Lisa Y. Debus;Pit Hofmann;Jorge Torres Gómez;Frank H. P. Fitzek;Falko Dressler
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引用次数: 0
Abstract
Relay mechanisms are an important part of communication systems and, therefore, naturally occurring molecular communication (MC) links. Multiple techniques have been proposed for designing MC relay-aided setups, assuming synchronous operation and perfect timing during the decoding process. In this paper, we propose using a reinforcement learning (RL)-based synchronizer to continually adapt a decoding threshold and detect transmitted synchronization frames in a dynamic MC environment. We implement our approach in a two-hop MC link model with mobility and show its advantages compared to filter-based maximum likelihood (ML) synchronization. Thereby, we utilized a macroscale, air-based MC testbed for the experimental determination of the channel impulse response (CIR) for a more realistic channel model. Our simulation results exhibit the potential of an RL-based synchronizer with a similarly high detection rate, a false positive rate one order of magnitude lower, and a misalignment several bit times lower compared to the state of the art.
中继机制是通信系统的重要组成部分,因此也是自然出现的分子通信(MC)链路的重要组成部分。目前已经提出了多种技术来设计 MC 中继辅助设置,这些技术假定在解码过程中同步运行和完美定时。在本文中,我们建议使用基于强化学习(RL)的同步器来不断调整解码阈值,并检测动态 MC 环境中传输的同步帧。我们在具有移动性的双跳 MC 链路模型中实施了我们的方法,并展示了它与基于滤波器的最大似然 (ML) 同步相比的优势。因此,我们利用一个基于空气的宏观 MC 试验台,对更真实的信道模型进行了信道脉冲响应(CIR)的实验测定。我们的仿真结果表明,基于 RL 的同步器具有类似的高检测率潜力,误报率比现有技术低一个数量级,错位率比现有技术低数倍。
期刊介绍:
As a result of recent advances in MEMS/NEMS and systems biology, as well as the emergence of synthetic bacteria and lab/process-on-a-chip techniques, it is now possible to design chemical “circuits”, custom organisms, micro/nanoscale swarms of devices, and a host of other new systems. This success opens up a new frontier for interdisciplinary communications techniques using chemistry, biology, and other principles that have not been considered in the communications literature. The IEEE Transactions on Molecular, Biological, and Multi-Scale Communications (T-MBMSC) is devoted to the principles, design, and analysis of communication systems that use physics beyond classical electromagnetism. This includes molecular, quantum, and other physical, chemical and biological techniques; as well as new communication techniques at small scales or across multiple scales (e.g., nano to micro to macro; note that strictly nanoscale systems, 1-100 nm, are outside the scope of this journal). Original research articles on one or more of the following topics are within scope: mathematical modeling, information/communication and network theoretic analysis, standardization and industrial applications, and analytical or experimental studies on communication processes or networks in biology. Contributions on related topics may also be considered for publication. Contributions from researchers outside the IEEE’s typical audience are encouraged.