Location
Dates
Presentation
The aim of the school is to introduce participants to several numerical techniques and analysis in Partial Differential Equations (PDEs). The topics to be treated will vary from standard contemporary schemes to recent advances in the numerical treatment of PDEs and numerical linear algebra techniques. Some of the other topics to be presented during the school are: model order reductions, pde constrained optimal control and inverse problems.
Scientific program is available on the local website of the School: https://sites.google.com/ucc.edu.gh/cimpa-numpde
Official language of the school: English
Administrative and scientific coordinators
Scientific program
Course 1: "advanced course - Parallel-in-time integration has been the focus of intensive research efforts over the past two decades due to the advent of massively parallel computer architectures and the scaling limits of purely spatial parallelization. The course is an introduction to the emerging field of time parallel time integration. ", Martin GANDER (Université de Genève, Switzerland)
Course 2: "advanced course - This course is devoted to inverse problems where the goal is to compute a fast reconstruction of the state of a physical system from available measurement observations and the knowledge of a physical PDE model. Due to their ill-posedness, these problems are often addressed with Bayesian approaches that consist in searching for the most plausible solution using sampling strategies of the posterior density. In view of their high numerical cost, especially in a high dimensional framework, reduced modeling of parametric PDEs has been proposed as a vehicle to reduce complexity and achieve near real time in the reconstructions. The course will give an overview of linear and nonlinear strategies for model reduction, and inverse problems. The concepts may be viewed as exploring alternatives to Bayesian inversion in favor of more deterministic notions of accuracy quantification. ", Olga MULA (EINDHOVEN UNIVERSITY OF TECHNOLOGY, Netherlands)
Course 3: "advanced course - This course deals with the numerical treatment and analysis of Partial differential equations. We will consider advance methods for optimal control problems. We will also consider optimization methods with example of monotonic algorithms. The rest of the course will cover numerical treatment of variational inequalities, finite element method and reduced basis method method.", Julien SALOMON (INRIA, France)
Course 4: "advanced course - These lectures will be devoted to the construction of numerical methods for partial differential equations (PDEs) based on splines. Splines are a ubiquitous tool in numerical analysis, and during this course, after an introduction to their main properties, we will define spline-based approximation techniques for differential problems. Starting from the simple Laplace problems, we will also investigate the approximation of more complex problems, such as the inverse harmonic problem and the Stokes and Maxwell equations. Moreover, if time permits, we will introduce the concept of adaptive approximation and discuss how to design adaptive spline approaches. ", Annalisa BUFFA ( École Polytechnique Fédérale de Lausanne, Switzerland)
Course 5: "advanced course - We introduce the concepts underlying ill-posedness and consider real-life problems leading to illposedness and the numerical techniques required to solve such problems. Particularly, we will consider as example an inverse problem that arises in the management of water resources and pertains to the analysis of surface water pollution by organic matter. ", Faker BEN BELGACEM (UNIVERSITÉ DE TECHNOLOGIE DE COMPIÈGNE, France)
Course 6: "advanced course - Numerical methods have been used to solve the one-dimensional advection-diffusion equation with constant coefficients. This partial differential equation is dissipative but not dispersive. We will study numerical methods applied to both scalar and system advection-diffusion problems.", Joseph Kojo ANSONG (UNIVERSITY OF GHANA, Ghana)
Course 7: "advanced course - We will study numerical methods for elliptic PDEs. Here, we will study finite element methods for Poisson and biharmonic problems. We will consider the analysis of such problems including error estimates. ", Clement BAHI (UNIVERSITE FELIX HOUPHOUET BOIGNY, Côte d'Ivoire)
Course 8: "advanced course - This course will introduce students to solving optimization problems. Because of the wide (and growing) use of optimization in science, engineering, economics, and industry, it is essential for students and practitioners alike to develop an understanding of optimization algorithms. Knowledge of the capabilities and limitations of these algorithms leads to a better understanding of their impact on various applications, and points the way to future research on improving and extending optimization algorithms and software.", Marie POSTEL (Sorbonne Université, France)
Website of the school
How to participate
For registration and application to a CIMPA financial support, follow the instructions given here. https://www.cimpa.info/fr/node/40
Deadline for registration and application: February 21, 2024