SFB 1313 PPSL #66 "A novel forward Lagrangian-Eulerian method for computing hyperbolic PDEs and applications" by Eduardo Cardoso de Abreu

June 17, 2025 /

The SFB 1313 "Pretty Porous Science Lecture" #66 will be given by Eduardo Cardoso de Abreu | State University of Campinas, Brazil | 17 June 2025 | 4 pm CET

We are pleased to announce that Eduardo Cardoso de Abreu, professor at the Department of Applied Mathematics of the State University of Campinas UNICAMP (Brazil), will give the SFB 1313 "Pretty Porous Science Lecture" #66. His talk will be on "A novel forward Lagrangian-Eulerian method for computing hyperbolic PDEs and applications".

Date: Tuesday, 17 June 2025
Time: 4 pm
Speaker: Prof. Eduardo Cardoso de Abreu, State University of Campinas UNICAMP (Brazil)
Title: "A novel forward Lagrangian-Eulerian method for computing hyperbolic PDEs and applications"
Venue: Multi Media Lab (MML), U1.003, Pfaffenwaldring 61, 70569 Stuttgart, Campus Vaihingen. If you are interested in participating in the lecture online, please contact samaneh.vahiddastjerdi@mechbau.uni-stuttgart.de

Abstract

Modeling, mathematical and numerical analysis challenges for the study of hyperbolic PDEs is in the realm of basic and applied sciences related to fluid mechanics, modeling of vehicular traffic flows, and fluid dynamics  in porous media flows, just to name a few specific problems. We design a new class of fully-discrete and semi-discrete Lagrangian-Eulerian schemes to approximate nonlinear multidimensional initial value problems for scalar models and multidimensional systems of hyperbolic conservation laws. The approach is also applied to nonlinear balance laws. The method is based on the concept of multidimensional no-flow curves/surfaces/manifolds. Roughly speaking, one reduces the hyperbolic PDE into a family of ODEs along the forward untangled space-time no-flow Lagrangian trajectories. Due to the no-flow framework, there is no need to compute the eigenvalues (exact or approximate values), and in fact there is no need to construct the Jacobian matrix of the hyperbolic flux functions, and thus giving rise to an effective weak CFL-stability condition in the computing practice. We were able to provide a convergence proof towards the entropy solution to the scalar problem. In the case of multidimensional hyperbolic systems of conservation laws, we show that the Lagrangian-Eulerian scheme also satisfies the weak version of the positivity principle proposed by P. Lax and X.-D. Liu. We also found a connection between some of the results of A. Bressan, in the context of local existence and continuous dependence for discontinuous ODEs and the no-flow curves (now viewed as a forward vector field with locally bounded variation). We present numerical computations for nontrivial (local and nonlocal) hyperbolic problems, as such compressible Euler flows with positivity of the density, the Orszag-Tang problem, which is well-known to satisfy the notable involution-constrained partial differential equation div B = 0, a nonstrictly hyperbolic three-phase flow system in porous media with a resonance point, and the classical 3 by 3 shallow-water system (with and without discontinuous bottom topography). We will also briefly present some numerical results in the context of high-performance parallel computing via a MPI environment.

About Eduardo Cardoso de Abreu

Eduardo Abreu has been a Professor Applied Mathematics with an emphasis on the interaction between mathematical modeling, mathematical and numerical analysis and computer simulations at State University of Campinas commonly called Unicamp, since 2011. He studied Computational Modeling & Applied Mathematics at State University of Rio de Janeiro (UERJ), and obtained master and doctoral degrees at the same university in 2003 and 2007, respectively, receiving the Best Thesis from the Brazilian Society of Computational and Applied Mathematics (2007) & 1st Prize for innovative technologies by Petrobras & CNPq (2005) (the Brazilian National Science Foundation). His postdoctoral (2008) CNPq Young Investigator and Research training (2009-2011) were at IMPA-Institute for Pure and Applied Mathematics in Brazil on applied topics for hyperbolic problems in fluid dynamics. EA has acted as PI's within academia grants from the main Brazilian science funding agencies and from industry. EA is involved in supervision of PostDoc, PhD, MSc researchers. Since 2020, E. Abreu is also member of the "Red Iberoamericana de Investigadores en Matemáticas Aplicadas a Datos". Since 2019, EA is Chair of the Brazil InterPore Chapter and since 2023 is Chair of the Interpore National Chapters Committee. EA was awarded the 2021 Academic Recognition Award "Zeferino Vaz", the most prestigious distinction given by Unicamp for his research excellence and outstanding academic achievements. EA is the recipient of CNPq Grant Awards (from the Brazilian NSF) and currently is leading the project [Mar/2024 - Feb/2028] "Numerical analysis, discretization of discontinuous ODEs/PDEs flows and multiscale irregular fields". EA is also a member of the Unicamp Council since 2023 and also Coordinator elected (June/2023 to May/2027) of the Excellence Graduate Program in Applied Mathematics in the Institute of Mathematics, Statistics and Scientific Computing at Unicamp. For further details, please see https://www.ime.unicamp.br/~eabreu/

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