A multiscale method for data assimilation

Moraes, Rafael J. de; Hajibeygi, Hadi

doi:10.1007/s10596-019-09839-2

Cited by 12 publications

(8 citation statements)

References 58 publications

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“…The Multi-Level method allows one to reduce the degrees of freedom while searching for the solution and yet stay robust. The use of Multi-Level and upscaling methods are introduced in Moraes et al [14] and in Echeverria et al [5], this thesis illustrates the robustness of upscaling in the design variable space. Further, this thesis demonstrates the use of inversion to find the reservoir characteristics.…”

Section: Discussionmentioning

confidence: 87%

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Multi-Level Inversion Based on Mesh Decoupling

Shachor¹

2021

Scientific Computing in Electrical Engineering

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Understanding the permeability of the subsurface is a crucial step to simulate fluid flow in the subsurface. A parameter estimation problem for the flow equations can be solved to find the permeability. The robust identification of material parameters remains a significant challenge. In classical approaches, the non-linear least-squares problem is formulated as a non-linear optimization problem in which the partial differential equation governing the permeability field acts as a constraint. These approaches lead to large scale problems and are, therefore, computationally challenging. This thesis proposes a new approach based on mesh decoupling of state and design variables. This approach allows treating the design variables on various scales of resolution without comprising the accuracy of the state and adjoint solver. The method is implemented on a one-dimensional and two-dimensional Poisson problem taken from the literature. The first numerical results show that the multilevel approach is able to accelerate the initial stages of the search procedure significantly. Without their guidance, supervision, insights, and help, I would not be able to do this work. I thank them for believing in me and willing to accept the challenge of combining pure mathematical research with petroleum engineering aspects to explore new ideas that can benefit both aspects of science. During the work, both have let me the flexibility to test my thoughts, some time to fail, all to be a better student and researcher for later stages. This approach has taught me a lot, and I thank them for that.I thank Dr. Ir. Femke Vossepoel for her interest in my work and for being a committee member for my thesis defense. During my studies, the courses and interactions with professor Vossepoel have encouraged me to find interest in geostatistics and different interpolation methods.I want to thank the TU Delft university staff for the different courses, classes, presentations, and fieldwork. All that prepared me to be a better scientific researcher, petroleum engineer, and a co-worker.Last but not least, I would like to thank my dear family and especially my dear mother for the constant support in the challenging times and for encouraging me to go abroad and pursue an MSc. v Contents List of Figures ix List of Tables xi 7 ConclusionBibliography

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Section: Discussionmentioning

confidence: 87%

“…Numerical Optimization and the Newton with Trust Region method are described at [4], [15]. Multi-Level appraoches help reduce computation and yet stay robust and similar ideas are introduced in [5], [14], [17]. The use of Julia and applications is described at [1], [6], [13] In chapter 1, an introduction to the topic is mentioned.…”

Section: Introductionmentioning

confidence: 99%

Multi-Level Inversion Based on Mesh Decoupling

Shachor¹

2021

Scientific Computing in Electrical Engineering

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“…We choose to construct them by spatial coarsening of the conventional simulation grid to several levels of coarseness, and correspondingly upscale the associated grid-based parameter functions. Multilevel Data Assimilation (MLDA) [8,14,15,22,23,32,35] utilizes multilevel models in the forecast step. Since inverted seismic data are given on the conventional grid (denoted the fine grid from now on), MLDA with such data must be able to handle differences in grid levels between data and model forecasts.…”

Section: Introductionmentioning

confidence: 99%

Iterative multilevel assimilation of inverted seismic data

et al. 2022

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In ensemble-based data assimilation (DA), the ensemble size is usually limited to around one hundred. Straightforward application of ensemble-based DA can therefore result in significant Monte Carlo errors, often manifesting themselves as severe underestimation of parameter uncertainties. Localization is the conventional remedy for this problem. Assimilation of large amounts of simultaneous data enhances the negative effects of Monte Carlo errors. Use of lower-fidelity models reduces the computational cost per ensemble member and therefore renders the possibility to reduce Monte Carlo errors by increasing the ensemble size, but it also adds to the modeling error. Multilevel data assimilation (MLDA) uses a selection of models forming hierarchies of both computational cost and computational accuracy, and tries to balance between Monte Carlo errors and modeling errors. In this work, we assess a recently developed MLDA algorithm, the Multilevel Hybrid Ensemble Smoother (MLHES), and introduce and assess an iterative version of this algorithm, the Iterative Multilevel Hybrid Ensemble Smoother (IMLHES). In our assessments, we compare these algorithms with conventional single-level DA algorithms with localization. To this end, a typical example of large amount of spatially distributed data, i.e. inverted seismic data, is considered and three data sets of this kind are assimilated in three different petroleum reservoir models. Qualitatively evaluating the DA outcomes, it is found that multilevel algorithms outperform their conventional single-level counterparts in obtaining the posterior statistics of both uncertain parameters and model forecasts. Additionally, it is observed that IMLHES performs better than MLHES in the same regard, and also successfully converges to the proximity of solution in a case where the considered iterative single-level algorithm did not converge to the global optimum.

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“…Development of the multiscale strategy is not only important for advancing the computational efficiency, as formerly addressed for linear mechanics but also crucial to allow for generating a consistent map between fine and coarse scale systems without any need of upscaled parameters. This can also allow for the connection of the coarse scale observation data directly to the fine-scale computational system, to reduce the uncertainty, as shown for flow in porous media 73 . For convenient integration within a given simulation framework, the developed multiscale strategy is also formulated and implemented algebraically.…”

Section: Introductionmentioning

confidence: 99%

Simulation of the inelastic deformation of porous reservoirs under cyclic loading relevant for underground hydrogen storage

Kumar

Honório

Hajibeygi

2022

Sci Rep

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Subsurface geological formations can be utilized to safely store large-scale (TWh) renewable energy in the form of green gases such as hydrogen. Successful implementation of this technology involves estimating feasible storage sites, including rigorous mechanical safety analyses. Geological formations are often highly heterogeneous and entail complex nonlinear inelastic rock deformation physics when utilized for cyclic energy storage. In this work, we present a novel scalable computational framework to analyse the impact of nonlinear deformation of porous reservoirs under cyclic loading. The proposed methodology includes three different time-dependent nonlinear constitutive models to appropriately describe the behavior of sandstone, shale rock and salt rock. These constitutive models are studied and benchmarked against both numerical and experimental results in the literature. An implicit time-integration scheme is developed to preserve the stability of the simulation. In order to ensure its scalability, the numerical strategy adopts a multiscale finite element formulation, in which coarse scale systems with locally-computed basis functions are constructed and solved. Further, the effect of heterogeneity on the results and estimation of deformation is analyzed. Lastly, the Bergermeer test case—an active Dutch natural gas storage field—is studied to investigate the influence of inelastic deformation on the uplift caused by cyclic injection and production of gas. The present study shows acceptable subsidence predictions in this field-scale test, once the properties of the finite element representative elementary volumes are tuned with the experimental data.

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A multiscale method for data assimilation

Cited by 12 publications

References 58 publications

Multi-Level Inversion Based on Mesh Decoupling

Multi-Level Inversion Based on Mesh Decoupling

Iterative multilevel assimilation of inverted seismic data

Simulation of the inelastic deformation of porous reservoirs under cyclic loading relevant for underground hydrogen storage

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