O. G. Smolyanov, N. N. Shamarov, “Schrödinger quantization of infinite-dimensional Hamiltonian systems with a nonquadratic Hamiltonian function”, Dokl. RAN. Math. Inf. Proc. Upr., 2020, Volume 492,Pages <nobr>65

This article is cited in 11 papers

MATHEMATICS

Schrödinger quantization of infinite-dimensional Hamiltonian systems with a nonquadratic Hamiltonian function

O. G. Smolyanov^ab, N. N. Shamarov^ab

^a Lomonosov Moscow State University, Moscow, Russian Federation
^b Moscow Institute of Physics and Technology (National Research University), Dolgoprudny, Moscow Region, Russian Federation

Abstract: According to a theorem of Andre Weil, there does not exist a standard Lebesgue measure on any infinite-dimensional locally convex space. Because of that, Schrödinger quantization of an infinite-dimensional Hamiltonian system is often defined using a $\sigma$-additive measure, which is not translation-invariant. In the present paper, a completely different approach is applied: we use the generalized Lebesgue measure, which is translation-invariant. In implicit form, such a measure was used in the first paper published by Feynman (1948). In this situation, pseudodifferential operators whose symbols are classical Hamiltonian functions are formally defined as in the finite-dimensional case. In particular, they use unitary Fourier transforms which map functions (on a finite-dimensional space) into functions. Such a definition of the infinite-dimensional unitary Fourier transforms has not been used in the literature.

Keywords: quantization, Schrödinger quantization, generalized Lebesgue measure, infinite-dimensional Hamiltonian systems, Heisenberg algebra, infinite-dimensional pseudodifferential operators.

UDC: 517

Presented: V. V. Kozlov
Received: 29.12.2019
Revised: 29.12.2019
Accepted: 19.03.2020

DOI: 10.31857/S2686954320030200