Curvature of Indoor Sensor Network: Clustering Coefficient

Curvature of Indoor Sensor Network: Clustering Coefficient

<p>Abstract</p> <p>We investigate the geometric properties of the communication graph in realistic low-power wireless networks. In particular, we explore the concept of the curvature of a wireless network via the clustering coefficient. Clustering coefficient analysis is a computat...

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Main Authors: Ariaei F, Lou M, Jonckheere E, Krishnamachari B, Zuniga M
Format: Article
Language:English
Published: SpringerOpen 2008-01-01
Series:EURASIP Journal on Wireless Communications and Networking
Online Access:http://jwcn.eurasipjournals.com/content/2008/213185
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spelling doaj-6057386e6e2f4788950d951d6a71f1b22020-11-25T01:14:49ZengSpringerOpenEURASIP Journal on Wireless Communications and Networking1687-14721687-14992008-01-0120081213185Curvature of Indoor Sensor Network: Clustering CoefficientAriaei FLou MJonckheere EKrishnamachari BZuniga M<p>Abstract</p> <p>We investigate the geometric properties of the communication graph in realistic low-power wireless networks. In particular, we explore the concept of the curvature of a wireless network via the clustering coefficient. Clustering coefficient analysis is a computationally simplified, semilocal approach, which nevertheless captures such a large-scale feature as congestion in the underlying network. The clustering coefficient concept is applied to three cases of indoor sensor networks, under varying thresholds on the link packet reception rate (PRR). A transition from positive curvature ("meshed" network) to negative curvature ("core concentric" network) is observed by increasing the threshold. Even though this paper deals with network curvature per se, we nevertheless expand on the underlying congestion motivation, propose several new concepts (network inertia and centroid), and finally we argue that greedy routing on a virtual positively curved network achieves load balancing on the physical network.</p>http://jwcn.eurasipjournals.com/content/2008/213185
collection DOAJ
language English
format Article
sources DOAJ
author Ariaei F
Lou M
Jonckheere E
Krishnamachari B
Zuniga M
spellingShingle Ariaei F
Lou M
Jonckheere E
Krishnamachari B
Zuniga M
Curvature of Indoor Sensor Network: Clustering Coefficient
EURASIP Journal on Wireless Communications and Networking
author_facet Ariaei F
Lou M
Jonckheere E
Krishnamachari B
Zuniga M
author_sort Ariaei F
title Curvature of Indoor Sensor Network: Clustering Coefficient
title_short Curvature of Indoor Sensor Network: Clustering Coefficient
title_full Curvature of Indoor Sensor Network: Clustering Coefficient
title_fullStr Curvature of Indoor Sensor Network: Clustering Coefficient
title_full_unstemmed Curvature of Indoor Sensor Network: Clustering Coefficient
title_sort curvature of indoor sensor network: clustering coefficient
publisher SpringerOpen
series EURASIP Journal on Wireless Communications and Networking
issn 1687-1472
1687-1499
publishDate 2008-01-01
description <p>Abstract</p> <p>We investigate the geometric properties of the communication graph in realistic low-power wireless networks. In particular, we explore the concept of the curvature of a wireless network via the clustering coefficient. Clustering coefficient analysis is a computationally simplified, semilocal approach, which nevertheless captures such a large-scale feature as congestion in the underlying network. The clustering coefficient concept is applied to three cases of indoor sensor networks, under varying thresholds on the link packet reception rate (PRR). A transition from positive curvature ("meshed" network) to negative curvature ("core concentric" network) is observed by increasing the threshold. Even though this paper deals with network curvature per se, we nevertheless expand on the underlying congestion motivation, propose several new concepts (network inertia and centroid), and finally we argue that greedy routing on a virtual positively curved network achieves load balancing on the physical network.</p>
url http://jwcn.eurasipjournals.com/content/2008/213185
work_keys_str_mv AT ariaeif curvatureofindoorsensornetworkclusteringcoefficient
AT loum curvatureofindoorsensornetworkclusteringcoefficient
AT jonckheeree curvatureofindoorsensornetworkclusteringcoefficient
AT krishnamacharib curvatureofindoorsensornetworkclusteringcoefficient
AT zunigam curvatureofindoorsensornetworkclusteringcoefficient
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