COOKIES: By using this website you agree that we can place Google Analytics Cookies on your device for performance monitoring. |

University of Cambridge > Talks.cam > Isaac Newton Institute Seminar Series > Extended Poisson-Kac theory: A unifying framework for stochastic processes with finite propagation velocity

## Extended Poisson-Kac theory: A unifying framework for stochastic processes with finite propagation velocityAdd to your list(s) Download to your calendar using vCal - Rainer Klages (Queen Mary University of London)
- Thursday 24 March 2022, 11:30-12:00
- Seminar Room 1, Newton Institute.
If you have a question about this talk, please contact nobody. FD2W02 - Fractional kinetics, hydrodynamic limits and fractals We present a theoretical framework for stochastic processes possessing physically realistic finite propagation velocity [1]. Our approach is motivated by the theory of Levy walks, which we embed into an extension of conventional Poisson-Kac processes. The resulting extended theory employs generalised transition rates to model subtle microscopic dynamics, which reproduces non-trivial spatio-temporal correlations on macroscopic scales. It thus enables the modelling of many different kinds of dynamical features, as is illustrated by three examples. [1] M.Giona, A.Cairoli, R.Klages, arXiv:2009.13434 and PRX (2022), in print This talk is part of the Isaac Newton Institute Seminar Series series. ## This talk is included in these lists:- All CMS events
- Featured lists
- INI info aggregator
- Isaac Newton Institute Seminar Series
- School of Physical Sciences
- Seminar Room 1, Newton Institute
- bld31
Note that ex-directory lists are not shown. |
## Other listsCambridge BSU Lectures in Biomedical Data Science DPMMS Pure Maths Seminar Type the title of a new list here## Other talksStatistics Clinic Summer 2022 II Asymptotic-preserving dynamical low-rank discretization of kinetic plasma models (copy) Striatal circuits underlying sensorimotor functions Alhazen's Perspectiva legacy in science and art Asymptotic behaviour and functional limit theorems for a time changed Wiener process Reynolds stress fluctuation properties in the inertial sublayer of canonical turbulent wall-flows |