2 research outputs found
Using Machine Learning for Model Physics: an Overview
In the overview, a generic mathematical object (mapping) is introduced, and
its relation to model physics parameterization is explained. Machine learning
(ML) tools that can be used to emulate and/or approximate mappings are
introduced. Applications of ML to emulate existing parameterizations, to
develop new parameterizations, to ensure physical constraints, and control the
accuracy of developed applications are described. Some ML approaches that allow
developers to go beyond the standard parameterization paradigm are discussed.Comment: 50 pages, 3 figures, 1 tabl
Nonlinear Dimensionality Reduction Methods in Climate Data Analysis
Linear dimensionality reduction techniques, notably principal component
analysis, are widely used in climate data analysis as a means to aid in the
interpretation of datasets of high dimensionality. These linear methods may not
be appropriate for the analysis of data arising from nonlinear processes
occurring in the climate system. Numerous techniques for nonlinear
dimensionality reduction have been developed recently that may provide a
potentially useful tool for the identification of low-dimensional manifolds in
climate data sets arising from nonlinear dynamics. In this thesis I apply three
such techniques to the study of El Nino/Southern Oscillation variability in
tropical Pacific sea surface temperatures and thermocline depth, comparing
observational data with simulations from coupled atmosphere-ocean general
circulation models from the CMIP3 multi-model ensemble.
The three methods used here are a nonlinear principal component analysis
(NLPCA) approach based on neural networks, the Isomap isometric mapping
algorithm, and Hessian locally linear embedding. I use these three methods to
examine El Nino variability in the different data sets and assess the
suitability of these nonlinear dimensionality reduction approaches for climate
data analysis.
I conclude that although, for the application presented here, analysis using
NLPCA, Isomap and Hessian locally linear embedding does not provide additional
information beyond that already provided by principal component analysis, these
methods are effective tools for exploratory data analysis.Comment: 273 pages, 76 figures; University of Bristol Ph.D. thesis; version
with high-resolution figures available from
http://www.skybluetrades.net/thesis/ian-ross-thesis.pdf (52Mb download