Scaling laws for ad hoc wireless networks : an information theoretic approach

The advent of ad hoc wireless networks demands fundamental understanding about what they can provide in the way of information transfer as well as what the appropriate architectures are for operating them. Scaling Laws for Ad-Hoc Wireless Networks addresses these questions by presenting various models and results that quantify how their information hauling capacity scales with the number of nodes in the network, and also sheds light on high level architecture design for information transport. It begins by studying wireless networks operating under current technology that spatio-temporally schedules transmissions to alleviate interference, and routes packets in a multi-hop fashion. The second half studies wireless networks from a Shannon information-theoretic point of view, allowing any causal operation and more sophisticated modes of nodal cooperation and information transfer over the shared wireless medium. The constructive procedures for obtaining the sharp lower bounds yield insight into order optimal architecture for wireless networks, while the upper bounds provide guidance to designers in assessing how much and how far information can be transported. This is an invaluable resource for every network engineer or researcher designing or building ad hoc wireless networks.

1 Introduction 2 The Transport Capacity of Arbitrary Wireless Networks - Protocol Model 3 Sharpening the Bounds on Transport Capacity of Arbitrary Networks - Protocol Model 4 The Transport Capacity of Arbitrary Wireless Networks - Physical Model 5 The Throughput Capacity of Random Wireless Networks - Protocol Model 6 The Throughput Capacity of Random Wireless Networks - Physical Model 7 Improved Throughput for Random Wireless Networks Using Differentiated Transmission Ranges 8 An Information Theory for Transport Capacity: The High Attenuation Regime 9 An Information Theory for Transport Capacity: The Low Attenuation Regime 10 The Transport Capacity of Wireless Networks with Fading 11 MIMO Techniques for Wireless Networks 12 Concluding Remarks