Deep-Learning Based Causal Inference: A Feasibility Study Based on Three Years of Tectonic-Climate Data From Moxa Geodynamic Observatory

IF 2.9 3区 地球科学 Q2 ASTRONOMY & ASTROPHYSICS Earth and Space Science Pub Date : 2024-10-25 DOI:10.1029/2023EA003430
Wasim Ahmad, Valentin Kasburg, Nina Kukowski, Maha Shadaydeh, Joachim Denzler
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Abstract

Highly sensitive laser strainmeters at Moxa Geodynamic Observatory (MGO) measure motions of the upper Earth's crust. Since the mountain overburden of the laser strainmeters installed in the gallery of the observatory is relatively low, the recorded time series are strongly influenced by local meteorological phenomena. To estimate the nonlinear effect of the meteorological variables on strain measurements in a non-stationary environment, advanced methods capable of learning the nonlinearity and discovering causal relationships in the non-stationary multivariate tectonic-climate time series are needed. Methods for causal inference generally perform well in identifying linear causal relationships but often struggle to retrieve complex nonlinear causal structures prevalent in real-world systems. This work presents a novel model invariance-based causal discovery (CDMI) method that utilizes deep networks to model nonlinearity in a multivariate time series system. We propose to use the theoretically well-established Knockoffs framework to generate in-distribution, uncorrelated copies of the original data as interventional variables and test the model invariance for causal discovery. To deal with the non-stationary behavior of the tectonic-climate time series recorded at the MGO, we propose a regime identification approach that we apply before causal analysis to generate segments of time series that possess locally consistent statistical properties. First, we evaluate our method on synthetically generated time series by comparing it to other causal analysis methods. We then investigate the hypothesized effect of meteorological variables on strain measurements. Our approach outperforms other causality methods and provides meaningful insights into tectonic-climate causal interactions.

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基于深度学习的因果推理:基于莫萨地球动力观测站三年构造-气候数据的可行性研究
莫萨地球动力观测站(MGO)的高灵敏度激光应变计测量地壳上部的运动。由于安装在观测站走廊上的激光应变计的山体覆盖层相对较低,记录的时间序列受当地气象现象的影响很大。为了估计气象变量在非稳态环境下对应变测量的非线性影响,需要采用先进的方法来学习非线性,并发现非稳态多变量构造-气候时间序列中的因果关系。因果推理方法通常在识别线性因果关系方面表现出色,但在检索现实世界系统中普遍存在的复杂非线性因果结构方面往往力不从心。本研究提出了一种新颖的基于模型不变性的因果发现(CDMI)方法,该方法利用深度网络对多元时间序列系统中的非线性进行建模。我们建议使用理论上成熟的 Knockoffs 框架,生成原始数据的分布内、不相关副本作为干预变量,并测试模型不变性以发现因果关系。为了处理 MGO 记录的构造-气候时间序列的非平稳行为,我们提出了一种制度识别方法,并在因果分析之前应用该方法生成具有局部一致统计特性的时间序列片段。首先,我们在合成生成的时间序列上评估我们的方法,并将其与其他因果分析方法进行比较。然后,我们研究了气象变量对应变测量的假设影响。我们的方法优于其他因果分析方法,并为构造与气候之间的因果互动提供了有意义的见解。
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来源期刊
Earth and Space Science
Earth and Space Science Earth and Planetary Sciences-General Earth and Planetary Sciences
CiteScore
5.50
自引率
3.20%
发文量
285
审稿时长
19 weeks
期刊介绍: Marking AGU’s second new open access journal in the last 12 months, Earth and Space Science is the only journal that reflects the expansive range of science represented by AGU’s 62,000 members, including all of the Earth, planetary, and space sciences, and related fields in environmental science, geoengineering, space engineering, and biogeochemistry.
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