Past

Rapidly oscillating problems, whether differential equations or

integrals, ubiquitous in applications, are allegedly difficult to

compute. In this talk we will endeavour to persuade the audience that

this is false: high oscillation, properly understood, is good for

computation! We describe methods for differential equations, based on

Magnus and Neumann expansions of modified systems, whose efficacy

improves in the presence of high oscillation. Likewise, we analyse

generalised Filon quadrature methods, showing that also their error

sharply decreases as the oscillation becomes more rapid.

In many applications of interest, such as the conformational

dynamics of molecules, large deterministic systems can exhibit

stochastic behaviour in a relative small number of coarse-grained

variables. This kind of dimension reduction, from a large deterministic

system to a smaller stochastic one, can be very useful in understanding

the problem. Whilst the subject of statistical mechanics provides

a wealth of explicit examples where stochastic models for coarse

variables can be found analytically, it is frequently the case

that applications of interest are not amenable to analytic

dimension reduction. It is hence of interest to pursue computational

algorithms for such dimension reduction. This talk will be devoted

to describing recent work on parameter estimation aimed at

problems arising in this context.

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Joint work with Raz Kupferman (Jerusalem) and Petter Wiberg (Warwick)