The Topology of Wireless Communication on a Line

Erez Kantor; Zvi Lotker; Merav Parter; David Peleg

doi:10.1016/j.tcs.2017.10.002

The Topology of Wireless Communication on a Line

Erez Kantor, Zvi Lotker, Merav Parter, David Peleg

Ben-Gurion University of the Negev, Weizmann Institute of Science, Technion - Israel Institute of Technology

Research output: Contribution to journal › Article › peer-review

Abstract

This note considers a 1-dimensional wireless network consisting of a set of n stations located on a line, in the SINR model, which compares the received power of a signal at a receiver against the sum of strengths of other interfering signals plus background noise. The behavior of a multi-station network is described using the convenient representation of a reception diagram. In the SINR model, the resulting SINR diagram partitions the plane into reception zones, one per station, and the complementary region of the plane where no station can be heard. We use the minimum principle, recently shown to hold for the SINR function, to derive a tight bound on the number of connected components in 1-dimensional networks.

Original language	American English
Pages (from-to)	105-108
Number of pages	4
Journal	Theoretical Computer Science
Volume	711
DOIs	https://doi.org/10.1016/j.tcs.2017.10.002
State	Published - 8 Feb 2018

Keywords

Connectivity
Non-uniform power
SINR

All Science Journal Classification (ASJC) codes

Theoretical Computer Science
General Computer Science

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10.1016/j.tcs.2017.10.002

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title = "The Topology of Wireless Communication on a Line",

abstract = "This note considers a 1-dimensional wireless network consisting of a set of n stations located on a line, in the SINR model, which compares the received power of a signal at a receiver against the sum of strengths of other interfering signals plus background noise. The behavior of a multi-station network is described using the convenient representation of a reception diagram. In the SINR model, the resulting SINR diagram partitions the plane into reception zones, one per station, and the complementary region of the plane where no station can be heard. We use the minimum principle, recently shown to hold for the SINR function, to derive a tight bound on the number of connected components in 1-dimensional networks.",

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AU - Parter, Merav

AU - Peleg, David

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N2 - This note considers a 1-dimensional wireless network consisting of a set of n stations located on a line, in the SINR model, which compares the received power of a signal at a receiver against the sum of strengths of other interfering signals plus background noise. The behavior of a multi-station network is described using the convenient representation of a reception diagram. In the SINR model, the resulting SINR diagram partitions the plane into reception zones, one per station, and the complementary region of the plane where no station can be heard. We use the minimum principle, recently shown to hold for the SINR function, to derive a tight bound on the number of connected components in 1-dimensional networks.

AB - This note considers a 1-dimensional wireless network consisting of a set of n stations located on a line, in the SINR model, which compares the received power of a signal at a receiver against the sum of strengths of other interfering signals plus background noise. The behavior of a multi-station network is described using the convenient representation of a reception diagram. In the SINR model, the resulting SINR diagram partitions the plane into reception zones, one per station, and the complementary region of the plane where no station can be heard. We use the minimum principle, recently shown to hold for the SINR function, to derive a tight bound on the number of connected components in 1-dimensional networks.

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JO - Theoretical Computer Science

JF - Theoretical Computer Science

ER -

The Topology of Wireless Communication on a Line

Abstract

Keywords

All Science Journal Classification (ASJC) codes

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