Line-of-Sight Networks

Abstract

Random geometric graphs have been one of the fundamental models for reasoning about wireless networks: one places n points at random in a region of the plane (typically a square or circle), and then connects pairs of points by an edge if they are within a fixed distance of one another. In addition to giving rise to a range of basic theoretical questions, this class of random graphs has been a central analytical tool in the wireless networking community. For many of the primary applications of wireless networks, however, the underlying environment has a large number of obstacles, and communication can only take place among nodes when they are close in space and when they have line-of-sight access to one another -- consider, for example, urban settings or large indoor environments. In such domains, the standard model of random geometric graphs is not a good approximation of the true constraints, since it is not designed to capture the line-of-sight restrictions. Here we propose a random-graph model incorporating both range limitations and line-of-sight constraints and we prove asymptotically tight results for k-connectivity. Specifically, we consider points placed randomly on a grid (or torus), such that each node can see up to a fixed distance along the row and column it belongs to. (We think of the rows and columns as "streets" and "avenues" among a regularly spaced array of obstructions.) Further, we show that when the probability of node placement is a constant factor larger than the threshold for connectivity, near-shortest paths between pairs of nodes can be found, with high probability, by an algorithm using only local information. In addition to analyzing connectivity and k-connectivity, we also study the emergence of a giant component, as well an approximation question, in which we seek to connect a set of given nodes in such an environment by adding a small set of additional "relay" nodes.

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Document Details

Document Type
Technical Report
Publication Date
Jan 01, 2007
Accession Number
ADA633661

Entities

People

  • Alan Frieze
  • Jon Kleinberg
  • R. Ravi
  • Warren Debany

Organizations

  • Cornell University

Tags

Communities of Interest

  • Materials and Manufacturing Processes

DTIC Thesaurus Topics

  • Ad Hoc Networks
  • Air Force Research Laboratories
  • Algorithms
  • Communities
  • Computations
  • Computer Science
  • Environment
  • Grids
  • Line Of Sight
  • Mesh Networks
  • Mobile Ad Hoc Networks
  • Networks
  • Probability
  • Radio Frequency
  • Standards
  • Wireless Communications
  • Wireless Networks

Fields of Study

  • Computer science

Readers

  • Graph Algorithms and Convex Optimization.
  • Radio communications and signal processing.
  • Systems Analysis and Design

Technology Areas

  • Space