Uncertainty Quantification in Seismic Inversion Through Integrated Importance Sampling and Ensemble Methods

Luping Qu, Mauricio Araya-Polo, Laurent Demanet
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Abstract

Seismic inversion is essential for geophysical exploration and geological assessment, but it is inherently subject to significant uncertainty. This uncertainty stems primarily from the limited information provided by observed seismic data, which is largely a result of constraints in data collection geometry. As a result, multiple plausible velocity models can often explain the same set of seismic observations. In deep learning-based seismic inversion, uncertainty arises from various sources, including data noise, neural network design and training, and inherent data limitations. This study introduces a novel approach to uncertainty quantification in seismic inversion by integrating ensemble methods with importance sampling. By leveraging ensemble approach in combination with importance sampling, we enhance the accuracy of uncertainty analysis while maintaining computational efficiency. The method involves initializing each model in the ensemble with different weights, introducing diversity in predictions and thereby improving the robustness and reliability of the inversion outcomes. Additionally, the use of importance sampling weights the contribution of each ensemble sample, allowing us to use a limited number of ensemble samples to obtain more accurate estimates of the posterior distribution. Our approach enables more precise quantification of uncertainty in velocity models derived from seismic data. By utilizing a limited number of ensemble samples, this method achieves an accurate and reliable assessment of uncertainty, ultimately providing greater confidence in seismic inversion results.
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通过综合重要度采样和集合方法量化地震反演中的不确定性
地震反演对于地球物理勘探和地质评估至关重要,但它本身存在很大的不确定性。这种不确定性主要源于观测到的地震数据所提供的信息有限,这在很大程度上是数据采集几何限制的结果。因此,多个可信的速度模型往往可以解释同一组地震观测数据。在基于深度学习的地震反演中,不确定性有多种来源,包括数据噪声、神经网络设计和训练以及固有数据限制。本研究通过将集合方法与重要性采样相结合,为地震反演中的不确定性量化引入了一种新方法。通过将集合方法与重要性采样相结合,我们在保持计算效率的同时提高了不确定性分析的准确性。该方法涉及以不同权重初始化集合中的每个模型,引入预测的多样性,从而提高反演结果的稳健性和可靠性。此外,使用输入采样对每个集合样本的贡献进行加权,使我们能够使用有限数量的集合样本来获得更精确的后向分布估计值。我们的方法能够更精确地量化地震数据速度模型的不确定性。通过利用有限数量的集合样本,该方法实现了对不确定性的准确可靠评估,最终为地震反演结果提供了更大的可信度。
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