Large deviations for trajectory observables of diffusion processes in dimension d>1 in the double limit of large time and small diffusion coefficient

Abstract

For diffusion processes in dimension d>1, the statistics of trajectory observables over the time-window [0,T] can be studied via the Feynman-Kac deformations of the Fokker-Planck generator, that can be interpreted as euclidean non-hermitian electromagnetic quantum Hamiltonians. It is then interesting to compare the four regimes corresponding to the time T either finite or large and to the diffusion coefficient D either finite or small. (1) For finite T and finite D, one needs to consider the full time-dependent quantum problem that involves the full spectrum of the Hamiltonian. (2) For large time T + ∞ and finite D, one only needs to consider the ground-state properties of the quantum Hamiltonian to obtain the generating function of rescaled cumulants and to construct the corresponding canonical conditioned processes. (3) For finite T and D 0, one only needs to consider the dominant classical trajectory and its action satisfying the Hamilton-Jacobi equation, as in the semi-classical WKB approximation of quantum mechanics. (4) In the double limit T + ∞ and D 0, the simplifications in the large deviations in TD of trajectory observables can be analyzed via the two orders of limits, i.e. either from the limit D 0 of the ground-state properties of the quantum Hamiltonians of (2), or from the limit of long classical trajectories T +∞ in the semi-classical WKB approximation of (3). This general framework is illustrated in dimension d=2 with rotational invariance.