Programming Wireless Sensor Networks in a Self-Stabilizing Style

Author

Weyer, Christoph ; Turau, Volker ; Lagemann, Andreas ; Nolte, Jörg

Author_Institution

Inst. of Telematics, Hamburg Univ. of Technol., Hamburg, Germany

fYear

2009

fDate

18-23 June 2009

Firstpage

610

Lastpage

616

Abstract

Wireless sensor networks operate in an unstable environment and thus are subject to arbitrary transient faults. Self-stabilization is a promising technique to add tolerance against transient faults in a self-contained non-masking way. A core factor for the applicability of a given self-stabilizing algorithm is its convergence time. This paper analyses the average stabilization time of three algorithms commonly regarded as central building blocks for wireless sensor networks. The analysis is accomplished with SelfWISE, a framework providing programming abstractions for self-stabilizing algorithms. The performed analysis considers the target models as well as network size and density. This demonstrates the usability of SelfWISE for evaluating self-stabilizing algorithms under a wide range of models.

Keywords

fault tolerance; telecommunication network reliability; wireless sensor networks; WSN programming; arbitrary transient fault tolerance; convergence time; self-contained non-masking way; self-stabilizing technique; target model; wireless sensor network; Algorithm design and analysis; Clustering algorithms; Concurrent computing; Convergence; Fault tolerance; Runtime environment; Scheduling algorithm; Sensor systems and applications; Upper bound; Wireless sensor networks; Model Transformation; Self Stabilization; Wireless Sensor Networks;

fLanguage

English

Publisher

ieee

Conference_Titel

Sensor Technologies and Applications, 2009. SENSORCOMM '09. Third International Conference on

Conference_Location

Athens, Glyfada

Print_ISBN

978-0-7695-3669-9

Type

conf

DOI

10.1109/SENSORCOMM.2009.100

Filename

5210843