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Deep Reinforcement Learning for Wireless Sensor Scheduling in Cyber-Physical Systems

Authors :
Leong, Alex S.
Ramaswamy, Arunselvan
Quevedo, Daniel E.
Karl, Holger
Shi, Ling
Source :
Automatica, vol. 113, 2020
Publication Year :
2018

Abstract

In many Cyber-Physical Systems, we encounter the problem of remote state estimation of geographically distributed and remote physical processes. This paper studies the scheduling of sensor transmissions to estimate the states of multiple remote, dynamic processes. Information from the different sensors have to be transmitted to a central gateway over a wireless network for monitoring purposes, where typically fewer wireless channels are available than there are processes to be monitored. For effective estimation at the gateway, the sensors need to be scheduled appropriately, i.e., at each time instant one needs to decide which sensors have network access and which ones do not. To address this scheduling problem, we formulate an associated Markov decision process (MDP). This MDP is then solved using a Deep Q-Network, a recent deep reinforcement learning algorithm that is at once scalable and model-free. We compare our scheduling algorithm to popular scheduling algorithms such as round-robin and reduced-waiting-time, among others. Our algorithm is shown to significantly outperform these algorithms for many example scenarios.

Details

Database :
arXiv
Journal :
Automatica, vol. 113, 2020
Publication Type :
Report
Accession number :
edsarx.1809.05149
Document Type :
Working Paper