Probabilistic model-error assessment of deep learning proxies: an application to real-time inversion of borehole electromagnetic measurements

Rammay, Muzammil Hussain; Alyaev, Sergey; Elsheikh, Ahmed H.

doi:10.1093/gji/ggac147

Cited by 10 publications

(7 citation statements)

References 24 publications

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“…The future work is to integrate the DA developed in this paper with the decision framework developed in [8], allowing DSS under a much more complex geological setting. Furthermore, the method can be extended to account for model errors present in machine learning approximations in real-time [13].…”

Section: Discussionmentioning

confidence: 99%

“…The proposal is sampled from the proposal distribution q ( m * | m). The move is performed with probability b ( m, m * ) = min (1, r ( m, m * )) (13) where the Hastings ratio is defined as…”

Section: Mcmcmentioning

confidence: 99%

“…The forward deep neural network (FDNN) trained on synthetic data for extra-deep electromagnetic measurements [10] enabled the real-time ensemble-based update of layered models in 1.5D [11], and 3D [12]. Moreover, [13] showed that the model errors present in the FDNN approximation can be alleviated during the ensemble based inversion for the layered case.…”

Section: Introductionmentioning

confidence: 99%

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Verification of a real-time ensemble-based method for updating earth model based on GAN

Fossum¹,

Alyaev²,

Tveranger³

et al. 2022

Preprint

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The complexity of geomodelling workflows is a limiting factor for quantifying and updating uncertainty in real-time during drilling. We propose Generative Adversarial Networks (GANs) for parametrization and generation of geomodels, combined with Ensemble Randomized Maximum Likelihood (EnRML) for rapid updating of subsurface uncertainty. This real-time ensemble method combined with a highly non-linear model arising from neural-network modeling sequences might produce inaccurate and/or biased posterior solutions. This paper illustrates the predictive ability of EnRML on several examples where we assimilate local extra-deep electromagnetic logs. Statistical verification with MCMC confirms that the proposed workflow can produce reliable results required for geosteering wells.

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Section: Discussionmentioning

confidence: 99%

Section: Mcmcmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Verification of a real-time ensemble-based method for updating earth model based on GAN

Fossum¹,

Alyaev²,

Tveranger³

et al. 2022

Preprint

Self Cite

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“…Real-time DL inversion techniques also have the potential to perform statistical or probabilistic inversion processes (Alyaev et al, 2021). Real-time DL probabilistic inversion greatly improves the practicability of data-driven forward modeling in practical applications (Rammay et al, 2022). In addition, DL inversion methods also have great application potential in geophysical monitoring (Puzyrev, 2019).…”

Section: Application Scenariosmentioning

confidence: 99%

Electromagnetic imaging and deep learning for transition to renewable energies: a technology review

Castillo-Reyes,

Hu,

Wang

et al. 2023

Front. Earth Sci.

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Electromagnetic imaging is a technique that has been employed and perfected to investigate the Earth subsurface over the past three decades. Besides the traditional geophysical surveys (e.g., hydrocarbon exploration, geological mapping), several new applications have appeared (e.g., characterization of geothermal energy reservoirs, capture and storage of carbon dioxide, water prospecting, and monitoring of hazardous-waste deposits). The development of new numerical schemes, algorithms, and easy access to supercomputers have supported innovation throughout the geo-electromagnetic community. In particular, deep learning solutions have taken electromagnetic imaging technology to a different level. These emerging deep learning tools have significantly contributed to data processing for enhanced electromagnetic imaging of the Earth. Herein, we review innovative electromagnetic imaging technologies and deep learning solutions and their role in better understanding useful resources for the energy transition path. To better understand this landscape, we describe the physics behind electromagnetic imaging, current trends in its numerical modeling, development of computational tools (traditional approaches and emerging deep learning schemes), and discuss some key applications for the energy transition. We focus on the need to explore all the alternatives of technologies and expertise transfer to propel the energy landscape forward. We hope this review may be useful for the entire geo-electromagnetic community and inspire and drive the further development of innovative electromagnetic imaging technologies to power a safer future based on energy sources.

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“…Some traditional methods to solve inverse problems include gradient-based and statistics-based approaches (Malinverno & T orres-Verd ín 2000 ;T arantola 2005 ;W atzenig 2007 ;Ijasana et al 2013 ;Pardo & Torres-Verd ín 2014 ;Jahani et al 2022 ). Artificial intelligence (AI) algorithms, particularly deep learning (DL), have recently become popular to solve inverse problems (Jin et al 2019b ;Puzyrev 2019 ;Shahriari et al 2020c , b ;Moghadas 2020 ;Hu et al 2020 ;Rammay et al 2022 ). In this work, we use a deep neural network (DNN) to approximate the solution of an inverse problem.…”

mentioning

confidence: 99%

Neural network architecture optimization using automated machine learning for borehole resistivity measurements

Shahriari

Pardo

Kargaran

et al. 2023

Geophysical Journal International

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Summary Deep neural networks (DNNs) offer a real-time solution for the inversion of borehole resistivity measurements to approximate forward and inverse operators. Using extremely large DNNs to approximate the operators is possible, but it demands considerable training time. Moreover, evaluating the network after training also requires a significant amount of memory and processing power. In addition, we may overfit the model. In this work, we propose a scoring function that accounts for the accuracy and size of the DNNs compared to a reference DNNs that provides good approximations for the operators. Using this scoring function, we use DNN architecture search algorithms to obtain a quasi-optimal DNN smaller than the reference network; hence, it requires less computational effort during training and evaluation. The quasi-optimal DNN delivers comparable accuracy to the original large DNN.

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Probabilistic model-error assessment of deep learning proxies: an application to real-time inversion of borehole electromagnetic measurements

Cited by 10 publications

References 24 publications

Verification of a real-time ensemble-based method for updating earth model based on GAN

Verification of a real-time ensemble-based method for updating earth model based on GAN

Electromagnetic imaging and deep learning for transition to renewable energies: a technology review

Neural network architecture optimization using automated machine learning for borehole resistivity measurements

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