The stochastic variational approach for geophysical fluid dynamics was
introduced by Holm (Proc Roy Soc A, 2015) as a framework for deriving
stochastic parameterisations for unresolved scales. The key feature of
transport noise is that it respects the Kelvin circulation theorem. This paper
applies the variational stochastic parameterisation in a two-layer
quasi-geostrophic model for a $\beta$-plane channel flow configuration. The
parameterisation is tested by comparing it with a deterministic high resolution
eddy-resolving solution that has reached statistical equilibrium. We describe a
stochastic time-stepping scheme for the two-layer model and discuss its
consistency in time. Then we describe a procedure for estimating the stochastic
forcing to approximate unresolved components using data from the high
resolution deterministic simulation. We compare an ensemble of stochastic
solutions at lower resolution with the numerical solution of the deterministic
model. These computations quantify the uncertainty of the coarse grid
computation relative to the fine grid computation. The results show that the
proposed parameterisation is efficient and effective for both homogeneous and
heterogeneous flows, and they lay a solid foundation for data assimilation.
@article{1802.05711,
author = {Cotter, Colin and Crisan, Dan and Holm, Darryl D. and Pan, Wei and Shevchenko, Igor},
title = {Modelling uncertainty using circulation-preserving stochastic transport
noise in a 2-layer quasi-geostrophic model},
journal = {arXiv},
volume = {2018},
number = {0},
year = {2018},
language = {en},
url = {http://dml.mathdoc.fr/item/1802.05711}
}
Cotter, Colin; Crisan, Dan; Holm, Darryl D.; Pan, Wei; Shevchenko, Igor. Modelling uncertainty using circulation-preserving stochastic transport
noise in a 2-layer quasi-geostrophic model. arXiv, Tome 2018 (2018) no. 0, . http://gdmltest.u-ga.fr/item/1802.05711/