Optimum Resource Allocation in 6G Optical Wireless Communication Systems

2020 2nd 6G Wireless Summit (6G SUMMIT) Pub Date : 2020-01-07 DOI:10.1109/6GSUMMIT49458.2020.9083828

O. Z. Alsulami, A. Alahmadi, Sarah O. M. Saeed, S. Mohamed, T. El-Gorashi, M. Alresheedi, J. Elmirghani

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引用次数: 9

Abstract

Optical wireless communication (OWC) systems are a promising communication technology that can provide high data rates into the tens of Tb/s and can support multiple users at the same time. This paper investigates the optimum allocation of resources in wavelength division multiple access (WDMA) OWC systems to support multiple users. A mixed-integer linear programming (MILP) model is developed to optimise the resource allocation. Two types of receivers are examined, an angle diversity receiver (ADR) and an imaging receiver (ImR). The ImR can support high data rates up to 14 Gbps for each user with a higher signal to interference plus noise ratio (SINR). The ImR receiver provides a better result compared to the ADR in term of channel bandwidth, SINR and data rate. Given the highly directional nature of light, the space dimension can be exploited to enable the co-existence of multiple, spatially separated, links and thus aggregate data rates into the Tb/s. We have considered a visible light communication (VLC) setting with four wavelengths per access point (red, green, yellow and blue). In the infrared spectrum, commercial sources exist that can support up to 100 wavelengths, significantly increasing the system aggregate capacity. Other orthogonal domains can be exploited to lead to higher capacities in these future systems in 6G and beyond.

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6G光无线通信系统的资源优化分配

光无线通信(OWC)系统是一种很有前途的通信技术，它可以提供高达几十Tb/s的高数据速率，并且可以同时支持多个用户。研究了波分多址(WDMA) OWC系统中支持多用户的资源优化分配问题。提出了一种混合整数线性规划(MILP)模型来优化资源分配。研究了两种类型的接收机，角度分集接收机(ADR)和成像接收机(ImR)。ImR可以为每个用户支持高达14 Gbps的高数据速率，具有更高的信噪比(SINR)。ImR接收机在信道带宽、信噪比和数据速率方面都优于ADR。鉴于光的高度方向性，可以利用空间维度来实现多个空间分离的链路共存，从而将数据速率聚合到Tb/s。我们考虑了一个可见光通信(VLC)设置，每个接入点有四个波长(红、绿、黄、蓝)。在红外光谱中，存在可支持多达100个波长的商用光源，大大增加了系统的总容量。可以利用其他正交域在这些未来的6G及以后的系统中获得更高的容量。

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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2020 2nd 6G Wireless Summit (6G SUMMIT)

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