Coexistence-aware dynamic channel allocation for 3.5 GHz shared spectrum systems

2017 IEEE International Symposium on Dynamic Spectrum Access Networks (DySPAN) Pub Date : 2017-03-01 DOI:10.1109/DySPAN.2017.7920771

Xuhang Ying, M. Buddhikot, Sumit Roy

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引用次数: 14

Abstract

The paradigm of shared spectrum allows secondary devices to opportunistically access spectrum bands underutilized by primary owners. As the first step, the FCC targeted sharing the 3.5 GHz (3550–3700 MHz) federal spectrum with commercial systems. The proposed rules require a Spectrum Access System to implement a three-tiered spectrum management framework, and one of its key functions is dynamic channel allocation (CA) for secondary devices. In this paper, we introduce coexistence-aware radio-channel-pair conflict graphs to capture pairwise interference, spatial channel availability variations, channel contiguity, and coexistence opportunities. We develop a super-radio formation algorithm to identify valid super-radios, i.e., a set of radios that can coexist on the same channel(s) via WiFi-like carrier-sensing mechanisms. With the proposed generic graph representation, we formulate CA as conflict-free max-demand CA with a min-demand constraint, and develop algorithms based on maximum weighted independent set. Preliminary results demonstrate good performance of proposed algorithms and benefits of coexistence.

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3.5 GHz共享频谱系统的共存感知动态信道分配

共享频谱的范例允许辅助设备机会地访问主要所有者未充分利用的频谱频段。作为第一步，FCC的目标是与商业系统共享3.5 GHz (3550-3700 MHz)联邦频谱。该规则要求频谱接入系统实现三层频谱管理框架，其中一项关键功能是辅助设备的动态信道分配(CA)。在本文中，我们引入了共存感知的无线电信道对冲突图来捕获成对干扰、空间信道可用性变化、信道相邻性和共存机会。我们开发了一种超级无线电形成算法来识别有效的超级无线电，即通过类似wifi的载波传感机制在同一频道上共存的一组无线电。利用提出的通用图表示，我们将CA表述为具有最小需求约束的无冲突最大需求CA，并开发了基于最大加权独立集的算法。初步结果表明，所提算法具有良好的性能和共存的优点。

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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2017 IEEE International Symposium on Dynamic Spectrum Access Networks (DySPAN)

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