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Acoustic Arrival Predictions Using Oceanographic Measurements And Models In The Beaufort Sea.

Home
Acoustic Arrival Predictions Using Oceanographic Measurements And Models In The Beaufort Sea.

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Acoustic arrival predictions using oceanographic measurements and models in the Beaufort Sea.

Jessica B Desrochers^1,2, Lora J Van Uffelen¹, Sarah E Webster³

¹Ocean Engineering, University of Rhode Island, Kingston, Rhode Island 02881, USA.

JASA Express Letters

|March 25, 2024

View abstract on PubMed

Summary

This summary is machine-generated.

Accurate acoustic propagation models in the Arctic Beaufort Sea require in situ data. Seaglider data revealed discrepancies in the Beaufort duct

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Area of Science:

Oceanography
Acoustics
Arctic Research

Background:

Acoustic propagation in the Beaufort Sea is highly sensitive to upper-ocean sound-speed profiles.
A significant feature is the presence of a subsurface duct, known as the Beaufort duct.

Purpose of the Study:

To compare acoustic predictions from existing Arctic models with those derived from in situ Seaglider data.
To assess the impact of data discrepancies on acoustic propagation predictions.

Main Methods:

Utilized Seaglider autonomous underwater vehicles to collect in situ oceanographic data in the Beaufort Sea during summer 2017.
Performed acoustic propagation modeling using both established Arctic models and the collected in situ data.

Main Results:

Observed notable differences between model predictions and in situ data regarding the Beaufort duct's strength, depth, and quantity.
These discrepancies significantly influence the simulation of reverse geometric dispersion in acoustic signals.

Conclusions:

In situ data are crucial for accurately characterizing the Beaufort duct and improving acoustic propagation models in the Arctic.
Existing Arctic acoustic models may require refinement to incorporate real-world oceanographic conditions for precise predictions.