Quantitative propagation of chaos of McKean-Vlasov equations via the master equation
dc.contributor.advisor
Szpruch, Lukasz
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dc.contributor.advisor
Breit, Dominic
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dc.contributor.author
Tse, Alvin Tsz Ho
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dc.date.accessioned
2019-09-06T10:10:51Z
dc.date.available
2019-09-06T10:10:51Z
dc.date.issued
2019-11-28
dc.description.abstract
McKean-Vlasov stochastic differential equations (MVSDEs) are ubiquitous in kinetic theory
and in controlled games with a large number of players. They have been intensively studied
since McKean, as they pave a way to probabilistic representations for many important nonlinear/
nonlocal PDEs. Classically, their simulation involves using standard particle systems,
which replace the evolving law in MVSDEs by the evolving empirical measure of the particles.
However, this type of simulation is costly in terms of computational complexity, due to the
interaction between the particles.
Apart from classical techniques in stochastic analysis, the approach in this thesis relies
heavily on the calculus on Wasserstein space, presented by P. Lions in his course at Collège de
France. An important object in our study, is a PDE written on the product space of the space
of time horizon and the Wasserstein space, which is a generalisation of the classical Feynman-
Kac PDE. This PDE, namely the master equation, provides a new insight into the study of
mean-field limits of particles and consequently allows us to solve many problems on MVSDEs
that are very difficult/impossible to solve by classical techniques.
The layout of the thesis is as follows. We start by a recap on classical results of MVSDEs
(Chapter 2), followed by a full exposition of Wasserstein calculus on the results that we need
(Chapter 3). Chapters 4 and 5 propose approximating systems to MVSDEs (as alternatives to
the classical particle system) via Romberg extrapolation and Antithetic Multi-level Monte-Carlo
estimation respectively, which are less costly in terms of computational complexity. Finally, in
Chapter 6, we explore the converse: given a standard particle system, we hope to find an
alternative mean-field limit that gives a better approximation to the standard particle system.
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dc.identifier.uri
http://hdl.handle.net/1842/36096
dc.language.iso
en
dc.publisher
The University of Edinburgh
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dc.relation.hasversion
Jean-François Chassagneux, Lukasz Szpruch, and Alvin Tse. Weak quantitative propagation of chaos via differential calculus on the space of measures. arXiv preprint arXiv:1901.02556, 2019.
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dc.relation.hasversion
Łukasz Szpruch and Alvin Tse. Antithetic multilevel particle system sampling method for Mckean-Vlasov SDEs. arXiv preprint arXiv:1903.07063, 2019.
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dc.subject
propagation of chaos
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dc.subject
McKean-Vlasov equations
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dc.subject
stochastic analysis
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dc.subject
partial differential equations
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dc.subject
optimal transport
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dc.title
Quantitative propagation of chaos of McKean-Vlasov equations via the master equation
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dc.type
Thesis or Dissertation
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dc.type.qualificationlevel
Doctoral
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dc.type.qualificationname
PhD Doctor of Philosophy
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