Second quantization for classical nonlinear dynamics

Abstract

Using techniques from many-body quantum theory, we propose a framework for representing the evolution of observables of measure-preserving ergodic flows through infinite-dimensional rotation systems on tori. This approach is based on a class of weighted Fock spaces Fw( Hτ) generated by a 1-parameter family of reproducing kernel Hilbert spaces Hτ, and endowed with commutative Banach algebra structure under the symmetric tensor product using a subconvolutive weight w. We describe the construction of the spaces Fw( Hτ) and show that their Banach algebra spectra, σ(Fw( Hτ)), decompose into a family of tori of potentially infinite dimension. Spectrally consistent unitary approximations Utτ of the Koopman operator acting on Hτ are then lifted to rotation systems on these tori akin to the topological models of ergodic systems with pure point spectra in the Halmos--von Neumann theorem. Our scheme also employs a procedure for representing observables of the original system by polynomial functions on finite-dimensional tori in σ(Fw( Hτ)) of arbitrarily large degree, with coefficients determined from pointwise products of eigenfunctions of Utτ. This leads to models for the Koopman evolution of observables on L2 built from tensor products of finite collections of approximate Koopman eigenfunctions. Numerically, the scheme is amenable to consistent data-driven implementation using kernel methods. We illustrate it with applications to Stepanoff flows on the 2-torus and the Lorenz 63 system. Connections with quantum computing are also discussed.