Resolving meso-scale seabed variability using reflection measurements from an autonomous underwater vehicle

Abstract: Seabed geoacoustic variability is driven by geological processes that occur over a wide spectrum of space-time scales. While the acoustics community has some understanding of horizontal fine-scale geoacoustic variability, less than O(10(0)) m, and large-scale variability, greater than O(10(3)) m, there is a paucity of data resolving the geoacoustic meso-scale O(10(0)-10(3)) m. Measurements of the meso-scale along an ostensibly "benign" portion of the outer shelf reveal three classes of variability. The first c… Show more

“…However, the level of the stacked peak is not expected to be a good measure of the individual correlation peaks, because it is known from experience that bottom reflections contain a significant component of random spatial variability. At lower frequencies below approximately 10 kHz, mesoscale spatial variations O(1 to 10 ) m as mentioned in [6] will have a significant effect. At higher frequencies, the causes of variability include smaller scale variations O(10 to 1) m, such as interface roughness and volume inhomogeneities [12], variations in the bulk sediment properties, and bottom dwelling biological organisms [13].…”

“…Sound is projected at the seabed and the reflected signals are received by the line array and processed to measure the reflected signal, which is then used to invert for the properties and layering within the seabed. Recently, the source and receiving array have been miniaturized and deployed on an autonomous underwater vehicle (AUV) [4]- [6]. Instead of a dedicated sound source, sources of opportunity, such as the self-noise of the tow ship, have been used in conjunction with a matched-field technique to achieve a model-based inversion of the sediment strata [7].…”

Seabed Characterization Using Acoustic Communication Signals on an Autonomous Underwater Vehicle With a Thin-Line Towed Array

“…However, the level of the stacked peak is not expected to be a good measure of the individual correlation peaks, because it is known from experience that bottom reflections contain a significant component of random spatial variability. At lower frequencies below approximately 10 kHz, mesoscale spatial variations O(1 to 10 ) m as mentioned in [6] will have a significant effect. At higher frequencies, the causes of variability include smaller scale variations O(10 to 1) m, such as interface roughness and volume inhomogeneities [12], variations in the bulk sediment properties, and bottom dwelling biological organisms [13].…”

“…Sound is projected at the seabed and the reflected signals are received by the line array and processed to measure the reflected signal, which is then used to invert for the properties and layering within the seabed. Recently, the source and receiving array have been miniaturized and deployed on an autonomous underwater vehicle (AUV) [4]- [6]. Instead of a dedicated sound source, sources of opportunity, such as the self-noise of the tow ship, have been used in conjunction with a matched-field technique to achieve a model-based inversion of the sediment strata [7].…”

Seabed Characterization Using Acoustic Communication Signals on an Autonomous Underwater Vehicle With a Thin-Line Towed Array

“…Some geoacoustic inversion methods employ long-range (km to tens of km) propagation from a single receiver 1,2 or from a vertical array. 3,4 Other techniques [5][6][7] use shorter ranges to isolate a single interaction with the seabed. These techniques generally use inverse methods to estimate the geoacoustic properties.…”

Seafloor sound-speed profile and interface dip angle characterization by the image source method

“…2,4 The array is 30 m long with 26 receivers spaced every 1.2 m. The first hydrophone is 10 m behind the source. Source and receivers are 20 m above the seafloor (Fig.…”

Layer filtering for seafloor scatterers imaging