On the Amount of Randomness Needed for Improving Distributed Wireless Link Scheduling Under Arbitrary Interference

IF 2.2 3区计算机科学 Q3 COMPUTER SCIENCE, INFORMATION SYSTEMS

IEEE Transactions on Information Theory Pub Date : 2025-02-18 DOI:10.1109/TIT.2025.3542767

Dariusz R. Kowalski;Miguel A. Mosteiro

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引用次数: 0

Abstract

We study the Distributed Wireless Link Scheduling (DWLS) problem: there is a set of n autonomous stations, called senders, each with a message to be delivered to some other station, called receiver. The names and locations of all stations are arbitrarily selected and unknown to each other, to mirror an arbitrary scenario that may occur in mobile communication. Each pair ((sender,receiver),message) is called a request, and the event of successfully delivering the message is called the realization of the request. In the DWLS problem, the requests are realized through wireless communication links (which is a conceptual notion of two nodes being capable of direct wireless delivery of a message) between the stations. The decision to transmit a message is made locally by each station. We consider networks where communication links may interfere with each other, where the interference is an arbitrary input function of each pair of links, customarily called affectance; if the total affectance of other links whose senders are currently transmitting is above a given threshold, the considered transmission is not successful. In the above context, we study the impact of the number of truly random bits used by each link/sender, on the length of the transmission schedules. Specifically, for any set L of n requests with maximum average affectance

$A(L)$

, we present a deterministic algorithm (i.e., 0 random bits) and a randomized algorithm using

$O(\log A(L)\log n)$

random bits per link. (In this abstract we present formulas in simplified forms, for brevity.) The lengths of their transmission schedules are

$O(A(L)^{2}\log ^{3} n)$

and

$O(A(L)\log n)$

, respectively. We then combine both approaches to get a randomized solution using

$O(\log W \log n)$

truly random bits per station with schedules of length

$O\left ({{\frac {A(L)^{2}}{W}\log n}}\right)$

, for any

$W\le A(L)$

. To the best of our knowledge, our study is a first step towards understanding the trade-offs between randomness and time complexity of Link Scheduling under arbitrary interference. It is particularly important as currently used (in practice) wireless protocols are either deterministic or use a very small random seed of (truly) random bits.

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在任意干扰下改进分布式无线链路调度所需的随机量

本文研究了分布式无线链路调度（DWLS）问题：有一组n个自治站，称为发送者，每个站都有一个消息要传递给另一个称为接收者的站。所有站点的名称和位置都是任意选择的，彼此不知道，以反映移动通信中可能出现的任意场景。每一对（（发送方、接收方）、消息）称为一个请求，成功传递消息的事件称为请求的实现。在DWLS问题中，请求是通过站之间的无线通信链路实现的（这是两个节点能够直接无线传递消息的概念）。发送消息的决定是由每个电台在本地作出的。我们考虑通信链路可能相互干扰的网络，其中干扰是每对链路的任意输入函数，通常称为影响；如果发送方当前正在传输的其他链路的总影响超过给定的阈值，则认为传输不成功。在上述情况下，我们研究了每个链路/发送者使用的真正随机比特的数量对传输调度长度的影响。具体来说，对于具有最大平均影响$A(L)$的任何集合L （n个请求），我们提出了一个确定性算法（即0个随机比特）和一个使用$O(\log A(L)\log n)$每个链路随机比特的随机算法。（为简洁起见，本文以简化形式给出公式。）它们的传输时间表长度分别为$O(A(L)^{2}\log ^{3} n)$和$O(A(L)\log n)$。然后，我们将两种方法结合起来，得到一个随机的解决方案，使用$O(\log W \log n)$每个站点的真正随机比特，长度为$O\left ({{\frac {A(L)^{2}}{W}\log n}}\right)$，对于任何$W\le A(L)$。据我们所知，我们的研究是理解在任意干扰下链路调度的随机性和时间复杂性之间权衡的第一步。这一点尤其重要，因为目前使用的（在实践中）无线协议要么是确定性的，要么使用非常小的（真正的）随机比特的随机种子。

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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来源期刊

IEEE Transactions on Information Theory 工程技术-工程：电子与电气

CiteScore

5.70

自引率

20.00%

发文量

514

审稿时长

12 months

期刊介绍： The IEEE Transactions on Information Theory is a journal that publishes theoretical and experimental papers concerned with the transmission, processing, and utilization of information. The boundaries of acceptable subject matter are intentionally not sharply delimited. Rather, it is hoped that as the focus of research activity changes, a flexible policy will permit this Transactions to follow suit. Current appropriate topics are best reflected by recent Tables of Contents; they are summarized in the titles of editorial areas that appear on the inside front cover.