Multi-level equilibrium signaling for molecular communication

B. C. Akdeniz, Malcolm Egan
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引用次数: 2

Abstract

Two key challenges in diffusion-based molecular communication are low data rates and accounting for the geometry of the fluid medium in the form of obstacles and the boundary. To reduce the need for the receiver to have knowledge of the geometry of the medium, binary equilibrium signaling has recently been proposed for molecular communication with a passive receiver in bounded channels. In this approach, reversible chemical reactions are introduced at the transmitter and the receiver in order for the system to converge to a known equilibrium state. This provides a means of designing simple detection rules that only depend on the transmitted signal and the volume of the bounded fluid medium. In this paper, we introduce multi-level equilibrium signaling, which allows for higher data rates via higher order modulation. We show that for a wide range of conditions, with appropriate receiver optimization, multi-level equilibrium signaling can outperform conventional concentration shift keying schemes. As such, our approach provides a basis to improve data rates in molecular communications without the need to increase the complexity of the system by exploiting techniques such as multiple information-carrying molecules.
分子通信的多级平衡信号
基于扩散的分子通信的两个关键挑战是低数据速率和以障碍物和边界形式计算流体介质的几何形状。为了减少接收器对介质几何知识的需求,最近提出了在有界通道中与被动接收器进行分子通信的二元平衡信号。在这种方法中,为了使系统收敛到已知的平衡状态,在发送端和接收端引入了可逆的化学反应。这提供了一种设计简单的检测规则的方法,该规则仅依赖于传输的信号和有界流体介质的体积。在本文中,我们引入了多级平衡信令,它允许通过高阶调制获得更高的数据速率。我们表明,在广泛的条件下,通过适当的接收器优化,多级平衡信令可以优于传统的集中移位键控方案。因此,我们的方法为提高分子通信的数据速率提供了基础,而不需要通过利用多种携带信息的分子等技术来增加系统的复杂性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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