Spatial and Temporal Variability in Bottom Roughness: Implications to High Frequency Subcritical Penetration and Backscatter
Abstract
Quantitative prediction of high frequency, low grazing angle penetration into, and scattering from, sand sediments requires knowledge of the roughness of the water/sand interface. Since the sediment roughness evolves due to hydrodynamic and biological processes, concurrent, co-located measurement of roughness and acoustic penetration/backscattering is essential for testing acoustic models or using such models to determine the likelihood of buried target detection. Here, we examine both roughness and acoustic measurements carried out during a month-long 1999 Sediment Acoustics experiment (SAX99). A ripple field was present throughout the experimental period but changed wavelength and orientation as a result of a storm event (i.e., the ripple field is temporally non-stationary). The predicted impact of this change in the ripple field on acoustic penetration at shallow grazing angles is presented. The small-scale roughness important for backscattering was measured at several locations near to, but not co-located with, acoustic backscattering measurements. These roughness measurements indicate changes with location. The effect of this spatial non-stationary on tests of alternative backscattering models is discussed. Finally, simple sonar equation predictions of high frequency, low grazing angle buried mine detection are carried out using various combinations of interface roughness conditions.
Document Details
- Document Type
- Technical Report
- Publication Date
- Sep 20, 2002
- Accession Number
- ADA410803
Entities
People
- Dajun Tang
- Darrell R. Jackson
- Eric I. Thorsos
- Kevin B. Briggs
- Kevin L. Williams
Organizations
- United States Naval Research Laboratory