Oberwolfach Reports


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Volume 13, Issue 1, 2016, pp. 297–340
DOI: 10.4171/OWR/2016/7

Published online: 2016-10-11

Mini-Workshop: Applied Koopmanism

Didier Henrion, Igor Mezić[1] and Mihai Putinar[2]

(1) University of California, Santa Barbara, USA
(2) University of California, Santa Barbara, USA

Koopman and Perron–Frobenius operators are linear operators that encapsulate dynamics of nonlinear dynamical systems without loss of information. This is accomplished by embedding the dynamics into a larger infinite-dimensional space where the focus of study is shifted from trajectory curves to measurement functions evaluated along trajectories and densities of trajectories evolving in time. Operator-theoretic approach to dynamics shares many features with an optimization technique: the Lasserre moment–sums-of-squares (SOS) hierarchies, which was developed for numerically solving non-convex optimization problems with semialgebraic data. This technique embeds the optimization problem into a larger primal semidefinite programming (SDP) problem consisting of measure optimization over the set of globally optimal solutions, where measures are manipulated through their truncated moment sequences. The dual SDP problem uses SOS representations to certify bounds on the global optimum. This workshop highlighted the common threads between the operator-theoretic dynamical systems and moment–SOS hierarchies in optimization and explored the future directions where the synergy of the two techniques could yield results in fluid dynamics, control theory, optimization, and spectral theory.

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Henrion Didier, Mezić Igor, Putinar Mihai: Mini-Workshop: Applied Koopmanism. Oberwolfach Rep. 13 (2016), 297-340. doi: 10.4171/OWR/2016/7