Concept Design of Medium Access Control for Spectrum Access Systems in 3.5 GHz

Z. Youssef, Erfan Majeed, M. Mueck, Ingolf Karls, C. Drewes, G. Bruck, P. Jung
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引用次数: 5

Abstract

The issue of finding a three-tiered spectrum access scheme in the so-called innovation band from 3550 to 3700 MHz for incumbent applications and protection against other priority access licenses (PAL) and general authorized access (GAA) systems has been addressed by the federal communications commission (FCC). The PAL and GAA systems are citizens broadband radio service devices (CBSDs) connected to a spectrum access system (SAS) which controls the spectrum access. The challenge lies in creating an approach, where the CBSDs are able to fulfil interference mitigation (IM) among each other. In this paper, we present the design and results of a hybrid centralized and distributed medium access control (HMAC) scheme for SAS with efficient and self-organized spectrum sharing schemes using machine learning algorithms based on game theory (GT) and reinforcement learning (RL) for GAA CBSDs in an unlicensed spectrum. The system improvement shows how the SAS can assists decision-making algorithms in a minimum intrusive way to fulfill fair interference and channel occupancy compared with state-of-the-art (SoA) schemes, where the SAS uses an interference graph (IG) to solve the channel allocation problem. Moreover, the suggested schemes support the distributed carrier sense multiple access/collision avoidance (CSMA/CA) mechanism to handle adjacent-channel and cochannel interference (ACI, CCI), which opens new perspective for decentralized systems in a SAS context and beyond 5G.
3.5 GHz频谱接入系统介质访问控制的概念设计
美国联邦通信委员会(FCC)已经解决了在3550至3700 MHz的所谓创新频段中为现有应用寻找三层频谱接入方案的问题,并保护其免受其他优先接入许可证(PAL)和一般授权接入(GAA)系统的侵害。PAL和GAA系统是连接到控制频谱接入的频谱接入系统(SAS)的公民宽带无线电业务设备(cbsd)。挑战在于创造一种方法,使cbsd能够相互实现干扰缓解(IM)。在本文中,我们提出了一种用于SAS的混合式集中式和分布式介质访问控制(HMAC)方案的设计和结果,该方案具有高效和自组织的频谱共享方案,使用基于博弈论(GT)和强化学习(RL)的机器学习算法,用于未许可频谱中的GAA cbsd。系统改进表明,与最先进的(SoA)方案相比,SAS如何以最小的侵入方式协助决策算法实现公平的干扰和信道占用,其中SAS使用干扰图(IG)来解决信道分配问题。此外,建议的方案支持分布式载波感知多址/避免碰撞(CSMA/CA)机制来处理邻接信道和共信道干扰(ACI, CCI),这为SAS环境和5G以后的分散系统开辟了新的视角。
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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