How Well Can Graphs Represent Wireless Interference?

M. Halldórsson, Tigran Tonoyan
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引用次数: 39

Abstract

Efficient use of a wireless network requires that transmissions be grouped into feasible sets, where feasibility means that each transmission can be successfully decoded in spite of the interference caused by simultaneous transmissions. Feasibility is most closely modeled by a signal-to-interference-plus-noise (SINR) formula, which unfortunately is conceptually complicated, being an asymmetric, cumulative, many-to-one relationship. We re-examine how well graphs can capture wireless receptions as encoded in SINR relationships, placing them in a framework in order to understand the limits of such modelling. We seek for each wireless instance a pair of graphs that provide upper and lower bounds on the feasibility relation, while aiming to minimize the gap between the two graphs. The cost of a graph formulation is the worst gap over all instances, and the price of (graph) abstraction is the smallest cost of a graph formulation. We propose a family of conflict graphs that is parameterized by a non-decreasing sub-linear function, and show that with a judicious choice of functions, the graphs can capture feasibility with a cost of O(log* Δ), where Δ is the ratio between the longest and the shortest link length. This holds on the plane and more generally in doubling metrics. We use this to give greatly improved O(log* Δ)-approximation for fundamental link scheduling problems with arbitrary power control. We also explore the limits of graph representations and find that our upper bound is tight: the price of graph abstraction is Ω(log* Δ). In addition, we give strong impossibility results for general metrics, and for approximations in terms of the number of links.
图形如何很好地表示无线干扰?
无线网络的有效使用要求将传输分组为可行集,其中可行性意味着尽管同时传输造成干扰,但每个传输都可以成功解码。可行性最接近的模型是信号干扰加噪声(SINR)公式,不幸的是,这个公式在概念上很复杂,是一种不对称的、累积的、多对一的关系。我们重新研究了图形如何很好地捕获在信噪比关系中编码的无线接收,将它们放在一个框架中,以便了解这种建模的局限性。我们为每个无线实例寻找一对提供可行性关系上界和下界的图,同时力求最小化两个图之间的差距。图公式的成本是所有实例中最大的差距,而(图)抽象的成本是图公式的最小成本。我们提出了一组由非递减次线性函数参数化的冲突图,并表明,通过明智地选择函数,图可以以O(log* Δ)的代价捕获可行性,其中Δ是最长和最短链路长度之间的比率。这在平面上是成立的,更普遍的是在双指标上。对于任意功率控制的基本链路调度问题,我们使用该方法给出了改进的O(log* Δ)近似。我们还探索了图表示的极限,并发现我们的上界是紧的:图抽象的价格是Ω(log* Δ)。此外,我们给出了一般指标的强不可能结果,以及根据链接数量的近似值。
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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