Multipath virtual sink architecture for wireless sensor networks in harsh environments

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Multipath virtual sink architecture for wireless sensor networks in harsh environments

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InterSense; Vol. 138 archive
Proceedings of the first international conference on Integrated internet ad hoc and sensor networks table of contents

Nice, France

SESSION: Routing table of contents

Article No. 19

Year of Publication: 2006

ISBN:1-59593-427-8

Authors

Winston K. G. Seah	Institute of Infocomm Research, Heng Mui Keng Terrace (Singapore)
Hwee Pink Tan	EURANDOM, MB Eindhoven (The Netherlands)

Sponsors

: EU (IST-FET)
: Create-Net
: ICST

Publisher

ACM New York, NY, USA

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ABSTRACT

Wireless sensor networks are expected to be deployed in harsh environments characterized by extremely poor and fluctuating channel conditions. With the generally adopted single-sink architecture, be it static or mobile, such conditions arise due to contention near the sink as a result of multipath data delivery. The compactness of sensors with limited energy resources restricts the use of sophisticated FEC or ARQ mechanisms to improve the reliability of transmissions under such adverse conditions.We propose a novel virtual sink architecture for wireless sensor networks that mitigates the near-sink contention by defining a group of spatially diverse physical sinks. Reliability and energy efficiency is achieved through multipath data delivery to the sinks without the need for sophisticated FEC or ARQ mechanisms. This architecture is especially suitable for indoor environments, where channel conditions are harsh due to severe multipath fading, as well as emerging applications like underwater sensor networks where the predominant physical layer is acoustic communications, which is characterized by long propagation delays and severely fluctuating link conditions. We present our proposed architecture and demonstrate its efficacy using mathematical analysis.

REFERENCES

Note: OCR errors may be found in this Reference List extracted from the full text article. ACM has opted to expose the complete List rather than only correct and linked references.

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