When linear inversion fails: Neural-network optimization for sparse-ray travel-time tomography of a volcanic edifice

Abolfazl Komeazi , Georg Rümpker , Johannes Faber , Fabian Limberger , Nishtha Srivastava
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Abstract

In this study, we present an artificial neural network (ANN)-based approach for travel-time tomography of a volcanic edifice under sparse-ray coverage. We employ ray tracing to simulate the propagation of seismic waves through the heterogeneous medium of a volcanic edifice, and an inverse modeling algorithm that uses an ANN to estimate the velocity structure from the “observed” travel-time data. The performance of the approach is evaluated through a 2-dimensional numerical study that simulates i) an active source seismic experiment with a few (explosive) sources placed on one side of the edifice and a dense line of receivers placed on the other side, and ii) earthquakes located inside the edifice with receivers placed on both sides of the edifice. The results are compared with those obtained from conventional damped linear inversion. The average Root Mean Square Error (RMSE) between the input and output models is approximately 0.03 km/s for the ANN inversions, whereas it is about 0.4 km/s for the linear inversions, demonstrating that the ANN-based approach outperforms the classical approach, particularly in situations with sparse ray coverage. Our study emphasizes the advantages of employing a relatively simple ANN architecture in conjunction with second-order optimizers to minimize the loss function. Compared to using first-order optimizers, our ANN architecture shows a ∼25% reduction in RMSE. The ANN-based approach is computationally efficient. We observed that even though the ANN is trained based on completely random velocity models, it is still capable of resolving previously unseen anomalous structures within the edifice with about 5% anomalous discrepancies, making it a potentially valuable tool for the detection of low velocity anomalies related to magmatic intrusions or mush.

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当线性反演失败时火山大厦稀疏射线旅行时间断层成像的神经网络优化
在本研究中,我们提出了一种基于人工神经网络(ANN)的方法,用于在稀疏射线覆盖下对火山建筑物进行走时层析成像。我们采用射线追踪来模拟地震波在火山大厦异质介质中的传播,并采用逆建模算法,利用人工神经网络从 "观测到的 "走时数据中估计速度结构。通过一项二维数值研究对该方法的性能进行了评估,该研究模拟了 i) 在火山口一侧放置几个(爆炸)震源,在另一侧放置密集的接收器的主动源地震实验,以及 ii) 位于火山口内部,在火山口两侧放置接收器的地震实验。结果与传统的阻尼线性反演结果进行了比较。输入和输出模型之间的平均均方根误差(RMSE)在 ANN 反演中约为 0.03 km/s,而线性反演中约为 0.4 km/s,这表明基于 ANN 的方法优于传统方法,特别是在射线覆盖稀疏的情况下。我们的研究强调了采用相对简单的 ANN 架构和二阶优化器来最小化损失函数的优势。与使用一阶优化器相比,我们的 ANN 架构可将 RMSE 降低 25%。基于 ANN 的方法计算效率很高。我们观察到,即使是基于完全随机的速度模型训练的方差网络,它仍然能够以大约5%的异常差异解决先前未发现的建筑物内的异常结构,这使它成为检测与岩浆侵入或蘑菇相关的低速异常的一个有潜在价值的工具。
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