Abstract
The addition of redundancy is a promising solution to achieve a certain quality of service (QoS) for ultra-reliable low-latency communications (URLLC) in challenging fast fading scenarios. However, adding more and more redundancy to the transmission results in severely increased radio resource consumption. Monitoring and prediction of fast fading channels can serve as the foundation of advanced scheduling. By choosing suitable resources for transmission, the resource consumption is reduced while maintaining the QoS. In this article, we present outage prediction approaches for Rayleigh and Rician fading channels. Appropriate performance metrics are introduced to show the suitability for URLLC radio resource scheduling. Outage prediction in the Rayleigh fading case can be achieved by adding a threshold comparison to state-of-the-art fading prediction approaches. A line-of-sight (LOS) component estimator is introduced that enables outage prediction in LOS scenarios. Extensive simulations have shown that under realistic conditions, effective outage probabilities of 10^{-5} can be achieved while reaching up-state prediction probabilities of more than {90}{%}. We show that the predictor can be tuned to satisfy the desired trade-off between prediction reliability and utilizability of the link. This enables our predictor to be used in future scheduling strategies, which achieve the challenging QoS of URLLC with fewer required redundancy.
Highlights
1 Introduction One of the main pillars of the fifth generation (5G) mobile broadband standards is ultrareliable low-latency communications (URLLC), which aims to provide extremely high service availabilities paired with latency values of only a few milliseconds
All plots are generalized by using times that are normalized to the maximum Doppler frequency fm
To investigate the influence of the LOS estimation, which is the novel component compared to the Rayleigh fading case, we show the case of ideal LOS parameter estimation as dashed lines, where ideal estimates are used for subtraction and prediction of the LOS component and only the NLOS fading is realistically predicted using the Wiener filter
Summary
One of the main pillars of the fifth generation (5G) mobile broadband standards is ultrareliable low-latency communications (URLLC), which aims to provide extremely high service availabilities paired with latency values of only a few milliseconds. To realize even more ambitious quality of service (QoS) requirements compared to 5G, URLLC inevitably has to play a key role during research of the sixth generation (6G) mobile broadband standards [1, 2]. One major challenge is wireless closed-loop control as losing packets and the latency of the transmission might lead to plant instability, which in turn could cause damage or even human harm. Latency-critical mobile connectivity is required when humans are involved in the control loop [4, 5]. In industry, this is the case, e.g., in teleoperating applications or during installation of machines, where a human could train the machine instead of programming it. URLLC might find its way to consumer products for entertainment, for health or even for human learning
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