VLSI implementation of an energy-aware wake-up detector for an acoustic surveillance sensor network

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VLSI implementation of an energy-aware wake-up detector for an acoustic surveillance sensor network

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ACM Transactions on Sensor Networks (TOSN) archive
Volume 2 , Issue 4 (November 2006) table of contents

Pages: 594 - 611

Year of Publication: 2006

ISSN:1550-4859

Authors

David H. Goldberg	Johns Hopkins University, Baltimore, MD
Andreas G. Andreou	Johns Hopkins University, Baltimore, MD
Pedro Julián	Universidad Nacional del Sur, Bahía Blanca, CP, Argentina
Philippe O. Pouliquen	Johns Hopkins University, Baltimore, MD
Laurence Riddle	Signal Systems Corporation, Severna Park, MD
Rich Rosasco	Signal Systems Corporation, Severna Park, MD

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ACM New York, NY, USA

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ABSTRACT

We present a low-power VLSI wake-up detector for a sensor network that uses acoustic signals to localize ground-based vehicles. The detection criterion is the degree of low-frequency periodicity in the acoustic signal, and the periodicity is computed from the “bumpiness” of the autocorrelation of a one-bit version of the signal. We then describe a CMOS ASIC that implements the periodicity estimation algorithm. The ASIC is fully functional and its core consumes 835 nanowatts. It was integrated into an acoustic enclosure and deployed in field tests with synthesized sounds and ground-based vehicles.

REFERENCES

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