Global connectivity from local geometric constraints for sensor networks with various wireless footprints

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Global connectivity from local geometric constraints for sensor networks with various wireless footprints

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Information Processing In Sensor Networks archive
Proceedings of the 5th international conference on Information processing in sensor networks table of contents

Nashville, Tennessee, USA

SESSION: Main track--sensor selection and placement table of contents

Pages: 19 - 26

Year of Publication: 2006

ISBN:1-59593-334-4

Authors

Raissa D'Souza	University of California, Davis, CA
David Galvin	University of Pennsylvania, Philadelphia, PA
Cristopher Moore	University of New Mexico, Albuquerque, NM
Dana Randall	Georgia Inst. of Tech., Atlanta, GA

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ACM: Association for Computing Machinery

Publisher

ACM New York, NY, USA

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ABSTRACT

Adaptive power topology control (APTC) is a local algorithm for constructing a one-parameter family of θ-graphs, where each node increases power until it has a neighbor in every θ sector around it.We show it is possible to use such a local geometric θ-constraint to ensure full network connectivity, and consider tradeoffs between assumptions about the wireless footprint and constraints on the boundary nodes. In particular, we show that if the boundary nodes can communicate with neighboring boundary nodes and all interior nodes satisfy a θ_I π constraint, we can guarantee connectivity for any arbitrary wireless footprint. If we relax the boundary assumption and instead impose a θ_B < 3π/2 constraint on the boundary nodes, together with the θ_I < π constraint on interior nodes, we can guarantee full network connectivity using only a "weak-monotonicity" footprint assumption. The weak-monotonicity model, introduced herein, is much less restrictive than the disk model of coverage and captures aspects of the spatial correlations inherent in signal propagation and noise. We show that under the idealized disk model of coverage, APTC constructs graphs that are sparse. Finally, we show that if the wireless footprint has sufficiently small "eccentricity", then there is some θ for which greedy geometric routing always succeeds.

REFERENCES

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