Effective Beam Width of Directional Antennas in Wireless Ad Hoc Networks

TL;DR

This paper introduces the effective beam width, a quantitative measure that captures how directional antennas improve wireless ad hoc network capacity, considering antenna pattern, node distribution, and channel effects.

Contribution

It defines the effective beam width as a unified measure for antenna effectiveness, analyzes its properties, and derives capacity scaling laws for phased array antennas in ad hoc networks.

Findings

Effective beam width quantifies capacity-boosting potential of directional antennas.

Mathematical properties of effective beam width facilitate analysis of complex antenna patterns.

Phased array antennas with N elements can increase network capacity by approximately N^1.620.

Abstract

It is known at a qualitative level that directional antennas can be used to boost the capacity of wireless ad hoc networks. Lacking is a measure to quantify this advantage and to compare directional antennas of different footprint patterns. This paper introduces the concept of the effective beam width (and the effective null width as its dual counterpart) as a measure which quantitatively captures the capacity-boosting capability of directional antennas. Beam width is commonly defined to be the directional angle spread within which the main-lobe beam power is above a certain threshold. In contrast, our effective beam width definition lumps the effects of the (i) antenna pattern, (ii) active-node distribution, and (iii) channel characteristics, on network capacity into a single quantitative measure. We investigate the mathematical properties of the effective beam width and show how the convenience afforded by these properties can be used to analyze the effectiveness of complex directional antenna patterns in boosting network capacity, with fading and multi-user interference taken into account. In particular, we derive the extent to which network capacity can be scaled with the use of phased array antennas. We show that a phased array antenna with N elements can boost transport capacity of an Aloha-like network by a factor of order N^1.620.