Spread-Spectrum Techniques for Bio-Friendly Underwater Acoustic Communications

Spread-Spectrum Techniques for Bio-Friendly Underwater Acoustic Communications

This paper investigates techniques to mitigate the impact of acoustic communication signals on marine life, by minimizing source level and designing waveforms with characteristics proven to reduce animal discomfort in bioacoustics studies. High-ratio spread spectrum transmission is employed with ban...

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Bibliographic Details
Published in:IEEE access Vol. 6; pp. 4506 - 4520
Main Authors: Sherlock, Benjamin, Neasham, Jeffrey A., Tsimenidis, Charalampos C.
Format: Journal Article
Language:English
Published: Piscataway IEEE 01-01-2018
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects:
Acoustics
Bandpass filters
Bandwidth
Bandwidths
bio-friendly
Bioacoustics
Chirp
Discomfort
Frequency shift keying
low-power
low-received-SNR
M-OCK
Marine mammals
Pseudonoise
Receivers
Signal to noise ratio
Spread spectrum
Spread spectrum transmission
Synchronism
underwater acoustic modem
Underwater acoustics
Underwater communication
Waveforms
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Summary:This paper investigates techniques to mitigate the impact of acoustic communication signals on marine life, by minimizing source level and designing waveforms with characteristics proven to reduce animal discomfort in bioacoustics studies. High-ratio spread spectrum transmission is employed with bandwidth-time products exceeding 1000. Signaling is based on the families of near orthogonal pseudonoise waveforms, generated by bandpass filtering of binary M-sequences. This enables reception of data, at very low SNR, over a radius many times greater than the radius of discomfort experienced by marine mammals. Computationally efficient receivers with novel synchronization structures needed to be developed to operate at very low SNR and with severe Doppler effects. Simulations show the proposed scheme is able to achieve 45 bit/s at -18-dB SNR and 140 bit/s at -12-dB SNR. Experimental system performance was assessed during realistic experiments in the North Sea, verifying performance over ranges up to 10 km with transmitted SL of <;170 dB re 1 μPa at 1 m and with Doppler effects induced by relative motion exceeding 2 m/s. Conclusion: The system developed compares favorably, in terms of SNR performance and channel utilization, with previously reported work aimed at covert communication but offers reduced transmitter/receiver complexity and discomfort to animals. This paper offers a way forward to more biofriendly acoustic modem devices for operation in regions with sensitive fauna and/or increasingly strict environmental controls.
ISSN:2169-3536
2169-3536
DOI:10.1109/ACCESS.2018.2790478