Abstract
In scenarios, like critical public safety communication networks, On-Scene Available (OSA) user equipment (UE) may be only partially connected with the network infrastructure, e.g., due to physical damages or on-purpose deactivation by the authorities. In this work, we consider multi-hop Device-to-Device (D2D) communication in a hybrid infrastructure where OSA UEs connect to each other in a seamless manner in order to disseminate critical information to a deployed command center. The challenge that we address is to simultaneously keep the OSA UEs alive as long as possible and send the critical information to a final destination (e.g., a command center) as rapidly as possible, while considering the heterogeneous characteristics of the OSA UEs. We propose a dynamic adaptation approach based on machine learning to improve a joint energy-spectral efficiency (ESE). We apply a Q-learning scheme in a hybrid fashion (partially distributed and centralized) in learner agents (distributed OSA UEs) and scheduler agents (remote radio heads or RRHs), for which the next hop selection and RRH selection algorithms are proposed. Our simulation results show that the proposed dynamic adaptation approach outperforms the baseline system by approximately in terms of joint energy-spectral efficiency, wherein the energy efficiency of the OSA UEs benefit from a gain of approximately . Finally, the results show also that our proposed framework with C-RAN reduces latency by approximately w.r.t. the baseline.
Highlights
In the context of the cellular networks, from Advanced Long Term Evolution (LTE-A) to fifth-generation of mobile communication (5G), the increasing number of devices keeps pushing the demand for higher spectral and energy efficiencies
D2D communication allows user devices (UEs) that are in close proximity to exchange information over a direct link, which can be operated as an underlay to LTE-A networks by reusing the spectrum resources
Simulation results show that our optimized network outperforms the baseline one by almost 67% in terms of joint energy-spectral efficiency, and our algorithm helps to achieve approximately 30% energy efficiency for connected UEs compared to the baseline technique
Summary
In the context of the cellular networks, from Advanced Long Term Evolution (LTE-A) to fifth-generation of mobile communication (5G), the increasing number of devices keeps pushing the demand for higher spectral and energy efficiencies. In this direction, 5G provides a roadmap for increased resource efficiency and energy efficiency, greater reliability, and low latency solutions [1]. Sensors 2020, 20, 6692 out-of-coverage UEs. Sensors 2020, 20, 6692 out-of-coverage UEs This opportunity can be provided by D2D-based relays. Relay UEs help to communicate with the BS and other out-of-coverage UEs, as standardized in 3GPP Release 13 [3]
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