PDE acceleration: a convergence rate analysis and applications to obstacle problems

Calder, Jeff; Yezzi, Anthony

doi:10.1007/s40687-019-0197-x

Cited by 6 publications

(3 citation statements)

References 43 publications

(131 reference statements)

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“…Recent studies with matrix-free methods have demonstrated the ability to solve up to 10 12 degrees of freedom with a parallel efficiency of >90 per cent (Bauer et al 2019), which is far beyond what matrix-based methods can reach. At the same time, the iterative procedure of Pseudo-transient continuation, inspired by physical processes, has been proven to solve multiphysics problems efficiently (Frankel 1950;Calder & Yezzi 2019;Räss et al 2019;Benyamin et al 2020). With matrix-free implementation, Rass et al 2019 applied a pseudo-transient solver to simulate the long-term evolution of large-scale 3-D problems (1000 3 ) and showed its ability to handle the non-linearity of Kozeny-Carman permeability and decompaction weakening.…”

Section: Numerical Methods In Geosciencesmentioning

confidence: 99%

“…This method is also widely known as the 2nd Richardson or relaxation method (Frankel 1950), dynamic relaxation method (Otter et al 1966;Zhang & Yu 1989) and inertial method (Poliakov et al 1993). Recently, a general framework for this type of numerical methods has been developed, known as 'PDE acceleration', which shows great potentials both for the forward and inverse modeling problems (Calder & Yezzi 2018;Benyamin et al 2020). As demonstrated by previous studies, fast PT solvers usually involve 2nd time-derivatives or 'damping factors' (Frankel 1950;Zhang & Yu 1989;Chen 2009;Benyamin et al 2020) that enable the iteration number to be linearly scaled with grid number in one direction.…”

Section: P S E U D O -T R a N S I E N T C O N T I N Uat I O N M E T H...mentioning

confidence: 99%

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Physics-inspired pseudo-transient method and its application in modelling focused fluid flow with geological complexity

Wang

Yarushina

Alkhimenkov

et al. 2021

Geophysical Journal International

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Summary Two-phase flow equations that couple solid deformation and fluid migration have opened new research trends in geodynamical simulations and modelling of subsurface engineering. Physical nonlinearity of fluid-rock systems and strong coupling between flow and deformation in such equations lead to interesting predictions such as spontaneous formation of focused fluid flow in ductile/plastic rocks. However, numerical implementation of two-phase flow equations and their application to realistic geological environments with complex geometries and multiple stratigraphic layers is challenging. This study documents an efficient pseudo-transient solver for two-phase flow equations and describes the numerical theory and physical rationale. We provide a simple explanation for all steps involved in the development of a pseudo-transient numerical scheme for various types of equations. Two different constitutive models are used in our formulations: a bilinear viscous model with decompaction weakening and a viscoplastic model that allows decompaction weakening at positive effective pressures. The resulting numerical models are used to study fluid leakage from high porosity reservoirs into less porous overlying rocks. The interplay between time-dependent rock deformation and the buoyancy of ascending fluids leads to the formation of localized channels. The role of material parameters, reservoir topology, geological heterogeneity and porosity is investigated. Our results show that material parameters control the propagation speed of channels while the geometry of the reservoir controls their locations. Geological layers present in the overburden do not stop the propagation of the localized channels but rather modify their width, permeability, and growth speed.

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Section: Numerical Methods In Geosciencesmentioning

confidence: 99%

Section: P S E U D O -T R a N S I E N T C O N T I N Uat I O N M E T H...mentioning

confidence: 99%

Physics-inspired pseudo-transient method and its application in modelling focused fluid flow with geological complexity

Wang

Yarushina

Alkhimenkov

et al. 2021

Geophysical Journal International

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“…Recently, Koblitz et al [33] investigated the hydrodynamic forces for very high values of Bn. Calder and Yezzi [34] considered a rate of convergence and application for obstacle problems. In some studies mentioned therein [35][36][37][38], authors have numerically investigated the flows of incompressible non-Newtonian fluids in various computational domains.…”

Section: Outletmentioning

confidence: 99%

Flow of the Bingham-Papanastasiou Regularized Material in a Channel in the Presence of Obstacles: Correlation between Hydrodynamic Forces and Spacing of Obstacles

Mehmood

Mahmood

Majeed

et al. 2021

Modelling and Simulation in Engineering

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The numerical modeling and simulation for the stationary Bingham fluid flow around two confined circular cylinders with various gap ratios are studied. The singularity in the model’s apparent viscosity is dealt by Papanastasiou’s regularization. The model equations are discretized by adopting the methodology based on finite element method (FEM) by choosing a mixed higher order LBB-stable P 2 − P 1 finite element pair. The direct solver PARADISO has been utilized to solve the linearized system of equations. Hydrodynamic forces represented by drag and lift coefficients are computed, and a correlation coefficient is calculated for the gap ratios 0.1 ≤ G p ≤ 0.3 and for several values of the Bingham number 0 ≤ B n ≤ 50 . Line graphs for horizontal and vertical velocities are drawn. Moreover, velocity and pressure profiles are plotted for pertinent values of the parameters. Plug and shear zones are revealed via velocity snapshots in the domain. Pressure is nonlinear in the vicinity of the obstacles and becomes linear downstream in the cylinders as expected in channel flows.

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Distributionally-Robust Optimization for Sustainable Exploitation of the Infinite-Dimensional Superposition of Affine Processes with an Application to Fish Migration

Yoshioka

Tsujimura

Yoshioka

2023

Computational Science – ICCS 2023

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PDE acceleration: a convergence rate analysis and applications to obstacle problems

Cited by 6 publications

References 43 publications

Physics-inspired pseudo-transient method and its application in modelling focused fluid flow with geological complexity

Physics-inspired pseudo-transient method and its application in modelling focused fluid flow with geological complexity

Flow of the Bingham-Papanastasiou Regularized Material in a Channel in the Presence of Obstacles: Correlation between Hydrodynamic Forces and Spacing of Obstacles

Distributionally-Robust Optimization for Sustainable Exploitation of the Infinite-Dimensional Superposition of Affine Processes with an Application to Fish Migration

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