are analyzed in this article. Specifically, we present a spatio-temporal analytical framework for the contention-based GF access analysis. Based on this framework, we define the latent access failure probability to characterize URLLC reliability and latency performances. We propose a tractable approach to derive and analyze the latent access failure probability of the typical UE under three GF HARQ schemes. Our results show that under shorter latency constraints, the Proactive scheme provides the lowest latent access failure probability, whereas, under longer latency constraints, the K-repetition scheme achieves the lowest latent access failure probability, which depends on K. If K is overestimated, the Proactive scheme provides lower latent access failure probability than the K-repetition scheme.
Highlights
T HE Fifth Generation (5G) New Radio (NR) considers three new communication service categories: enhanced Mobile Broadband, massive Machine-Type Communications, and Ultra-Reliable Low-Latency Communications (URLLC) [1], [2]
Probability theory is applied to model the correlation of the buffer state and the transmission state over different time slots. Based on this framework, we propose a tractable approach to characterize and analyze the URLLC performances of a randomly chosen User Equipment (UE) by defining the latent access failure probability
Note that we only consider a single packet sequence arrival. This packet sequence will be removed from the buffer, i.e., the buffer becomes empty without new packets, once it has been successfully transmitted, otherwise, this UE will wait and reattempt in the Hybrid Automatic Repeat reQuest (HARQ) retransmission
Summary
T HE Fifth Generation (5G) New Radio (NR) considers three new communication service categories: enhanced Mobile Broadband (eMBB), massive Machine-Type Communications (mMTC), and Ultra-Reliable Low-Latency Communications (URLLC) [1], [2]. The Reactive scheme only allows for a limited number of retransmissions due to the stringent latency requirement of URLLC service [13], and this fact motivates more research for advanced HARQ schemes to be integrated with GF transmission to provide reduced latency and enhanced reliability. The authors in [19] claimed that the effects of inter- and intra-cell interference, queuing and time-frequency variant channels, are difficult or even infeasible to evaluate with analytical models This is because existing wireless systems were designed mainly to maximize the data rates of the long packet transmission, the short packet transmission in URLLC service challenges the existing wireless system in terms of the joint reliability and latency requirements.
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