Residue Number System Fade Mitigation Technique with Error Detection and Correction on a Satellite Communication Link

Advances in Networks Pub Date : 2021-08-24 DOI:10.11648/J.NET.20210902.11

S. Akobre, M. I. Daabo, Abdul-Mumin Salifu

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引用次数: 1

Abstract

Rain fade is the loss of signal power at the receiver of a telecommunication system mainly due to absorption and scattering caused by rain in the transmission medium, especially at frequencies above 10 GHz. In order to combat the loss of the signal power at the receiver, there is the need to employ rain fade mitigation techniques. Consequently, researchers have been studying how rain affects the signal in different geographical locations as well as proposing some mitigation techniques. Power control is one of the mitigation techniques that have been proposed. But this technique has some associated challenges. Increasing the power will lead to an increase in cost of transmission which will eventually be passed on to the consumer thereby making satellite services expensive. It requires high power in uplink and downlink which increases the burden either on user terminal or satellite payload. Also, because of health concerns there is a limit to the amount of power that can be radiated to the ground and this is governed by international agreements. Another power management drawback in using this technique is that, uplink power control is not efficient in directing the added power to only the ground station experiencing path attenuation, because the additional power is distributed to all locations within the satellite antenna coverage area. In this paper, we address the power control challenges, by leveraging on the inherent properties of Residue Number System (RNS) and Redundant Residue Number System (RRNS) to propose an RNS architecture using the moduli set {22n+1-1, 22n -1, 22n, 24n+1 -1, 22n +1} that can mitigate rain fade in the satellite link as well as detect and correct multiple errors. In digital communication systems, the bit energy, eb, is the most important parameter in determining the communications link performance. Numerical analysis shows that the proposed scheme performs better than the traditional method as indicated in the high energy per bit value obtained in the proposed system in comparison with the traditional method, all other things being equal.

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基于卫星通信链路错误检测与纠错的残数系统衰落抑制技术

雨衰是指通信系统接收机的信号功率损失，主要是由于传输介质中的雨引起的吸收和散射，特别是在10千兆赫以上的频率。为了对抗接收机信号功率的损失，需要采用雨衰减缓技术。因此，研究人员一直在研究降雨如何影响不同地理位置的信号，并提出了一些缓解技术。功率控制是已提出的缓解技术之一。但是这种技术有一些相关的挑战。增加功率将导致传输成本的增加，最终将转嫁给消费者，从而使卫星服务变得昂贵。它对上行链路和下行链路的功率要求很高，增加了用户终端和卫星载荷的负担。此外，出于对健康的考虑，可以辐射到地面的能量是有限制的，这是由国际协定规定的。使用这种技术的另一个电源管理缺点是，上行功率控制在将附加功率仅定向到经历路径衰减的地面站方面效率不高，因为附加功率被分配到卫星天线覆盖区域内的所有位置。在本文中，我们通过利用剩余数系统(RNS)和冗余剩余数系统(RRNS)的固有特性，提出了一种使用模集{22n+1- 1,22n - 1,22n, 24n+1 - 1,22n +1}的RNS架构，以解决功率控制方面的挑战，该架构可以减轻卫星链路中的雨衰减，并检测和纠正多个错误。在数字通信系统中，比特能量(eb)是决定通信链路性能的最重要参数。数值分析表明，在其他条件相同的情况下，该方案比传统方法具有更高的每比特能量值。

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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Advances in Networks

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