Emission Time Estimation with Rectangular Input Concentration in Molecular Communication Systems

Ajit Kumar, Sudhir Kumar
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引用次数: 1

Abstract

The nanomachine has a finite processing capability due to size, power, and complexity constraints. To overcome these issues, nanomachine must cooperate to optimize its information exchange operations. Clock synchronization is required for nanomachine cooperation. In Molecular Communication (MC), synchronization is a challenging task due to the random move-ment of molecules that causes inter-symbol interference (ISI) and non-stationary noise. In this paper, we propose a method for clock synchronization between the transmitter nanomachine (TN) and the receiver nanomachine (RN) based on the molecule's emission time estimation. In the presence of both signal-dependent noise and ISI, clock synchronization is performed using maximum likelihood estimation (MLE). The proposed method takes into account a non-zero emission duration of molecules by the TN. The clock synchronization with rectangular input concentration is realistic for practical applications because the emission duration of molecules can not be zero. The effectiveness of the proposed method is shown by numerical results.
基于矩形输入浓度的分子通信系统发射时间估计
由于尺寸、功率和复杂性的限制,纳米机器的处理能力有限。为了克服这些问题,纳米机器必须协作以优化其信息交换操作。时钟同步是纳米机器协作的必要条件。在分子通信(MC)中,由于分子的随机运动会引起码间干扰(ISI)和非平稳噪声,同步是一项具有挑战性的任务。本文提出了一种基于分子发射时间估计的发射端纳米机(TN)和接收端纳米机(RN)时钟同步方法。在存在信号相关噪声和ISI的情况下,使用最大似然估计(MLE)进行时钟同步。该方法考虑了分子的非零发射持续时间。由于分子的发射持续时间不可能为零,因此与矩形输入浓度的时钟同步在实际应用中是现实的。数值结果表明了该方法的有效性。
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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