Minimizing Delay in UAV-Aided Federated Learning for IoT Applications With Straggling Devices

IF 6.3 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC IEEE Open Journal of the Communications Society Pub Date : 2024-11-22 DOI:10.1109/OJCOMS.2024.3504852

Mudassar Liaq;Waleed Ejaz

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Abstract

The Internet of Things (IoT) applications generate large volumes of data, which needs to be processed securely, reliably, and promptly for effective decision-making. However, the limited processing capability of IoT devices is a significant bottleneck in processing these datasets. In scenarios like forest fire surveillance, flash flood alert systems, or wildlife activity tracking, where IoT devices are deployed in remote locations and only need coverage for a few weeks a year, thus deploying permanent base stations is not a feasible solution. One potential solution to overcome this challenge is to use Federated learning (FL) with unmanned aerial vehicle (UAV) as mobile edge computing (MEC) servers. FL enables collaborative model training across decentralized IoT devices by keeping data local, eliminating the need for centralized data collection. This approach is especially effective when IoT devices generate large volumes of data, making FL an ideal solution for data-sensitive, resource-constrained environments. In this paper, we propose a UAV-aided FL framework that utilizes the computation capacity of UAV-MEC to process some portion of the datasets from the straggling devices (devices which are unable to process their dataset in reasonable time and are lagging, increasing delay in the whole system). We also incorporate an IoT device importance and selection scheme to further improve system performance. We formulate an optimization problem to minimize system delay, considering UAV-MEC’s computation power, computation and communication power of IoT devices, and quality of service constraints. To solve the problem, we transform the proposed problem by introducing auxiliary variables and epigraph form. We then use the concurrent deterministic simplex with root relaxation algorithm. We also propose a deep reinforcement learning (DRL)-based solution to improve runtime complexity. Simulation results show the effectiveness of the proposed framework compared to existing approaches.

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具有分散设备的物联网应用的无人机辅助联邦学习延迟最小化

物联网（IoT）应用会产生大量数据，需要对这些数据进行安全、可靠和及时的处理，以便做出有效决策。然而，物联网设备有限的处理能力是处理这些数据集的一大瓶颈。在森林火灾监控、山洪暴发警报系统或野生动物活动跟踪等场景中，物联网设备部署在偏远地区，每年只需要覆盖几个星期，因此部署永久性基站并不是一个可行的解决方案。克服这一挑战的一个潜在解决方案是将无人飞行器（UAV）作为移动边缘计算（MEC）服务器，使用联合学习（FL）。通过保持本地数据，FL 能够在分散的物联网设备之间进行协作模型训练，从而消除了集中数据收集的需要。当物联网设备产生大量数据时，这种方法尤其有效，使 FL 成为数据敏感、资源受限环境的理想解决方案。在本文中，我们提出了一种无人机辅助 FL 框架，它利用无人机-MEC 的计算能力来处理来自滞后设备（无法在合理时间内处理其数据集且滞后的设备，增加了整个系统的延迟）的部分数据集。我们还采用了物联网设备重要性和选择方案，以进一步提高系统性能。考虑到 UAV-MEC 的计算能力、物联网设备的计算能力和通信能力以及服务质量限制，我们提出了一个优化问题，以最小化系统延迟。为了解决这个问题，我们通过引入辅助变量和外显形式对提出的问题进行了转换。然后，我们使用带根松弛的并发确定性单纯形算法。我们还提出了一种基于深度强化学习（DRL）的解决方案，以改善运行时的复杂性。仿真结果表明，与现有方法相比，我们提出的框架非常有效。

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来源期刊

IEEE Open Journal of the Communications Society Multiple-

CiteScore

13.70

自引率

3.80%

发文量

审稿时长

10 weeks

期刊介绍： The IEEE Open Journal of the Communications Society (OJ-COMS) is an open access, all-electronic journal that publishes original high-quality manuscripts on advances in the state of the art of telecommunications systems and networks. The papers in IEEE OJ-COMS are included in Scopus. Submissions reporting new theoretical findings (including novel methods, concepts, and studies) and practical contributions (including experiments and development of prototypes) are welcome. Additionally, survey and tutorial articles are considered. The IEEE OJCOMS received its debut impact factor of 7.9 according to the Journal Citation Reports (JCR) 2023. The IEEE Open Journal of the Communications Society covers science, technology, applications and standards for information organization, collection and transfer using electronic, optical and wireless channels and networks. Some specific areas covered include: Systems and network architecture, control and management Protocols, software, and middleware Quality of service, reliability, and security Modulation, detection, coding, and signaling Switching and routing Mobile and portable communications Terminals and other end-user devices Networks for content distribution and distributed computing Communications-based distributed resources control.