Abstract
Low power wide area networks (LPWANs) have been recently deployed for long-range machine-to-machine (M2M) communications. These networks have been proposed for many applications and in particular for the communications of the advanced metering infrastructure (AMI) backhaul of the smart grid. However, they rely on simple access schemes that may suffer from important latency, which is one of the main performance indicators in smart grid communications. In this article, we apply reinforcement learning (RL) algorithms to reduce the latency of AMI communications in LPWANs. For that purpose, we first study the collision probability in an unslotted ALOHA-based LPWAN AMI backhaul which uses the LoRaWAN acknowledgement procedure. Then, we analyse the effect of collisions on the latency for different frequency access schemes. We finally show that RL algorithms can be used for the purpose of frequency selection in these networks and reduce the latency of the AMI backhaul in LPWANs. Numerical results show that non-coordinated algorithms featuring a very low complexity reduce the collision probability by 14% and the mean latency by 40%.
Highlights
The increasing development of renewable energy production and the high cost associated with power failures have been driving electricity operators towards the development of new functions enabling the real-time management of the electrical grid
We consider a LoRaWAN advanced metering infrastructure (AMI) backhaul but we focus our analysis on latency
We show that reinforcement learning algorithms and more precisely multi-armed bandit (MAB) learning reduce the latency of the AMI backhaul in Low power wide area network (LPWAN)
Summary
The increasing development of renewable energy production and the high cost associated with power failures have been driving electricity operators towards the development of new functions enabling the real-time management of the electrical grid. Please note that in the LoRaWAN standard case, if the base station cannot send the acknowledgement after the first receive delay, an acknowledgement can be sent after a second receive delay into another channel reserved for downlink communications This second receive window is not considered in this article. Consequence, an uplink packet can collide with a downlink packet (acknowledgement) only if the acknowledgement is sent before the packet
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