Towards a robust parameterization for conditioning facies models using deep variational autoencoders and ensemble smoother

Canchumuni, Smith W. Arauco; Emerick, Alexandre A.; Pacheco, Marco Aurélio Cavalcanti

doi:10.1016/j.cageo.2019.04.006

Cited by 117 publications

(74 citation statements)

References 68 publications

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“…Usually the negative expected log-likelihood (e.g., the crossentropy function) is used ( [30], [31], [33]- [35]) but the mean squared error [32] can also be used. The second term L KL (equ.…”

Section: Variational Autoencodersmentioning

confidence: 99%

“…Most of the generative applications deal with image processing as in [33] where a VAE was trained to generate face images with much clearer and more natural noses, eyes, teeth, hair textures as well as reasonable backgrounds. In [30], a generative model is constructed to create new random realizations of faces that are indistinguishable from samples.…”

Section: Variational Autoencodersmentioning

confidence: 99%

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Deep Convolutional Variational Autoencoder as a 2D-Visualization Tool for Partial Discharge Source Classification in Hydrogenerators

et al. 2020

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Hydrogenerators are strategic assets for power utilities. Their reliability and availability can lead to significant benefits. For decades, monitoring and diagnosis of hydrogenerators have been at the core of maintenance strategies. A significant part of generator diagnosis relies on Partial Discharge (PD) measurements, because the main cause of hydrogenerator breakdown comes from failure of its high voltage stator, which is a major component of hydrogenerators. A study of all stator failure mechanisms reveals that more than 85 % of them involve the presence of PD activity. PD signal can be detected from the lead of the hydrogenerator while it is running, thus allowing for on-line diagnosis. Hydro-Québec has been collecting more than 33 000 unlabeled PD measurement files over the last decades. Up to now, this diagnostic technique has been quantified based on global PD amplitudes and integrated PD energy irrespective of the source of the PD signal. Several PD sources exist and they all have different relative risk, but in order to recognize the nature of the PD, or its source, the judgement of experts is required. In this paper, we propose a new method based on visual data analysis to build a PD source classifier with a minimum of labeled data. A convolutional variational autoencoder has been used to help experts to visually select the best training data set in order to improve the performances of the PD source classifier.

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Section: Variational Autoencodersmentioning

confidence: 99%

Section: Variational Autoencodersmentioning

confidence: 99%

Deep Convolutional Variational Autoencoder as a 2D-Visualization Tool for Partial Discharge Source Classification in Hydrogenerators

et al. 2020

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“…Tools based on deep-learning have been shown to be applicable for such geological parameterizations. Specific approaches include those based on variational autoencoders (VAEs) [18,19] and generative adversarial networks (GANs) [20,21,22,23,24,25,26,27]. Algorithms based on a combination of VAE and GAN have also been devised [7].…”

Section: Introductionmentioning

confidence: 99%

A deep-learning-based surrogate model for data assimilation in dynamic subsurface flow problems

Tang

Liu

Durlofsky

2020

Journal of Computational Physics

202

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A deep-learning-based surrogate model is developed and applied for predicting dynamic subsurface flow in channelized geological models. The surrogate model is based on deep convolutional and recurrent neural network architectures, specifically a residual U-Net and a convolutional long short term memory recurrent network. Training samples entail global pressure and saturation maps, at a series of time steps, generated by simulating oil-water flow in many (1500 in our case) realizations of a 2D channelized system. After training, the 'recurrent R-U-Net' surrogate model is shown to be capable of accurately predicting dynamic pressure and saturation maps and well rates (e.g., time-varying oil and water rates at production wells) for new geological realizations. Assessments demonstrating high surrogatemodel accuracy are presented for an individual geological realization and for an ensemble of 500 test geomodels. The surrogate model is then used for the challenging problem of data assimilation (history matching) in a channelized system. For this study, posterior reservoir models are generated using the randomized maximum likelihood method, with the permeability field represented using the recently developed CNN-PCA parameterization. The flow responses required during the data assimilation procedure are provided by the recurrent R-U-Net. The overall approach is shown to lead to substantial reduction in prediction uncertainty. High-fidelity numerical simulation results for the posterior geomodels (generated by the surrogate-based data assimilation procedure) are shown to be in essential agreement with the recurrent R-U-Net predictions. The accuracy and dramatic speedup provided by 1 arXiv:1908.05823v1 [cs.LG] 16 Aug 2019 the surrogate model suggest that it may eventually enable the application of more formal posterior sampling methods in realistic problems. our case), this surrogate model can provide flow predictions in close agreement with the underlying flow simulator, but with a significant reduction in computational cost. Thus this approach enables the application of accurate but computationally demanding inverse modeling procedures.There has been extensive research on constructing surrogate models for subsurface flow prediction. These can be generally classified, based on the mathematical formulation, into physics-based and data-driven procedures (though these categories are not mutually exclusive). The physics-based methods typically neglect or simplify physical or numerical aspects of the problem, through, for example, reduced-physics modeling, coarse-grid modeling, or proper orthogonal decomposition (POD) based reduced-order modeling (ROM). A variety of POD-based ROMs, in which the state variables and the system of equations are projected into low-dimensional space and then solved, have been applied for a range of subsurface flow problems [1, 2, 3, 4, 5]. These ROMs can be effective, although they are generally only accurate when new (test) runs are sufficiently 'close' to training runs. In addition, the applicat...

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“…Deep generative models (DGMs) are part of the deep models family and are a powerful way to learn any distribution of observed data through unsupervised learning. The DGMs are composed mainly by variational autoencoders (VAEs) [1][2][3][4], and generative adversarial networks (GANs) [5]. The VAEs are mainly used to extract features from the input vector in an unsupervised way while the GANs are used to generate synthetic samples through an adversarial learning by achieving an equilibrium between a Generator and a Discriminator.…”

Section: Introductionmentioning

confidence: 99%

“…The VAEs have met with great success in recent years in several applicative areas including anomaly detection [6][7][8][9], text classification [10], sentence generation [11], speech synthesis and recognition [12][13][14], spatio-temporal solar irradiance forecasting [15] and in geoscience for data assimilation [2]. In other respects, the two major application areas of the VAEs are the biomedical and healthcare recommendation [16][17][18][19], and industrial applications for nonlinear processes monitoring [1,3,4,[20][21][22][23][24][25].…”

Section: Introductionmentioning

confidence: 99%

Semi-Supervised Adversarial Variational Autoencoder

Zemouri

2020

MAKE

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We present a method to improve the reconstruction and generation performance of a variational autoencoder (VAE) by injecting an adversarial learning. Instead of comparing the reconstructed with the original data to calculate the reconstruction loss, we use a consistency principle for deep features. The main contributions are threefold. Firstly, our approach perfectly combines the two models, i.e., GAN and VAE, and thus improves the generation and reconstruction performance of the VAE. Secondly, the VAE training is done in two steps, which allows to dissociate the constraints used for the construction of the latent space on the one hand, and those used for the training of the decoder. By using this two-step learning process, our method can be more widely used in applications other than image processing. While training the encoder, the label information is integrated to better structure the latent space in a supervised way. The third contribution is to use the trained encoder for the consistency principle for deep features extracted from the hidden layers. We present experimental results to show that our method gives better performance than the original VAE. The results demonstrate that the adversarial constraints allow the decoder to generate images that are more authentic and realistic than the conventional VAE.

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Towards a robust parameterization for conditioning facies models using deep variational autoencoders and ensemble smoother

Cited by 117 publications

References 68 publications

Deep Convolutional Variational Autoencoder as a 2D-Visualization Tool for Partial Discharge Source Classification in Hydrogenerators

Deep Convolutional Variational Autoencoder as a 2D-Visualization Tool for Partial Discharge Source Classification in Hydrogenerators

A deep-learning-based surrogate model for data assimilation in dynamic subsurface flow problems

Semi-Supervised Adversarial Variational Autoencoder

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