计算机科学
外推法
水下
水准点(测量)
灵活性(工程)
人工神经网络
水声学
过程(计算)
高斯过程
数据建模
克里金
环境数据
数据挖掘
机器学习
高斯分布
数学
地质学
统计
法学
数学分析
物理
操作系统
海洋学
大地测量学
数据库
量子力学
政治学
作者
Kexin Li,Mandar Chitre
标识
DOI:10.1109/joe.2023.3292417
摘要
Acoustic propagation models are widely used in numerous oceanic and underwater applications.Most conventional models are approximate solutions of the acoustic wave equation, and require accurate environmental knowledge to be available beforehand.Environmental parameters may not always be easily or accurately measurable.While data-driven techniques might allow us to model acoustic propagation without the need for extensive prior environmental knowledge, such techniques tend to be data-hungry and often infeasible in oceanic applications where data collection is difficult and expensive.We propose a data-aided physics-based high-frequency acoustic propagation modeling approach that enables us to train models with only a small amount of data.The proposed framework is not only data-efficient, but also offers flexibility to incorporate varying degrees of environmental knowledge, and generalizes well to permit extrapolation beyond the area where data were collected.We demonstrate the feasibility and applicability of our method through four numerical case studies, and one controlled experiment.We also benchmark our method's performance against two classical data-driven techniques -Gaussian process regression and deep neural network.
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