Limitations in wavelet analysis of non-stationary atmospheric gravity wave signatures in temperature profiles

IF 3.2 3区 地球科学 Q2 METEOROLOGY & ATMOSPHERIC SCIENCES
Robert Reichert, Natalie Kaifler, Bernd Kaifler
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Abstract

Abstract. Continuous wavelet transform (CWT) is a commonly used mathematical tool when it comes to the time–frequency (or distance–wavenumber) analysis of non-stationary signals that is used in a variety of research areas. In this work, we use the CWT to investigate signatures of atmospheric internal gravity waves (GWs) as observed in vertical temperature profiles obtained, for instance, by lidar. The focus is laid on the determination of vertical wavelengths of dominant GWs. According to linear GW theory, these wavelengths are a function of horizontal wind speed, and hence, vertical wind shear causes shifts in the evolution of the vertical wavelength. The resulting signal fulfills the criteria of a chirp. Using complex Morlet wavelets, we apply CWT to test mountain wave signals modeling wind shear of up to 5m s-1km-1 and investigate the capabilities and limitations. We find that the sensitivity of the CWT decreases for large chirp rates, i.e., strong wind shear. For a fourth-order Morlet wavelet, edge effects become dominant at a vertical wind shear of 3.4m s-1km-1. For higher-order wavelets, edge effects dominate at even smaller values. In addition, we investigate the effect of GW amplitudes growing exponentially with altitude on the determination of vertical wavelengths. It becomes evident that in the case of conservative amplitude growth, spectral leakage leads to artificially enhanced spectral power at lower altitudes. Therefore, we recommend normalizing the GW signal before the wavelet analysis and before the determination of vertical wavelengths. Finally, the cascading of receiver channels, which is typical of middle-atmosphere lidar measurements, results in an exponential sawtooth-like pattern of measurement uncertainties as a function of altitude. With the help of Monte Carlo simulations, we compute a wavelet noise spectrum and determine significance levels, which enable the reliable determination of vertical wavelengths. Finally, the insights obtained from the analysis of artificial chirps are used to analyze and interpret real GW measurements from the Compact Rayleigh Autonomous Lidar in April 2018 in Río Grande, Argentina. Comparison of commonly used analyses and our suggested wavelet analysis demonstrate improvements in the accuracy of determined wavelengths. For future analyses, we suggest the usage of a fourth-order Morlet wavelet, normalization of GW amplitudes before wavelet analysis, and computation of the significance level based on measurement uncertainties.
对温度剖面中的非稳态大气重力波特征进行小波分析的局限性
摘要连续小波变换(CWT)是对非稳态信号进行时频(或距离-波数)分析的常用数学工具,被广泛应用于多个研究领域。在这项工作中,我们使用 CWT 来研究通过激光雷达等获取的垂直温度剖面中观测到的大气内部重力波(GWs)的特征。重点是确定主要重力波的垂直波长。根据线性 GW 理论,这些波长是水平风速的函数,因此垂直风切变会导致垂直波长的变化。由此产生的信号符合啁啾信号的标准。我们使用复杂的 Morlet 小波,将 CWT 应用于测试山波信号,模拟高达 5m s-1km-1 的风切变,并研究其能力和局限性。我们发现,CWT 的灵敏度在大啁啾率(即强风切变)情况下会降低。对于四阶莫列特小波,当垂直风切变为 3.4m s-1km-1 时,边缘效应成为主导。对于更高阶的小波,边缘效应在更小值时也占主导地位。此外,我们还研究了全球风速振幅随高度呈指数增长对确定垂直波长的影响。很明显,在振幅保守增长的情况下,频谱泄漏会导致低海拔地区的频谱功率被人为增强。因此,我们建议在进行小波分析和确定垂直波长之前,对全球大气监测信号进行归一化处理。最后,中间大气层激光雷达测量中典型的接收通道级联会导致测量不确定性随高度呈指数锯齿状分布。在蒙特卡罗模拟的帮助下,我们计算了小波噪声频谱并确定了显著性水平,从而能够可靠地确定垂直波长。最后,通过分析人工啁啾声获得的见解被用于分析和解释 2018 年 4 月在阿根廷里奥格兰德使用紧凑型雷利自主激光雷达进行的真实全球变暖测量。对常用分析方法和我们建议的小波分析方法进行比较后发现,确定波长的准确性有所提高。对于未来的分析,我们建议使用四阶 Morlet 小波,在进行小波分析之前对全球瓦振幅进行归一化处理,并根据测量的不确定性计算显著性水平。
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来源期刊
Atmospheric Measurement Techniques
Atmospheric Measurement Techniques METEOROLOGY & ATMOSPHERIC SCIENCES-
CiteScore
7.10
自引率
18.40%
发文量
331
审稿时长
3 months
期刊介绍: Atmospheric Measurement Techniques (AMT) is an international scientific journal dedicated to the publication and discussion of advances in remote sensing, in-situ and laboratory measurement techniques for the constituents and properties of the Earth’s atmosphere. The main subject areas comprise the development, intercomparison and validation of measurement instruments and techniques of data processing and information retrieval for gases, aerosols, and clouds. The manuscript types considered for peer-reviewed publication are research articles, review articles, and commentaries.
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