Multiagent Federated Reinforcement Learning for Resource Allocation in UAV-Enabled Internet of Medical Things Networks

In the 5G/B5G network paradigms, intelligent medical devices known as the Internet of Medical Things (IoMT) have been used in the healthcare industry to monitor remote users’ health status, such as elderly monitoring, injuries, stress, and patients with chronic diseases. Since IoMT devices have limi...

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Veröffentlicht in:	IEEE internet of things journal 2023-11, Vol.10 (22), p.19695-19711
Hauptverfasser:	Seid, Abegaz Mohammed, Erbad, Aiman, Abishu, Hayla Nahom, Albaseer, Abdullatif, Abdallah, Mohamed, Guizani, Mohsen
Format:	Artikel
Sprache:	eng
Schlagworte:	5G mobile communication Algorithms Computation offloading Edge computing Energy consumption Health care Health care industry Internet of medical things Machine learning Markov processes Medical devices Medical electronics Medical equipment Mobile computing Multiagent systems Network latency Remote monitoring Resource allocation Servers Unmanned aerial vehicles
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creator	Seid, Abegaz Mohammed Erbad, Aiman Abishu, Hayla Nahom Albaseer, Abdullatif Abdallah, Mohamed Guizani, Mohsen
description	In the 5G/B5G network paradigms, intelligent medical devices known as the Internet of Medical Things (IoMT) have been used in the healthcare industry to monitor remote users’ health status, such as elderly monitoring, injuries, stress, and patients with chronic diseases. Since IoMT devices have limited resources, mobile edge computing (MEC) has been deployed in 5G networks to enable them to offload their tasks to the nearest computational servers for processing. However, when IoMTs are far from network coverage or the computational servers at the terrestrial MEC are overloaded/emergencies occur, these devices cannot access computing services, potentially risking the lives of patients. In this context, unmanned aerial vehicles (UAVs) are considered a prominent aerial connectivity solution for healthcare systems. In this article, we propose a multiagent federated reinforcement learning (MAFRL)-based resource allocation framework for a multi-UAV-enabled healthcare system. We formulate the computation offloading and resource allocation problems as a Markov decision process game in federated learning with multiple participants. Then, we propose an MAFRL algorithm to solve the formulated problem, minimize latency and energy consumption, and ensure the quality of service. Finally, extensive simulation results on a real-world heartbeat data set prove that the proposed MAFRL algorithm significantly minimizes the cost, preserves privacy, and improves accuracy compared to the baseline learning algorithms.
doi_str_mv	10.1109/JIOT.2023.3283353
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subjects	5G mobile communication Algorithms Computation offloading Edge computing Energy consumption Health care Health care industry Internet of medical things Machine learning Markov processes Medical devices Medical electronics Medical equipment Mobile computing Multiagent systems Network latency Remote monitoring Resource allocation Servers Unmanned aerial vehicles
title	Multiagent Federated Reinforcement Learning for Resource Allocation in UAV-Enabled Internet of Medical Things Networks
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