Operating Regimes of Large Wireless Networks

Found. Trends Netw. Pub Date : 2011-12-14 DOI:10.1561/1300000016

Ayfer Özgür, O. Lévêque, David Tse

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引用次数: 22

Abstract

Multi-hop is the current communication architecture of wireless mesh and ad hoc networks. Information is relayed from each source to its destination in successive transmissions between intermediate nodes. A major problem regarding this architecture is its poor performance at large system size: as the number of users in a wireless network increases, the communication rate for each user rapidly decreases. Can we design new communication architectures that significantly increase the capacity of large wireless networks? In this monograph, we present a scaling law characterization of the information-theoretic capacity of wireless networks, which sheds some light on this question. We show that the answer depends on the parameter range in which a particular network lies, namely the operating regime of the network. There are operating regimes where the information-theoretic capacity of the network is drastically higher than the capacity of conventional multi-hop. New architectures can provide substantial capacity gains here. We determine what these regimes are and investigate the new architectures that are able to approach the information-theoretic capacity of the network. In some regimes, there is no way to outperform multi-hop. In other words, the conventional multi-hop architecture indeed achieves the information-theoretic capacity of the network. We discuss the fundamental factors limiting the capacity of the network in these regimes and provide an understanding of why conventional multi-hop indeed turns out to be the right architecture. The monograph is structured as follows: In Section 2, we discuss the role of interference in wireless networks. We show that while current communication architectures are fundamentally limited by interference, new architectures based on distributed MIMO communication can overcome this interference limitation, yielding drastic performance improvements. Section 3 discusses the impact of power. We show that in power-limited regimes, distributed MIMO-based techniques are important not only because they remove interference but also because they provide received power gain. We identify the power-limited operating regimes of wireless networks and define the engineering quantities that determine the operating regime of a given wireless network. We show that unless the wireless network operates in a severely power-limited regime, distributed MIMO communication provides significant capacity gain over current techniques. Finally, in Section 4, we study how the area of the network, i.e., space, impacts the capacity of the network. This study enriches the earlier picture by adding new operating regimes where wireless networks can be moderately or severely space-limited. We see that unless the network is severely limited in space, distributed-MIMO-based communication continues to provide drastic improvements over conventional multi-hop.

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大型无线网络的运作机制

多跳是当前无线网状网络和自组网的通信体系结构。信息通过中间节点之间的连续传输从每个源传递到目的地。这种体系结构的一个主要问题是它在大系统规模下的性能差:随着无线网络中用户数量的增加，每个用户的通信速率迅速降低。我们能否设计出新的通信架构来显著增加大型无线网络的容量?在这篇专著中，我们提出了无线网络信息论容量的标度律特征，这对这个问题有所启发。我们证明了答案取决于特定网络所处的参数范围，即网络的运行状态。在某些情况下，网络的信息论容量大大高于传统多跳网络的容量。新架构可以在这方面提供大量的容量增益。我们确定了这些机制是什么，并研究了能够接近网络信息理论能力的新架构。在某些情况下，没有办法超越多跳。换句话说，传统的多跳结构确实实现了网络的信息论容量。我们讨论了在这些情况下限制网络容量的基本因素，并提供了为什么传统的多跳确实是正确的体系结构的理解。本专著的结构如下:在第2节中，我们讨论了无线网络中干扰的作用。我们表明，虽然当前的通信架构从根本上受到干扰的限制，但基于分布式MIMO通信的新架构可以克服这种干扰限制，从而大幅提高性能。第3节讨论权力的影响。我们表明，在功率有限的情况下，基于mimo的分布式技术很重要，不仅因为它们可以消除干扰，还因为它们提供接收功率增益。我们确定了无线网络的功率限制运行状态，并定义了决定给定无线网络运行状态的工程量。我们表明，除非无线网络在严重的功率限制下运行，否则分布式MIMO通信比当前技术提供了显着的容量增益。最后，在第4节中，我们研究了网络的面积，即空间，如何影响网络的容量。这项研究通过增加无线网络可能受到适度或严重空间限制的新操作机制，丰富了早期的图景。我们看到，除非网络在空间上受到严重限制，否则基于分布式mimo的通信将继续比传统的多跳通信提供巨大的改进。

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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