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Constrained Deep Reinforcement Learning for Energy Sustainable Multi-UAV Based Random Access IoT Networks With NOMA

Sami Khairy, Prasanna Balaprakash, Lin X. Cai, Yu Cheng

2020IEEE Journal on Selected Areas in Communications93 citationsDOIOpen Access PDF

Abstract

In this paper, we apply the Non-Orthogonal Multiple Access (NOMA) technique to improve the massive channel access of a wireless IoT network where solar-powered Unmanned Aerial Vehicles (UAVs) relay data from IoT devices to remote servers. Specifically, IoT devices contend for accessing the shared wireless channel using an adaptive p-persistent slotted Aloha protocol; and the solar-powered UAVs adopt Successive Interference Cancellation (SIC) to decode multiple received data from IoT devices to improve access efficiency. To enable an energy-sustainable capacity-optimal network, we study the joint problem of dynamic multi-UAV altitude control and multi-cell wireless channel access management of IoT devices as a stochastic control problem with multiple energy constraints. We first formulate this problem as a Constrained Markov Decision Process (CMDP), and propose an online model-free Constrained Deep Reinforcement Learning (CDRL) algorithm based on Lagrangian primal-dual policy optimization to solve the CMDP. Extensive simulations demonstrate that our proposed algorithm learns a cooperative policy in which the altitude of UAVs and channel access probability of IoT devices are dynamically controlled to attain the maximal long-term network capacity while ensuring energy sustainability of UAVs, outperforming baseline schemes. The proposed CDRL agent can be trained on a small network, yet the learned policy can efficiently manage networks with a massive number of IoT devices and varying initial states, which can amortize the cost of training the CDRL agent.

Topics & Concepts

Computer scienceReinforcement learningAlohaMarkov decision processComputer networkRelayWirelessRandom accessWireless networkChannel (broadcasting)Distributed computingAccess controlEfficient energy useNomaMarkov processWireless sensor networkPower controlThroughputInterference (communication)Energy (signal processing)Access networkStochastic geometryTelecommunications linkStochastic controlMarkov chainReal-time computingMIMOPartially observable Markov decision processUAV Applications and OptimizationIoT Networks and ProtocolsAdvanced Wireless Communication Technologies
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