Proxy observations of surface wind from a globally distributed network of wave buoys

IF 1.9 4区 地球科学 Q2 ENGINEERING, OCEAN Journal of Atmospheric and Oceanic Technology Pub Date : 2023-11-03 DOI:10.1175/jtech-d-23-0044.1
Ciara Dorsay, Galen Egan, Isabel Houghton, Christie Hegermiller, Pieter B. Smit
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Abstract

Abstract In the equilibrium range of the wave spectrum’s high frequency tail, energy levels are proportional to the wind friction velocity. As a consequence of this intrinsic coupling, spectral tail energy levels can be used as proxy observations of surface stress and wind speed when direct observations are unavailable. Proxy observations from drifting wave-buoy networks can therefore augment existing remote sensing capabilities by providing long dwell observations of surface winds. Here we consider the skill of proxy wind estimates obtained from observations recorded by the globally distributed Sofar Spotter network (observations from 2021–2022) when compared with collocated observations derived from satellites (yielding over 20000 collocations) and reanalysis data. We consider physics motivated parameterizations (based on frequency −4 universal tail assumption), inverse modelling (estimate wind speed from spectral energy balance), and a data driven approach (artificial neural network) as potential methods. Evaluation of trained/calibrated models on unseen test-data reveals comparable performance across methods with generally order 1 m/s root-mean-square-difference with satellite observations.
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全球分布的波浪浮标网络对地面风的替代观测
在波谱高频尾的平衡范围内,能量水平与风的摩擦速度成正比。由于这种内在耦合,当无法直接观测时,谱尾能级可以用作地表应力和风速的替代观测值。因此,来自漂流波浪浮标网络的替代观测可以通过提供地面风的长时间观测来增强现有的遥感能力。在这里,我们考虑从全球分布的Sofar Spotter网络记录的观测数据(2021-2022年观测数据)中获得的代理风估计的技巧,并将其与来自卫星(产生超过20000个配位)和再分析数据的配位观测数据进行比较。我们考虑物理驱动的参数化(基于频率- 4通用尾假设)、逆建模(从频谱能量平衡估计风速)和数据驱动的方法(人工神经网络)作为潜在的方法。对未见过的测试数据进行训练/校准模型的评估显示,不同方法的性能相当,与卫星观测的均方根差通常为1阶/秒。
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来源期刊
CiteScore
4.50
自引率
9.10%
发文量
135
审稿时长
3 months
期刊介绍: The Journal of Atmospheric and Oceanic Technology (JTECH) publishes research describing instrumentation and methods used in atmospheric and oceanic research, including remote sensing instruments; measurements, validation, and data analysis techniques from satellites, aircraft, balloons, and surface-based platforms; in situ instruments, measurements, and methods for data acquisition, analysis, and interpretation and assimilation in numerical models; and information systems and algorithms.
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