Coupled Time‐Lapse Full‐Waveform Inversion for Subsurface Flow Problems Using Intrusive Automatic Differentiation

Li, Dongzhuo; Xu, Kailai; Harris, Jerry M.; Darve, Eric

doi:10.1029/2019wr027032

Cited by 46 publications

(20 citation statements)

References 60 publications

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“…Finally, we show that we can easily build a framework for seismic monitoring of geological carbon storage that integrates PDE solvers, deep learning models and physical constraints. These monitoring problems rely on three different types of physics [40]: fluid-flow physics, rock physics and wave physics. Given time-lapse seismic data collected over multiple years, we jointly invert for the rocks intrinsic permeability which can be used to recover the CO 2 concentration.…”

Section: End-to-end Inversion For Geological Carbon Storage Monitoringmentioning

confidence: 99%

Accelerating innovation with software abstractions for scalable computational geophysics

Louboutin¹,

Witte²,

Siahkoohi³

et al. 2022

Preprint

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We present the SLIM open-source software framework for computational geophysics, and more generally, inverse problems based on the wave-equation (e.g., medical ultrasound). We developed a software environment aimed at scalable research and development by designing multiple layers of abstractions. This environment allows the researchers to easily formulate their problem in an abstract fashion, while still being able to exploit the latest developments in high-performance computing. We illustrate and demonstrate the benefits of our software design on many geophysical applications, including seismic inversion and physics-informed machine learning for geophysics(e.g., loop unrolled imaging, uncertainty quantification), all while facilitating the integration of external software.

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Section: End-to-end Inversion For Geological Carbon Storage Monitoringmentioning

confidence: 99%

Accelerating innovation with software abstractions for scalable computational geophysics

Louboutin¹,

Witte²,

Siahkoohi³

et al. 2022

Preprint

View full text Add to dashboard Cite

show abstract

“…We excited waves from each source and recorded travel time at the receiver array, which constituted the observed data. We solved the eikonal equation using the fast sweeping method [63] and computed the gradient using the discrete adjoint-state method [33].…”

Section: Eikonal Tomographymentioning

confidence: 99%

Differentiable Gaussianization Layers for Inverse Problems Regularized by Deep Generative Models

Li¹

2021

Preprint

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Generative networks such as normalizing flows can serve as a learning-based prior to augment inverse problems to achieve high-quality results. However, the latent space vector may not remain a typical sample from the desired high-dimensional standard Gaussian distribution when traversing the latent space during an inversion. As a result, it can be challenging to attain a high-fidelity solution, particularly in the presence of noise and inaccurate physics-based models. To address this issue, we propose to re-parameterize and Gaussianize the latent vector using novel differentiable data-dependent layers wherein custom operators are defined by solving optimization problems. These proposed layers enforce an inversion to find a feasible solution within a Gaussian typical set of the latent space. We tested and validated our technique on an image deblurring task and eikonal tomography -a PDE-constrained inverse problem and achieved high-fidelity results.

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“…Given physical properties of the two fluids (brine and supercritical CO 2 ) and the spatial porosity and permeability distributions, these fluid-flow equations are capable of predicting CO 2 concentration snapshots during and after CO 2 injection. By coupling these fluid-flow equations, via a rock physics model (the patchy saturation model [Avseth et al, 2010]), to the wave equation, Li et al [2020a] proposed an end-to-end inversion framework where time-lapse seismic surveys are jointly inverted to yield estimates for the spatial permeability distribution. Compared to the sequential inversion [Hatab and MacBeth, 2021b,a] and history matching workflows [Oliver et al, 2021], estimates of the CO 2 concentration in the coupled inversion are regularized by fluid-flow physics.…”

Section: Introductionmentioning

confidence: 99%

“…Compared to the sequential inversion [Hatab and MacBeth, 2021b,a] and history matching workflows [Oliver et al, 2021], estimates of the CO 2 concentration in the coupled inversion are regularized by fluid-flow physics. Because coupled inversion [Li et al, 2020a] makes use of the fluid-flow equations, it offers a framework capable of producing direct estimates for the permeability. The latter can be used to generate improved predictions for the behavior of CO 2 plumes.…”

Section: Introductionmentioning

confidence: 99%

“…The latter can be used to generate improved predictions for the behavior of CO 2 plumes. Despite the initially promising results by Li et al [2020a] on synthetic experiments, the downside of their proposed coupled framework is the increased complexity that comes with including partial differential equations (PDEs) for the fluid-flow as constraints. Aside from the need to compute sensitivities of solutions of the fluid-flow equations, solving these PDE can be computationally expensive [Settgast et al, 2018, Rasmussen et al, 2021.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Learned coupled inversion for carbon sequestration monitoring and forecasting with Fourier neural operators

Yin¹,

Siahkoohi²,

Louboutin³

et al. 2022

Preprint

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Seismic monitoring of carbon storage sequestration is a challenging problem involving both fluid-flow physics and wave physics. Additionally, monitoring usually requires the solvers for these physics to be coupled and differentiable to effectively invert for the subsurface properties of interest. To drastically reduce the computational cost, we introduce a learned coupled inversion framework based on the wave modeling operator, rock property conversion and a proxy fluid-flow simulator. We show that we can accurately use a Fourier neural operator as a proxy for the fluid-flow simulator for a fraction of the computational cost. We demonstrate the efficacy of our proposed method by means of a synthetic experiment. Finally, our framework is extended to carbon sequestration forecasting, where we effectively use the surrogate Fourier neural operator to forecast the CO 2 plume in the future at near-zero additional cost.

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Coupled Time‐Lapse Full‐Waveform Inversion for Subsurface Flow Problems Using Intrusive Automatic Differentiation

Cited by 46 publications

References 60 publications

Accelerating innovation with software abstractions for scalable computational geophysics

Accelerating innovation with software abstractions for scalable computational geophysics

Differentiable Gaussianization Layers for Inverse Problems Regularized by Deep Generative Models

Learned coupled inversion for carbon sequestration monitoring and forecasting with Fourier neural operators

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