9 results on '"Houzeaux, Guillaume"'
Search Results
2. A Generic Performance Analysis Technique Applied to Different CFD Methods for HPC.
- Author
-
Garcia-Gasulla, Marta, Banchelli, Fabio, Peiro, Kilian, Ramirez-Gargallo, Guillem, Houzeaux, Guillaume, Ben Hassan Saïdi, Ismaïl, Tenaud, Christian, Spisso, Ivan, and Mantovani, Filippo
- Subjects
FINITE volume method ,COMPUTATIONAL fluid dynamics - Abstract
For complex engineering and scientific applications, Computational Fluid Dynamics (CFD) simulations require a huge amount of computational power. As such, it is of paramount importance to carefully assess the performance of CFD codes and to study them in depth for enabling optimisation and portability. In this paper, we study three complex CFD codes, OpenFOAM, Alya and CHORUS representing two numerical methods, namely the finite volume and finite-element methods, on both structured and unstructured meshes. To all codes, we apply a generic performance analysis method based on a set of metrics helping the code developer in spotting the critical points that can potentially limit the scalability of a parallel application. We show the root cause of the performance bottlenecks studying the three applications on the MareNostrum4 supercomputer. We conclude providing hints for improving the performance and the scalability of each application. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
3. A Gluing Method for Non-matching Meshes.
- Author
-
Houzeaux, Guillaume, Eguzkitza, Beatriz, Soni, Bela, Calmet, Hadrien, Aliabadi, Shahrouz, Bates, Alister, Doorly, Denis, and Vázquez, Mariano
- Subjects
MESH analysis (Electric circuits) ,GLUE ,RESPIRATORY organs ,SUPERIMPOSED coding ,PATCH dynamics ,OVERLAP integral - Abstract
Abstract: This paper presents a gluing method for composite meshes. Different meshes are generated independently and are glued together using some extension elements to connect them. The resulting global mesh is non-conforming and consists of connected overlapping meshes. The method is inherently implicit, parallel and versatile, in the sense that it is PDE independent. The most cited gluing method is probably the Chimera method, used for overset grids, where patch meshes are superimposed onto a background mesh. The method employed here was originally devised for such situations and is now applied to disjoint or overlapping meshes. One of the advantages of the method is that the meshes do not have to coincide and can present a gap between them. The method is illustrated through some simple examples to demonstrate the mesh convergence and finally applied to the solution of the airflow in the complete respiratory system, by joining independent meshes for the large and small airways. [Copyright &y& Elsevier]
- Published
- 2013
- Full Text
- View/download PDF
4. Parallel Aspects of Fluid-structure Interaction.
- Author
-
Casoni, Eva, Houzeaux, Guillaume, and Vázquez, Mariano
- Subjects
FLUID dynamics ,SCALABILITY ,HEAT transfer ,SOLID modeling (Engineering) ,COUPLED mode theory (Wave-motion) ,DEFORMATIONS (Mechanics) - Abstract
Abstract: This paper presents several parallelization aspects of Fluid-Structure Interaction (FSI) problems in computational mechanics when using an Arbitrary Lagrangian-Eulerian (ALE) scheme. The physical domain of the coupled problem is then solved on two different zones: a first zone for the fluid dynamics and the fluid mesh deformation and a second one for the solid mechanics. The idea can be further extended by adding more Physics to the coupled system, such as heat transport (for fluid and solid) or excitable media, among many others. In this paper, the basic two premises are that all problems can already be solved individually in parallel with good scalability and that the coupled system is solved in a coupled way within the same code. The paper introduces the formulation, presents some parallelization issues and proposes how to attack them, presents some results and discuss them and draws some future lines. [Copyright &y& Elsevier]
- Published
- 2013
- Full Text
- View/download PDF
5. Forest density is more effective than tree rigidity at reducing the onshore energy flux of tsunamis.
- Author
-
Mukherjee, Abhishek, Cajas, Juan Carlos, Houzeaux, Guillaume, Lehmkuhl, Oriol, Suckale, Jenny, and Marras, Simone
- Subjects
- *
FOREST density , *COMPUTATIONAL fluid dynamics , *FLUID-structure interaction , *COASTAL forests , *TSUNAMIS , *TREE trunks , *HARDWOODS - Abstract
Communities around the world are increasingly interested in nature-based solutions to the mitigation of coastal risks by coastal forests, but it remains unclear how much protective benefits vegetation provides, particularly in the limit of highly energetic flows after tsunami impact. The current study, using a three-dimensional incompressible computational fluid dynamics model with a fluid–structure interaction approach, aims to quantify how energy reflection and dissipation vary with different degrees of rigidity and vegetation density of a coastal forest. We represent tree trunks as cylinders and use the elastic modulus of hardwood trees such as pine or oak to characterize the rigidity of these cylinders. The numerical results show that energy reflection increases with rigidity only for a single cylinder. In the presence of multiple cylinders, the difference in energy reflection created by varying rigidity diminishes as the number of cylinders increases. Instead of rigidity, we find that the blockage area created by the presence of multiple tree trunks dominates energy reflection. As tree trunks are deformed by the hydrodynamic forces, they alter the flow field around them, causing turbulent kinetic energy generation in the wake region. As a consequence, trees dissipate flow energy, highlighting coastal forests reducing the onshore energy flux of tsunamis by means of both reflection and dissipation. • The number of tree trunks and the spacing between them are more important for tsunami-risk mitigation than the species-specific properties. • Deflection of tree trunks alters the flow field around them, causing turbulent kinetic energy generation in the wake region. • Coastal forests reduces the onshore energy flux of tsunamis by means of both reflection and dissipation. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
6. Fluid–structure interaction of human nasal valves under sniff conditions and transport of inhaled aerosols: A numerical study.
- Author
-
Calmet, Hadrien, Santiago, Alfonso, Cajas, Juan Carlos, Langdon, Cristobal, Eguzkitza, Beatriz, and Houzeaux, Guillaume
- Subjects
- *
FLUID-structure interaction , *COMPUTATIONAL fluid dynamics , *SOCIAL interaction , *VALVES , *AEROSOLS - Abstract
The nasal valve is the narrowest part of the nasal airway which is responsible for the largest part of the nasal resistance. Even little changes in the aperture can affect the flow downstream through the nose significantly. Its principal function is to limit airflow for example during a rapid and short inhalation, also called a sniff. Coupling Computational Fluid Dynamics (CFD) with Fluid–Structure Interaction (FSI) allows solving and exchanging force and displacement between the solid and fluid domains and offers a more accurate representation of the physical system in confined flow cases. Furthermore, particle transport and deposition are performed in this study to reveal the effect of the complex coupling on the nasal cavity deposition of inhaled aerosols. Two different configurations are used to model the nasal valve and differences in magnitudes in deformations are observed during the sniff. A comparison between FSI results and the in-vivo evaluation of the deformation shows an acceptable agreement as to the first step of validation. In addition, the results demonstrated that FSI increases significantly the particle deposition in the nasal cavity and the micro-particle diameter is the critical range parameter to enhance deposition with nasal valve deformation during a sniff. • The results demonstrated that FSI increases significantly the particle deposition in the nasal cavity. • The micro-particle diameter is the critical range parameter to enhance deposition with nasal valve deformation during a sniff. • The Comparison between FSI results and the in-vivo evaluation of the deformation shows an acceptable agreement as first step of validation. [ABSTRACT FROM AUTHOR]
- Published
- 2022
- Full Text
- View/download PDF
7. Dynamic load balance of chemical source term evaluation in high-fidelity combustion simulations.
- Author
-
Ramirez-Miranda, Guillem, Mira, Daniel, Pérez-Sánchez, Eduardo J., Surapaneni, Anurag, Borrell, Ricard, Houzeaux, Guillaume, and Garcia-Gasulla, Marta
- Subjects
- *
DYNAMIC balance (Mechanics) , *CHEMICAL kinetics , *COMBUSTION , *FLAME , *FLOW simulations , *DYNAMIC loads , *NUMERICAL integration - Abstract
This paper presents a load balancing strategy for reaction rate evaluation and chemistry integration in reacting flow simulations. The large disparity in scales during combustion introduces stiffness in the numerical integration of the PDEs and generates load imbalance during the parallel execution. The strategy is based on the use of the DLB library to redistribute the computing resources at node level, lending additional CPU-cores to higher loaded MPI processes. This approach does not require explicit data transfer and is activated automatically at runtime. Two chemistry descriptions, detailed and reduced, are evaluated on two different configurations: laminar counterflow flame and a turbulent swirl-stabilized flame. For single-node calculations, speedups of 2.3x and 7x are obtained for the detailed and reduced chemistry, respectively. Results on multi-node runs also show that DLB improves the performance of the pure-MPI code similar to single node runs. It is shown DLB can get performance improvements in both detailed and reduced chemistry calculations. • A load balancing strategy for reaction rate and chemistry integration is presented. • It uses the DLB library to redistribute the computational resources at node level. • Code hybridization improves the performance over MPI-pure implementations. • Single-node and multi-node tests show speedups in reacting flow calculations. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
8. Computational modelling of an aerosol extraction device for use in COVID-19 surgical tracheotomy.
- Author
-
Calmet, Hadrien, Bertomeu, Pablo Ferrer, McIntyre, Charlotte, Rennie, Catherine, Gouder, Kevin, Houzeaux, Guillaume, Fletcher, Christian, Still, Robert, and Doorly, Denis
- Subjects
- *
COVID-19 , *MICROBIOLOGICAL aerosols , *COVID-19 pandemic , *AEROSOLS , *COMPUTATIONAL fluid dynamics , *TRACHEOTOMY - Abstract
In view of the ongoing COVID-19 pandemic and its effects on global health, understanding and accurately modelling the propagation of human biological aerosols has become crucial. Worldwide, health professionals have been one of the most affected demographics, representing approximately 20% of all cases in Spain, 10% in Italy and 4% in China and US. Methods to contain and remove potentially infected aerosols during Aerosol Generating Procedures (AGPs) near source offer advantages in reducing the contamination of protective clothing and the surrounding theatre equipment and space. In this work we describe the application of computational fluid dynamics in assessing the performance of a prototype extraction hood as a means to contain a high speed aerosol jet. Whilst the particular prototype device is intended to be used during tracheotomies, which are increasingly common in the wake of COVID-19, the underlying physics can be adapted to design similar machines for other AGPs. Computational modelling aspect of this study was largely carried out by Barcelona Supercomputing Center using the high performance computational mechanics code Alya. Based on the high fidelity LES coupled with Lagrangian frameworks the results demonstrate high containment efficiency of generated particles is feasible with achievable air extraction rates. • Evaluation of a new device to reduce the risk of infection during Aerosol Generating Procedures for use in COVID-19 surgical tracheotomy. • High fidelity LES coupled with Lagrangian frameworks is used as results to demonstrate the efficiency. • Accurate numerical modelling of the propagation of human biological aerosols. [ABSTRACT FROM AUTHOR]
- Published
- 2022
- Full Text
- View/download PDF
9. A variational multiscale stabilized finite element method for the solution of the Euler equations of nonhydrostatic stratified flows
- Author
-
Marras, Simone, Moragues, Margarida, Vázquez, Mariano, Jorba, Oriol, and Houzeaux, Guillaume
- Subjects
- *
FINITE element method , *EULER equations , *HYDROSTATICS , *ALGORITHMS , *COMPUTATIONAL fluid dynamics , *BUOYANCY - Abstract
Abstract: We present a compressible version of the variational multiscale stabilization (VMS) method applied to the finite element (FE) solution of the Euler equations for nonhydrostatic stratified flows. This paper is meant to verify how the algorithm performs when solving problems in the framework of nonhydrostatic atmospheric dynamics. This effort is justified by the previously observed good performance of VMS and by the advantages that a compact Galerkin formulation offers on massively parallel architectures – a paradigm for both computational fluid dynamics (CFD) and numerical weather prediction (NWP) practitioners. We also propose a simple technique to construct a well-balanced approximation of the dominant hydrostatics that, if not properly discretized, may cause unacceptable vertical oscillations. This is a relevant problem in NWP, especially in the proximity of steep topography. To evaluate the performance of the method for stratified environments, six standard 2D and two 3D test cases are selected. Of these, two admit a semi-analytic solution, while the remaining six are non-steady and non-linear thermal problems with dominant buoyancy effects that challenge the algorithm in terms of stability. [Copyright &y& Elsevier]
- Published
- 2013
- Full Text
- View/download PDF
Catalog
Discovery Service for Jio Institute Digital Library
For full access to our library's resources, please sign in.