Dynamical large deviations of the fractional Ornstein-Uhlenbeck process

Abstract

The fractional Ornstein-Uhleneck (fOU) process is described by the overdamped Langevin equation x(t)+γ x=2 D(t), where (t) is the fractional Gaussian noise with the Hurst exponent 0<H<1. For H≠ 1/2 the fOU process is non-Markovian but Gaussian, and it has either vanishing (for H<1/2), or divergent (for H>1/2) spectral density at zero frequency. For H>1/2, the fOU is long-correlated. Here we study dynamical large deviations of the fOU process and focus on the area An=∫-TT xn(t) dt, n=1,2,… over a long time window 2T. Employing the optimal fluctuation method, we determine the optimal path of the conditioned process, which dominates the large-An tail of the probability distribution of the area, P(An,T) [-S(An,T)]. We uncover a nontrivial phase diagram of scaling behaviors of the optimal paths and of the action S(An 2 an T,T) Tα(H,n) a2/nn on the (H,n) plane. The phase diagram includes three regions: (i) H>1-1/n, where α(H,n)=2-2H, and the optimal paths are delocalized, (ii) n=2 and H≤ 12, where α(H,n)=1, and the optimal paths oscillate with an H-dependent frequency, and (iii) H≤ 1-1/n and n>2, where α(H,n)=2/n, and the optimal paths are strongly localized. We verify our theoretical predictions in large-deviation simulations of the fOU process. By combining the Wang-Landau Monte-Carlo algorithm with the circulant embedding method of generation of stationary Gaussian fields, we were able to measure probability densities as small as 10-170. We also generalize our findings to other stationary Gaussian processes with either diverging, or vanishing spectral density at zero frequency.

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