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49 results on '"Hale, Jack S."'

1. Intrinsic mixed-dimensional beam-shell-solid couplings in linear Cosserat continua via tangential differential calculus

Author

Sky, Adam, Hale, Jack S., Zilian, Andreas, Bordas, Stéphane P. A., and Neff, Patrizio

Subjects
Mathematics - Numerical Analysis, Computer Science - Computational Engineering, Finance, and Science, Mathematical Physics
Abstract

We present an approach to the coupling of mixed-dimensional continua by employing the mathematically enriched linear Cosserat micropolar model. The kinematical reduction of the model to lower dimensional domains leaves its fundamental degrees of freedom intact. Consequently, the degrees of freedom intrinsically agree even at the interface with a domain of a different dimensionality. Thus, this approach circumvents the need for intermediate finite elements or mortar methods. We introduce the derivations of all models of various dimensions using tangential differential calculus. The coupling itself is then achieved by defining a mixed-dimensional action functional with consistent Sobolev trace operators. Finally, we present numerical examples involving a three-dimensional silicone-rubber block reinforced with a curved graphite shell on its lower surface, a three-dimensional silver block reinforced with a graphite plate and beams, and lastly, intersecting silver shells reinforced with graphite beams.

Published
2024

2. Formulae and transformations for simplicial tensorial finite elements via polytopal templates

Author

Sky, Adam, Neunteufel, Michael, Hale, Jack S., and Zilian, Andreas

Subjects
Mathematics - Numerical Analysis
Abstract

We introduce a unified method for constructing the basis functions of a wide variety of partially continuous tensor-valued finite elements on simplices using polytopal templates. These finite element spaces are essential for achieving well-posed discretisations of mixed formulations of partial differential equations that involve tensor-valued functions, such as the Hellinger-Reissner formulation of linear elasticity. In our proposed polytopal template method, the basis functions are constructed from template tensors associated with the geometric polytopes (vertices, edges, faces etc.) of the reference simplex and any scalar-valued $H^1$-conforming finite element space. From this starting point we can construct the Regge, Hellan-Herrmann-Johnson, Pechstein-Sch\"oberl, Hu-Zhang, Hu-Ma-Sun and Gopalakrishnan-Lederer-Sch\"oberl elements. Because the Hu-Zhang element and the Hu-Ma-Sun element cannot be mapped from the reference simplex to a physical simplex via standard double Piola mappings, we also demonstrate that the polytopal template tensors can be used to define a consistent mapping from a reference simplex even to a non-affine simplex in the physical mesh. Finally, we discuss the implications of element regularity with two numerical examples for the Reissner-Mindlin plate problem.

Published
2024

3. FEniCSx Preconditioning Tools (FEniCSx-pctools)

Author

Řehoř, Martin and Hale, Jack S.

Subjects
Computer Science - Mathematical Software, Mathematics - Numerical Analysis, 65N22, 65F08, 65F10
Abstract

FEniCSx Preconditioning Tools (FEniCSx-pctools) is a software package for easing the specification of PETSc-based block preconditioning strategies in the DOLFINx finite element solver of the FEniCS Project. It attaches all of the necessary metadata to the block-structured linear systems in order that block-structured preconditioners can be applied straightforwardly via PETSc's options-based configuration system. Fast prototyping is facilitated thanks to the implementation in Python, and all intensive operations are executed in C/C++. FEniCSx-pctools is available under the LGPLv3 or later license., Comment: 7 pages, 2 figures, 1 table

Published
2024

5. A Reissner-Mindlin plate formulation using symmetric Hu-Zhang elements via polytopal transformations

Author

Sky, Adam, Neunteufel, Michael, Hale, Jack S., and Zilian, Andreas

Subjects
Mathematics - Numerical Analysis
Abstract

In this work we develop new finite element discretisations of the shear-deformable Reissner--Mindlin plate problem based on the Hellinger-Reissner principle of symmetric stresses. Specifically, we use conforming Hu-Zhang elements to discretise the bending moments in the space of symmetric square integrable fields with a square integrable divergence $\boldsymbol{M} \in \mathcal{HZ} \subset H^{\mathrm{sym}}(\mathrm{Div})$. The latter results in highly accurate approximations of the bending moments $\boldsymbol{M}$ and in the rotation field being in the discontinuous Lebesgue space $\boldsymbol{\phi} \in [L]^2$, such that the Kirchhoff-Love constraint can be satisfied for $t \to 0$. In order to preserve optimal convergence rates across all variables for the case $t \to 0$, we present an extension of the formulation using Raviart-Thomas elements for the shear stress $\mathbf{q} \in \mathcal{RT} \subset H(\mathrm{div})$. We prove existence and uniqueness in the continuous setting and rely on exact complexes for inheritance of well-posedness in the discrete setting. This work introduces an efficient construction of the Hu-Zhang base functions on the reference element via the polytopal template methodology and Legendre polynomials, making it applicable to hp-FEM. The base functions on the reference element are then mapped to the physical element using novel polytopal transformations, which are suitable also for curved geometries. The robustness of the formulations and the construction of the Hu-Zhang element are tested for shear-locking, curved geometries and an L-shaped domain with a singularity in the bending moments $\boldsymbol{M}$. Further, we compare the performance of the novel formulations with the primal-, MITC- and recently introduced TDNNS methods., Comment: Additional implementation material in: https://github.com/Askys/NGSolve_HuZhang_Element

Published
2023

6. SOniCS: Develop intuition on biomechanical systems through interactive error controlled simulations

Author

Mazier, Arnaud, Hadramy, Sidaty El, Brunet, Jean-Nicolas, Hale, Jack S., Cotin, Stéphane, and Bordas, Stéphane P. A.

Subjects
Computer Science - Mathematical Software, Computer Science - Computational Engineering, Finance, and Science, Computer Science - Software Engineering
Abstract

This new approach allows the user to experiment with model choices easily and quickly without requiring in-depth expertise, as constitutive models can be modified by one line of code only. This ease in building new models makes SOniCS ideal to develop surrogate, reduced order models and to train machine learning algorithms for uncertainty quantification or to enable patient-specific simulations. SOniCS is thus not only a tool that facilitates the development of surgical training simulations but also, and perhaps more importantly, paves the way to increase the intuition of users or otherwise non-intuitive behaviors of (bio)mechanical systems. The plugin uses new developments of the FEniCSx project enabling automatic generation with FFCx of finite element tensors such as the local residual vector and Jacobian matrix. We validate our approach with numerical simulations such as manufactured solutions, cantilever beams, and benchmarks provided by FEBio. We reach machine precision accuracy and demonstrate the use of the plugin for a real-time haptic simulation involving a surgical tool controlled by the user in contact with a hyperelastic liver. We include complete examples showing the use of our plugin for simulations involving Saint Venant-Kirchhoff, Neo-Hookean, Mooney-Rivlin, and Holzapfel Ogden anisotropic models as supplementary material.

Published
2022

7. An a posteriori error estimator for the spectral fractional power of the Laplacian

Author

Bulle, Raphaël, Barrera, Olga, Bordas, Stéphane P. A., Chouly, Franz, and Hale, Jack S.

Subjects
Mathematics - Numerical Analysis, 65N15, 65N30
Abstract

We develop a novel a posteriori error estimator for the $L^2$ error committed by the finite element discretization of the solution of the fractional Laplacian. Our a posteriori error estimator takes advantage of the semi-discretization scheme using rational approximations which allow to reformulate the fractional problem into a family of non-fractional parametric problems. The estimator involves applying the implicit Bank-Weiser error estimation strategy to each parametric non-fractional problem and reconstructing the fractional error through the same rational approximation used to compute the solution to the original fractional problem. In addition we propose an algorithm to adapt both the finite element mesh and the rational scheme in order to balance the discretization errors. We provide several numerical examples in both two and three-dimensions demonstrating the effectivity of our estimator for varying fractional powers and its ability to drive an adaptive mesh refinement strategy.

Published
2022
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8. Inverse deformation analysis: an experimental and numerical assessment using the FEniCS Project

Author

Mazier, Arnaud, Bilger, Alexandre, Forte, Antonio E., Peterlik, Igor, Hale, Jack S., Bordas, Stéphane P. A., Engineering, Institute of Computational, Engineering, Department of, Luxembourg, University of, Esch-sur-Alzette, Luxembourg., University, Harvard, Cambridge, USA., Electronics, Department of, Information, Bioengineering, di Milano, Politecnico, Milan, Italy., Science, Institute of Computer, University, Masaryk, Republic., Czech, Research, Institute of, University, Development Duy Tan, Danang, and Vietnam

Subjects
Computer Science - Computational Engineering, Finance, and Science
Abstract

In this paper, we develop a framework for solving inverse deformation problems using the FEniCS Project finite element software. We validate our approach with experimental imaging data acquired from a soft silicone beam under gravity. In contrast with inverse iterative algorithms that require multiple solutions of a standard elasticity problem, the proposed method can compute the undeformed configuration by solving only one modified elasticity problem. This modified problem has a complexity comparable to the standard one. The framework is implemented within an open-source pipeline enabling the direct and inverse deformation simulation directly from imaging data. We use the high-level Unified Form Language (UFL) of the FEniCS Project to express the finite element model in variational form and to automatically derive the consistent Jacobian. Consequently, the design of the pipeline is flexible: for example, it allows the modification of the constitutive models by changing a single line of code. We include a complete working example showing the inverse deformation of a beam deformed by gravity as supplementary material., Comment: 33 pages, 12 figures, submitted to Elsevier

Published
2021

9. Hierarchical a posteriori error estimation of Bank-Weiser type in the FEniCS Project

Author

Bulle, Raphaël, Hale, Jack S., Lozinski, Alexei, Bordas, Stéphane P. A., and Chouly, Franz

Subjects
Mathematics - Numerical Analysis, Computer Science - Computational Engineering, Finance, and Science
Abstract

In the seminal paper of Bank and Weiser [Math. Comp., 44 (1985), pp.283-301] a new a posteriori estimator was introduced. This estimator requires the solution of a local Neumann problem on every cell of the finite element mesh. Despite the promise of Bank-Weiser type estimators, namely locality, computational efficiency, and asymptotic sharpness, they have seen little use in practical computational problems. The focus of this contribution is to describe a novel implementation of hierarchical estimators of the Bank-Weiser type in a modern high-level finite element software with automatic code generation capabilities. We show how to use the estimator to drive (goal-oriented) adaptive mesh refinement and to mixed approximations of the nearly-incompressible elasticity problems. We provide comparisons with various other used estimators. An open-source implementation based on the FEniCS Project finite element software is provided as supplementary material.

Published
2021

13. A volume-averaged nodal projection method for the Reissner-Mindlin plate model

Author

Ortiz-Bernardin, Alejandro, Köbrich, Philip, Hale, Jack S., Olate-Sanzana, Edgardo, Bordas, Stéphane P. A., and Natarajan, Sundararajan

Subjects
Mathematics - Numerical Analysis
Abstract

We introduce a novel meshfree Galerkin method for the solution of Reissner-Mindlin plate problems that is written in terms of the primitive variables only (i.e., rotations and transverse displacement) and is devoid of shear-locking. The proposed approach uses linear maximum-entropy approximations and is built variationally on a two-field potential energy functional wherein the shear strain, written in terms of the primitive variables, is computed via a volume-averaged nodal projection operator that is constructed from the Kirchhoff constraint of the three-field mixed weak form. The stability of the method is rendered by adding bubble-like enrichment to the rotation degrees of freedom. Some benchmark problems are presented to demonstrate the accuracy and performance of the proposed method for a wide range of plate thicknesses.

Published
2018
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14. Containers for portable, productive and performant scientific computing

Author

Hale, Jack S., Li, Lizao, Richardson, Chris N., and Wells, Garth N.

Subjects
Computer Science - Distributed, Parallel, and Cluster Computing, Computer Science - Mathematical Software, Computer Science - Software Engineering, 68N99, 68U0, D.2.7, D.2.8, D.2.9
Abstract

Containers are an emerging technology that hold promise for improving productivity and code portability in scientific computing. We examine Linux container technology for the distribution of a non-trivial scientific computing software stack and its execution on a spectrum of platforms from laptop computers through to high performance computing (HPC) systems. We show on a workstation and a leadership-class HPC system that when deployed appropriately there are no performance penalties running scientific programs inside containers. For Python code run on large parallel computers, the run time is reduced inside a container due to faster library imports. The software distribution approach and data that we present will help developers and users decide on whether container technology is appropriate for them. We also provide guidance for the vendors of HPC systems that rely on proprietary libraries for performance on what they can do to make containers work seamlessly and without performance penalty.

Published
2016
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15. Bayesian inference for the stochastic identification of elastoplastic material parameters: Introduction, misconceptions and insights

Author

Rappel, Hussein, Beex, Lars A. A., Hale, Jack S., and Bordas, Stephane P. A.

Subjects
Computer Science - Computational Engineering, Finance, and Science
Abstract

We discuss Bayesian inference (BI) for the probabilistic identification of material parameters. This contribution aims to shed light on the use of BI for the identification of elastoplastic material parameters. For this purpose a single spring is considered, for which the stress-strain curves are artificially created. Besides offering a didactic introduction to BI, this paper proposes an approach to incorporate statistical errors both in the measured stresses, and in the measured strains. It is assumed that the uncertainty is only due to measurement errors and the material is homogeneous. Furthermore, a number of possible misconceptions on BI are highlighted based on the purely elastic case.

Published
2016

26. Selecting a conceptual hydrological model using Bayes' factors computed with Replica Exchange Hamiltonian Monte Carlo and Thermodynamic Integration.

Author

Mingo, Damian N., Nijzink, Remko, Ley, Christophe, and Hale, Jack S.

Subjects
MARKOV chain Monte Carlo, CONCEPTUAL models, HYDROLOGIC models, PARSIMONIOUS models, PROGRAMMING languages
Abstract

We develop a method for computing Bayes' factors of conceptual rainfall-runoff models based on thermodynamic integration, gradient-based replica-exchange Markov Chain Monte Carlo algorithms and modern differentiable programming languages. We apply our approach to the problem of choosing from a set of conceptual bucket-type models with increasing dynamical complexity calibrated against both synthetically generated and real runoff data from Magela Creek, Australia. We show that using the proposed methodology the Bayes factor can be used to select a parsimonious model and can be computed robustly in a few hours on modern computing hardware. We introduce formal posterior predictive checks for the selected model. The prior calibrated posterior predictive p-value, which also tests for prior data conflict, is used for the posterior predictive checks. Prior data conflict is when the prior favours parameter values that are less likely given the data. [ABSTRACT FROM AUTHOR]

Published
2024
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35. FEniCSX: A sustainable future for the FEniCS Project

Author

Habera, Michal, Hale, Jack S., Richardson, Chris, Ring, Johannes, Rognes, Marie, Sime, Nate, and Wells, Garth N.

Abstract

The FEniCS Project was founded in 2003, and is open source software for the automatic solution of partial differential equations using the finite element method. Only a few individuals involved in the early days are still active in 2019, and the scientific software landscape has changed immeasurably in that time. Nonetheless, the FEniCS Project is still actively maintained, widely used, and is currently undergoing a complete overhaul in a project we call FEniCSX. In this talk I will highlight four of the most impactful changes with respect to the sustainability of the FEniCS Project:Formalisation of a governance structure within NumFOCUS. By joining NumFOCUS, the FEniCS Project has gained access to a huge variety of legal, administrative and fundraising opportunities.Sustainable pathways for bringing in new contributors. Examples include access to the Google Summer of Code programme, which has lead to some of the most significant new features (e.g. complex number support).The FEniCSX technical redevelopment. FEniCSX is a complete redevelopment of the FEniCS Project's software components, with a strong focus on simplicity, extensibility and standards compliance.Reducing time burden on core developers with software as a service. We used to administer many services e.g. continuous integration, ourselves. Wherever possible, we are now using external third party services.Presented at SIAM PP20 Minisymposium: Improving Productivity and Sustainability for Parallel Computing Software.

Published
2020
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37. Bubble-Enriched Smoothed Finite Element Methods for Nearly-Incompressible Solids.

Author

Lee, Changkye, Natarajan, Sundararajan, Hale, Jack S., Taylor, Zeike A., and Jurng-Jae Yee

Subjects
FINITE element method, ANALYTICAL solutions, DEGREES of freedom, SOLIDS
Abstract

This work presents a locking-free smoothed finite element method (S-FEM) for the simulation of soft matter modelled by the equations of quasi-incompressible hyperelasticity. The proposed method overcomes well-known issues of standard finite element methods (FEM) in the incompressible limit: the over-estimation of stiffness and sensitivity to severely distorted meshes. The concepts of cell-based, edge-based and node-based S-FEMs are extended in this paper to three-dimensions. Additionally, a cubic bubble function is utilized to improve accuracy and stability. For the bubble function, an additional displacement degree of freedom is added at the centroid of the element. Several numerical studies are performed demonstrating the stability and validity of the proposed approach. The obtained results are compared with standard FEM and with analytical solutions to show the effectiveness of the method. [ABSTRACT FROM AUTHOR]

Published
2021
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38. Strain smoothing for compressible and nearly-incompressible finite elasticity

Author

Lee, Chang-Kye, Angela Mihai, L., Hale, Jack S., Kerfriden, Pierre, and Bordas, Stéphane P.A.

Subjects
Materials Science(all), Mechanical Engineering, Modelling and Simulation, QA, Civil and Structural Engineering, Computer Science Applications, Mathematics::Numerical Analysis
Abstract

We present a robust and efficient form of the smoothed finite element method (S-FEM) to simulate hyperelastic bodies with compressible and nearly-incompressible neo-Hookean behaviour. The resulting method is stable, free from volumetric locking and robust on highly distorted meshes. To ensure inf-sup stability of our method we add a cubic bubble function to each element. The weak form for the smoothed hyperelastic problem is derived analogously to that of smoothed linear elastic problem. Smoothed strains and smoothed deformation gradients are evaluated on sub-domains selected by either edge information (edge-based S-FEM, ES-FEM) or nodal information (node-based S-FEM, NS-FEM). Numerical examples are shown that demonstrate the efficiency and reliability of the proposed approach in the nearly-incompressible limit and on highly distorted meshes. We conclude that, strain smoothing is at least as accurate and stable, as the MINI element, for an equivalent problem size.

Published
2017

39. FEniCS: Sustainable Software Development Practices

Author

Alnæs, Martin, Blechta, Jan, Hale, Jack S., Logg, Anders, Richardson, Chris, Johannr@Simula.No, Rognes, Marie, and Wells, Garth N.

Abstract

The FEniCS project aims to provide a high productivity environment for development of finite element based simulation software. Techniques applied to achieve this goal include mixed language programming and code generation, which enables writing high performance programs in a high level language. End-user productivity is a high priority goal in our software designs. To sustain the productivity of the multinational team of part-time developers (mainly researchers and students) is paramount to the long term survival of the project. To minimize the developer workload while making the process open and accessible to new contributors and users, we regularly question which tools are the best available for our needs. On this poster we will present our current tool choices and work flows for developers and the wider FEniCS community. This list includes version control, build systems, testing, release management, team communication, documentation, and end user support. The most recent addition to our toolbox are developer curated Docker images. We are investigating their usefulness in testing infrastructure, end user deployment, HPC cluster deployment, and as reproducible software environments to accompany journal publications. We welcome discussion on alternatives that can simplify our lives.Poster presented at SIAM CSE17 PP108 Minisymposterium: Software Productivity and Sustainability for CSE and Data Science.

Published
2017
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42. Investigation of the Sharkskin melt instability using optical Fourier analysis.

Author

Gansen, Alex, Řehoř, Martin, Sill, Clemens, Polińska, Patrycja, Westermann, Stephan, Dheur, Jean, Hale, Jack S., and Baller, Jörg

Subjects
STYRENE-butadiene rubber, EXTRUSION process, PRESSURE transducers, FLOW instability, INVESTIGATIONS, PLASTIC extrusion, FOURIER analysis
Abstract

An optical method allowing the characterization of melt flow instabilities typically occurring during an extrusion process of polymers and polymer compounds is presented. It is based on a camera‐acquired image of the extruded compound with a reference length scale. Application of image processing and transformation of the calibrated image to the frequency domain yields the magnitude spectrum of the instability. The effectiveness of the before mentioned approach is shown on Styrene‐butadiene rubber (SBR) compounds, covering a wide range of silica filler content, extruded through a Göttfert capillary rheometer. The results of the image‐based analysis are compared with the results from the sharkskin option, a series of highly sensitive pressure transducers installed inside the rheometer. A simplified version of the code used to produce the optical analysis results is included as supplementary material. © 2019 Wiley Periodicals, Inc. J. Appl. Polym. Sci. 2020, 137, 48806. [ABSTRACT FROM AUTHOR]

Published
2020
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47. FEniCS in Linux Containers

Author

Hale, Jack S., Lizao (Larry) Li, and Wells, Garth N.

Abstract

Poster presented at the FEniCS'15 Workshop, Imperial College London, 29th June - 1st July 2015.

Published
2015
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49. Bayesian inference for the stochastic identification of elastoplastic material parameters: Introduction, misconceptions and insights

Author

Rappel, Hussein, Beex, Lars A. A., Hale, Jack S., Bordas, Stephane P. A., University of Luxembourg - UL [sponsor], and European Research Council [sponsor]

Subjects
FOS: Computer and information sciences, Bayes’ theorem, elastoplasticity, statistical identification, Materials science & engineering [C09] [Engineering, computing & technology], Bayesian inference, Multidisciplinary, general & others [C99] [Engineering, computing & technology], stochastic identification, Mechanical engineering [C10] [Engineering, computing & technology], Computational Engineering, Finance, and Science (cs.CE), Multidisciplinaire, généralités & autres [C99] [Ingénierie, informatique & technologie], parameter identification, Science des matériaux & ingénierie [C09] [Ingénierie, informatique & technologie], Ingénierie mécanique [C10] [Ingénierie, informatique & technologie], plasticity, Multidisciplinary, general & others [G99] [Physical, chemical, mathematical & earth Sciences], Computer Science - Computational Engineering, Finance, and Science, Multidisciplinaire, général & autres [G99] [Physique, chimie, mathématiques & sciences de la terre], Civil engineering [C04] [Engineering, computing & technology], Ingénierie civile [C04] [Ingénierie, informatique & technologie]
Abstract

We discuss Bayesian inference (BI) for the probabilistic identification of material parameters. This contribution aims to shed light on the use of BI for the identification of elastoplastic material parameters. For this purpose a single spring is considered, for which the stress-strain curves are artificially created. Besides offering a didactic introduction to BI, this paper proposes an approach to incorporate statistical errors both in the measured stresses, and in the measured strains. It is assumed that the uncertainty is only due to measurement errors and the material is homogeneous. Furthermore, a number of possible misconceptions on BI are highlighted based on the purely elastic case. v4

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