Verónica Anaya’s research while affiliated with University of Concepción and other places

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Publications (32)


Conforming and Nonconforming Virtual Element Methods for Fourth Order Nonlocal Reaction Diffusion Equation
  • Article

May 2023

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93 Reads

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1 Citation

Mathematical Models and Methods in Applied Sciences

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Veronica Anaya

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In this work, we have designed conforming and nonconforming Virtual Element Methods (VEM) to approximate non-stationary nonlocal biharmonic equation on general shaped domain. By employing Faedo-Galerkin technique, we have proved the existence and uniqueness of the continuous weak formulation. Upon applying Brouwer’s fixed point theorem, the well-posedness of the fully discrete scheme is derived. Further, following [37], we have introduced the Enrichment operator and derived a priori error estimates for fully discrete schemes on polygonal domains, not necessarily convex. The proposed error estimates are justified with some benchmark examples.




Velocity-vorticity-pressure formulation for the Oseen problem with variable viscosity

December 2021

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59 Reads

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13 Citations

Calcolo

We propose and analyse an augmented mixed finite element method for the Oseen equations written in terms of velocity, vorticity, and pressure with non-constant viscosity and homogeneous Dirichlet boundary condition for the velocity. The weak formulation includes least-squares terms arising from the constitutive equation and from the incompressibility condition, and we show that it satisfies the hypotheses of the Babuška-Brezzi theory. Repeating the arguments of the continuous analysis, the stability and solvability of the discrete problem are established. The method is suited for any Stokes inf-sup stable finite element pair for velocity and pressure, while for vorticity any generic discrete space (of arbitrary order) can be used. A priori and a posteriori error estimates are derived using two specific families of discrete subspaces. Finally, we provide a set of numerical tests illustrating the behaviour of the scheme, verifying the theoretical convergence rates, and showing the performance of the adaptive algorithm guided by residual a posteriori error estimation.


Figure 4.2. Example 3: Flow in a maze-shaped geometry. Distribution of variable kinematic viscosity, and portrait of approximate solutions (velocity magnitude and velocity streamlines, vorticity magnitude and vorticity streamlines, and pressure profile).
Augmented finite element formulation for the Navier--Stokes equations with vorticity and variable viscosity
  • Preprint
  • File available

November 2021

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247 Reads

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2 Citations

Computers & Mathematics with Applications

We propose and analyse an augmented mixed finite element method for the Navier--Stokes equations written in terms of velocity, vorticity, and pressure with non-constant viscosity and no-slip boundary conditions. The weak formulation includes least-squares terms arising from the constitutive equation and from the incompressibility condition, and we use a fixed point strategies to show the existence and uniqueness of continuous and discrete solutions under the assumption of sufficiently small data. The method is constructed using any compatible finite element pair (conforming or non-conforming) for velocity and pressure as dictated by Stokes inf-sup stability, while for vorticity any generic discrete space (of arbitrary order) can be used. We establish optimal a priori error estimates. Finally, we provide a set of numerical tests in 2D and 3D illustrating the behaviour of the scheme as well as verifying the theoretical convergence rates.

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Error analysis for a vorticity/Bernoulli pressure formulation for the Oseen equations

August 2021

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125 Reads

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2 Citations

Journal of Numerical Mathematics

A variational formulation is analysed for the Oseen equations written in terms of vorticity and Bernoulli pressure. The velocity is fully decoupled using the momentum balance equation, and it is later recovered by a post-process. A finite element method is also proposed, consisting in equal-order Nédélec finite elements and piecewise continuous polynomials for the vorticity and the Bernoulli pressure, respectively. The a priori error analysis is carried out in the L ² -norm for vorticity, pressure, and velocity; under a smallness assumption either on the convecting velocity, or on the mesh parameter. Furthermore, an a posteriori error estimator is designed and its robustness and efficiency are studied using weighted norms. Finally, a set of numerical examples in 2D and 3D is given, where the error indicator serves to guide adaptive mesh refinement. These tests illustrate the behaviour of the new formulation in typical flow conditions, and also confirm the theoretical findings.


Fig. 5.2. Example 3. Approximate elastic rotation on a horizontally clipped elastic geometry (top), displacement on a diagonally clipped domain (centre), and fluid pressure on a zoomed poroelastic domain (bottom); for three steps of adaptive refinement for the Biot/elasticity application in fractured reservoirs.
Robust a posteriori error analysis for rotation-based formulations of the elasticity/poroelasticity coupling

June 2021

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83 Reads

We develop the \textit{a posteriori} error analysis of three mixed finite element formulations for rotation-based equations in elasticity, poroelasticity, and interfacial elasticity-poroelasticity. The discretisations use H1H^1-conforming finite elements of degree k+1 for displacement and fluid pressure, and discontinuous piecewise polynomials of degree k for rotation vector, total pressure, and elastic pressure. Residual-based estimators are constructed, and upper and lower bounds (up to data oscillations) for all global estimators are rigorously derived. The methods are all robust with respect to the model parameters (in particular, the Lam\'e constants), they are valid in 2D and 3D, and also for arbitrary polynomial degree k0k\geq 0. The error behaviour predicted by the theoretical analysis is then demonstrated numerically on a set of computational examples including different geometries on which we perform adaptive mesh refinement guided by the \textit{a posteriori} error estimators.


Figure 5.5: Example 4. Flow inside a channel with obstacles. Vorticity and line integral contours, classical pressure together with velocity streamlines, and post-processed velocity magnitude and arrows. Computation done with a second-order method.
Numerical analysis of a new formulation for the Oseen equations in terms of vorticity and Bernoulli pressure

February 2021

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224 Reads

A variational formulation is introduced for the Oseen equations written in terms of vor\-ti\-city and Bernoulli pressure. The velocity is fully decoupled using the momentum balance equation, and it is later recovered by a post-process. A finite element method is also proposed, consisting in equal-order N\'ed\'elec finite elements and piecewise continuous polynomials for the vorticity and the Bernoulli pressure, respectively. The {\it a priori} error analysis is carried out in the L2\mathrm{L}^2-norm for vorticity, pressure, and velocity; under a smallness assumption either on the convecting velocity, or on the mesh parameter. Furthermore, an {\it a posteriori} error estimator is designed and its robustness and efficiency are studied using weighted norms. Finally, a set of numerical examples in 2D and 3D is given, where the error indicator serves to guide adaptive mesh refinement. These tests illustrate the behaviour of the new formulation in typical flow conditions, and they also confirm the theoretical findings.


Fig. 5.1. Example 2: Approximate solutions computed using the MINI-element. Velocity streamlines (left) vorticity streamlines (centre) and pressure distribution (right).
Fig. 5.2. Example 3: Snapshots of four grids, T 1 h , T 4 h , T 6 h , T 10 h , adaptively refined according to the a posteriori error indicator defined in (4.22).
Fig. 5.3. Example 4: Simulation of stationary blood flow in an aortic arch. Approximate velocity, vorticity, and pressure (top panels), and samples of adaptive mesh after one, two and three refinement steps, and visualising a cut focusing on the boundaries (bottom row).
Velocity-vorticity-pressure formulation for the Oseen problem with variable viscosity

February 2021

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130 Reads

We propose and analyse an augmented mixed finite element method for the Oseen equations written in terms of velocity, vorticity, and pressure with non-constant viscosity and homogeneous Dirichlet boundary condition for the velocity. The weak formulation includes least-squares terms arising from the constitutive equation and from the incompressibility condition, and we show that it satisfies the hypotheses of the Babu\vska-Brezzi theory. Repeating the arguments of the continuous analysis, the stability and solvability of the discrete problem are established. The method is suited for any Stokes inf-sup stable finite element pair for velocity and pressure, while for vorticity any generic discrete space (of arbitrary order) can be used. A priori and a posteriori error estimates are derived using two specific families of discrete subspaces. Finally, we provide a set of numerical tests illustrating the behaviour of the scheme, verifying the theoretical convergence rates, and showing the performance of the adaptive algorithm guided by residual a posteriori error estimation.



Citations (26)


... A similar observation is valid for the eventual use of non-conforming virtual G.N. Gatica and Z. Gharibi element methods, originally introduced in [41,42], and further extended to diverse linear and nonlinear models (see, e.g. [43][44][45], and [46]), whose applicability within a Banach spaces framework has not been developed either. ...

Reference:

A Banach spaces-based fully mixed virtual element method for the stationary two-dimensional Boussinesq equations
Conforming and Nonconforming Virtual Element Methods for Fourth Order Nonlocal Reaction Diffusion Equation
  • Citing Article
  • May 2023

Mathematical Models and Methods in Applied Sciences

... Experimental observations, summarized mathematically as Darcy's law, govern the momentum equations in such scenarios. However, Darcy's law proves insufficient under conditions of Reynolds numbers greater than one or high porosity [2,8,31,32]. To address this limitation, an extension to the traditional Darcy's law is introduced as the Brinkman term, specifically designed to account for transitional flow between boundaries [6,7]. ...

A vorticity-based mixed formulation for the unsteady Brinkman–Forchheimer equations
  • Citing Article
  • February 2023

Computer Methods in Applied Mechanics and Engineering

... These methods use the velocityvorticity-pressure formulation and include techniques like mixed finite element, stabilized, least-squares, discontinuous Galerkin, hybrid discontinuous Galerkin, and spectral methods. These approaches have been applied to problems such as Brinkman equations [12,16], Stokes flows [8,15,30], Oseen equations [9,14], Navier-Stokes equations [7,11,18,24], and elasticity problems [13]. In a recent study, Anaya et al. [10] introduced a new augmented mixed finite element technique for the Oseen equations with a more general friction term of the form ∇ · (νε(y)), where ε(y) is the strain rate tensor and ν is variable viscosity. ...

Error analysis for a vorticity/Bernoulli pressure formulation for the Oseen equations

Journal of Numerical Mathematics

... These methods use the velocityvorticity-pressure formulation and include techniques like mixed finite element, stabilized, least-squares, discontinuous Galerkin, hybrid discontinuous Galerkin, and spectral methods. These approaches have been applied to problems such as Brinkman equations [12,16], Stokes flows [8,15,30], Oseen equations [9,14], Navier-Stokes equations [7,11,18,24], and elasticity problems [13]. In a recent study, Anaya et al. [10] introduced a new augmented mixed finite element technique for the Oseen equations with a more general friction term of the form ∇ · (νε(y)), where ε(y) is the strain rate tensor and ν is variable viscosity. ...

Robust A Posteriori Error Analysis for Rotation-Based Formulations of the Elasticity/Poroelasticity Coupling
  • Citing Article
  • August 2022

SIAM Journal on Scientific Computing

... These issues are amplified in the time-dependent setting, where those solvers are used multiple (even thousands) of times. As a consequence, the last few years have seen an expansion in the literature on numerical methods for variable-viscosity incompressible flow problems [37,34,14,35,38,3,4,24,18]. ...

Augmented finite element formulation for the Navier--Stokes equations with vorticity and variable viscosity

Computers & Mathematics with Applications

... In that context, the literature on numerical methods for variable-viscosity flow problems has recently been expanding. Some examples are stabilisation methods [2,3], fractional-step schemes [1,4,5,6] and mixed formulations [7,8]. ...

Velocity-vorticity-pressure formulation for the Oseen problem with variable viscosity
  • Citing Article
  • December 2021

Calcolo

... Examples include filter design, prosthetics, simulation of oil extraction from reservoirs, carbon sequestration, and sound insulation structures. From the viewpoint of constructing and analyzing numerical methods, recent works for the interfacial Biot/elasticity problem can be found in [4,5,[25][26][27]. These contributions include mortar-type discretizations, formulations using rotations, and extensions to lubrication models. ...

Rotation-Based Mixed Formulations for an Elasticity-Poroelasticity Interface Problem

SIAM Journal on Scientific Computing

... These methods use the velocityvorticity-pressure formulation and include techniques like mixed finite element, stabilized, least-squares, discontinuous Galerkin, hybrid discontinuous Galerkin, and spectral methods. These approaches have been applied to problems such as Brinkman equations [12,16], Stokes flows [8,15,30], Oseen equations [9,14], Navier-Stokes equations [7,11,18,24], and elasticity problems [13]. In a recent study, Anaya et al. [10] introduced a new augmented mixed finite element technique for the Oseen equations with a more general friction term of the form ∇ · (νε(y)), where ε(y) is the strain rate tensor and ν is variable viscosity. ...

Incorporating variable viscosity in vorticity-based formulations for Brinkman equations

Comptes Rendus Mathematique

... The formulation of incompressible viscous flow equations using vorticity (or microrotation), velocity and pressure has been used and analysed extensively in, e.g., [1,2,8,7,11,17,19,22,14,28,31,37,43,44]. Later on, models for coupled advection-diffusion equations and vorticity-based viscous flow formulations have been introduced in [6,34] (see also the recent contribution [24]). ...

Analysis and Approximation of a Vorticity–Velocity–Pressure Formulation for the Oseen Equations

Journal of Scientific Computing