DTWN: Q-learning-based Transmit Power Control for Digital Twin WiFi Networks

Q2 Engineering
Lal Verda Çakır, Khayal Huseynov, Elif Ak, B. Canberk
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引用次数: 3

Abstract

Interference has always been the main threat to the performance of traditional WiFi networks and next-generation moving forward. The problem can be solved with transmit power control(TPC). However, to accomplish this, an information-gathering process is required. But this brings overhead concerns that decrease the throughput. Moreover, mitigation of interference relies on the selection of transmit powers. In other words, the control scheme should select the optimum configuration relative to other possibilities based on the total interference, and this requires an extensive search. Furthermore, bidirectional communication in real-time needs to exist to control the transmit powers based on the current situation. Based on these challenges, we propose a complete solution with Digital Twin WiFi Networks (DTWN). Contrarily to other studies, with the agent programs installed on the APs in the physical layer of this architecture, we enable information-gathering without causing overhead to the wireless medium. Additionally, we employ Q-learning-based TPC in the Brain Layer to find the best configuration given the current situation. Consequently, we accomplish real-time monitoring and management thanks to the digital twin. Then, we evaluate the performance of the proposed approach through total interference and throughput metrics over the increasing number of users. Furthermore, we show that the proposed DTWN model outperforms existing schemes.
基于q学习的数字孪生WiFi网络发射功率控制
干扰一直是传统WiFi网络和下一代WiFi网络性能的主要威胁。这一问题可以通过发射功率控制(TPC)来解决。然而,要做到这一点,需要一个信息收集过程。但是这会带来降低吞吐量的开销问题。此外,干扰的抑制依赖于发射功率的选择。换句话说,控制方案应根据总干扰选择相对于其他可能性的最优配置,这需要广泛的搜索。此外,还需要实时的双向通信,以根据现状控制发射功率。基于这些挑战,我们提出了一个完整的解决方案,即数字孪生WiFi网络(DTWN)。与其他研究相反,通过在该体系结构的物理层的ap上安装代理程序,我们可以在不增加无线介质开销的情况下收集信息。此外,我们在脑层中使用基于q学习的TPC来找到给定当前情况的最佳配置。因此,我们通过数字孪生实现了实时监控和管理。然后,我们通过增加用户数量的总干扰和吞吐量指标来评估所提出方法的性能。此外,我们还证明了所提出的DTWN模型优于现有的方案。
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来源期刊
CiteScore
4.00
自引率
0.00%
发文量
15
审稿时长
10 weeks
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