Warren L. J. Fox scite author profile

This paper presents preliminary results of a recent study whose overall objectives are to determine the mechanisms contributing significantly to subcritical acoustic penetration into ocean sediments, and to quantify the results for use in sonar performance prediction for the detection of buried objects. In situ acoustic measurements were performed on a sandy bottom whose geoacoustical and geomorphological properties were also measured. A parametric array mounted on a tower moving on a rail was used to insonify hydrophones located above and below the sediment interface. Data covering grazing angles both above and below the nominal critical angle and in the frequency range 2-15 kHz were acquired and processed. The results are compared to two models that account for scattering of sound at the rough water-sediment interface into the sediment. Although all possible mechanisms for subcritical penetration are not modeled, the levels predicted by both models are consistent with the levels observed in the experimental data. For the specific seafloor and experimental conditions examined, the analysis suggests that for frequencies below 5-7 kHz sound penetration into the sediment at subcritical insonification is dominated by the evanescent field, while scattering due to surface roughness is the dominant mechanism at higher frequencies.

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System Design Considerations for Undersea Networks: Link and Multiple Access Protocols

Parrish

Tracy

Roy

et al. 2008

IEEE J. Select. Areas Commun.

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Abstract-We address several inter-related aspects of underwater network design within the context of a cross-layer approach. We first highlight the impact of key characteristics of the acoustic propagation medium on the choice of link layer parameters; in turn, the consequences of these choices on design of a suitable MAC protocol and its performance are investigated.Specifically, the paper makes contributions on the following fronts: a) Based on accepted acoustic channel models, the pointto-point (link) capacity is numerically calculated, quantifying sensitivities to factors such as the sound speed profile, power spectral density of the (colored) additive background noise and the impact of boundary (surface) conditions for the acoustic channel; b) It provides an analysis of the Micromodem-like linklayer based on FH-FSK modulation; and finally c) it undertakes performance evaluation of a simple MAC protocol based on ALOHA with Random Backoff, that is shown to be particularly suitable for small underwater networks.

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Characterization of the two-dimensional roughness of wave-rippled sea floors using digital photogrammetry

Lyons

Fox

Hasiotis

et al. 2002

IEEE J. Oceanic Eng.

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Warren L. J. Fox

Underwater acoustic communication by passive-phase conjugation: theory and experimental results

Multichannel Equalization by Decision-Directed Passive Phase Conjugation: Experimental Results

Mechanisms for subcritical penetration into a sandy bottom: Experimental and modeling results

System Design Considerations for Undersea Networks: Link and Multiple Access Protocols

Characterization of the two-dimensional roughness of wave-rippled sea floors using digital photogrammetry

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