Channel Capacity of Molecular Signaling via Diffusion in Confined Microenvironment

Q3 Mathematics

International Journal of Sensors, Wireless Communications and Control Pub Date : 2022-01-05 DOI:10.2174/2210327912666220105143734

U. Chude-Okonkwo

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引用次数: 0

Abstract

To model molecular signal propagation in confined environment. Molecular communication (MC) is rooted in the concepts of understanding, modeling, and engineering information exchange among naturally and artificially synthesized nanosystems. To develop or analyze an MC system, there is the need to model the communication channel through which the molecular signal diffuse, from the transmitter to the receiver. Many models for the diffusion-based MC channel have been proposed in the literature for evaluating the performance of MC systems. Most of the contemporary works assume, and rightly so for some scenarios, that the MC channels under consideration have infinite boundaries. However, this assumption becomes invalid in bounded domains such as the interiors of natural cells and artificially synthesized nanosystems. In this paper, the model of molecular propagation in a confined. microenvironment is employ to explore the effect of such an environment on the MC system. The mutual information of the channel and specifically the closed-form expression of the channel capacity of the molecular signaling in the confined geometry is derive. Numerical results showing the variation in the channel capacity as the function of the channel dimension are presented. Results showed that the channel capacity increases with the decrease in the channel dimension. Subsequently, as the dimension of the channel tends to the nanoscale range typical of many artificially synthesized nanosystems, the effect of the channel width on the capacity and by induction on many other system metrics increases.

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受限微环境下分子信号扩散的通道容量研究

模拟分子信号在密闭环境中的传播。分子通信(MC)植根于自然和人工合成纳米系统之间的理解、建模和工程信息交换的概念。为了开发或分析MC系统，需要对分子信号从发射机扩散到接收机的通信信道进行建模。文献中已经提出了许多基于扩散的MC通道模型来评估MC系统的性能。大多数当代作品都假设，在某些情况下，所考虑的MC通道具有无限的边界。然而，这种假设在有限的领域是不成立的，比如自然细胞内部和人工合成的纳米系统。本文建立了分子在密闭条件下的传播模型。利用微环境来探讨这种环境对MC系统的影响。导出了通道互信息，特别是分子信号在受限几何条件下通道容量的封闭表达式。给出了信道容量随信道尺寸变化的数值结果。结果表明:沟道容量随沟道尺寸的减小而增大;随后，当通道的尺寸趋向于许多人工合成纳米系统的典型纳米尺度范围时，通道宽度对容量的影响以及通过感应对许多其他系统指标的影响都会增加。

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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来源期刊

International Journal of Sensors, Wireless Communications and Control Engineering-Electrical and Electronic Engineering

CiteScore

2.20

自引率

0.00%

发文量

期刊介绍： International Journal of Sensors, Wireless Communications and Control publishes timely research articles, full-length/ mini reviews and communications on these three strongly related areas, with emphasis on networked control systems whose sensors are interconnected via wireless communication networks. The emergence of high speed wireless network technologies allows a cluster of devices to be linked together economically to form a distributed system. Wireless communication is playing an increasingly important role in such distributed systems. Transmitting sensor measurements and control commands over wireless links allows rapid deployment, flexible installation, fully mobile operation and prevents the cable wear and tear problem in industrial automation, healthcare and environmental assessment. Wireless networked systems has raised and continues to raise fundamental challenges in the fields of science, engineering and industrial applications, hence, more new modelling techniques, problem formulations and solutions are required.