Academics
follow us
  • Linkedin
  • Twitter
  • Facebook
  • Youtube
  • Instagram
Feedback

Guest talk by Prof. Prof. Patrick E. Farrell, University of Oxford

he department of Mathematics invites you to an online talk by Prof. Patrick EFarrell, University of Oxford on 16.10.24 at 05.00 pm.
The details of the talk and a short biodata of the speaker is given below. 
Prof. Patrick EFarrell is a Professor of Numerical Analysis at the Mathematical Institute, University of Oxford, focusing on 
the numerical solution of partial differential equations (PDEs) with applications in physics and chemistry. His research 
includes adaptive finite element discretizations, Adjoints and PDE-constrained optimization problems, and Bifurcation 
analysis of nonlinear PDEs. He has received numerous prestigious awards, including the LMS Whitehead Prize, the 
Broyden Prize in Optimization, the Wilkinson Prize for Numerical Software, and the IMA Leslie Fox Prize in Numerical 
Analysis. A core developer of the Firedrake projects, he actively contributes to advancing scientific computing.
 
 
Title: Designing conservative and accurately dissipative numerical integrators in time


Abstract: Numerical methods for the simulation of transient systems with structure-preserving properties are 
known to exhibit greater accuracy and physical reliability, in particular over long durations. 
These schemes are often built on powerful geometric ideas for broad classes of problems, such 
as Hamiltonian or reversible systems. However, there remain difficulties in devising 
higher-order-in-time structure-preserving discretizations for nonlinear problems, and in 
conserving non-polynomial invariants.

In this work we propose a new, general framework for the construction of structure-preserving 
timesteppers via finite elements in time and the systematic introduction of auxiliary variables. 
The framework reduces to Gauss methods where those are structure-preserving, but extends 
to generate arbitrary-order structure-preserving schemes for nonlinear problems, and allows 
for the construction of schemes that conserve multiple higher-order invariants. We demonstrate 
the ideas by devising novel schemes that exactly conserve all known invariants of the Kepler 
and Kovalevskaya problems, arbitrary-order schemes for the compressible Navier–Stokes 
equations that conserve mass, momentum, and energy, and provably dissipate entropy, and 
multi-conservative schemes for the Benjamin-Bona-Mahony equation.
 
 
Date and time: Wednesday, October 16, 2024, 5:00 PM (IST) 

Prof. Patrick E. Farrell, Full Professor of Numerical Analysis at 

the University of Oxford