On necessary and sufficient conditions for the local large deviation principle

Abstract

One says that the local large deviation principle (LLDP) is satisfied for a family of random vectors \ζT\T 0 in Rd, d 1, if there exists a function D: Rd [0,∞], D ∞, such that, for any α∈ Rd, \[ T ∞T-1 P (|ζT -α|<T)= - D(α)\] for T 0 slowly enough. In this paper, we establish necessary and sufficient conditions for the LLDP that are very close to each other. Namely, if the LLDP is satisfied then, for MT∞ slowly enough as T∞, there exists the limit \[ A(μ):= T∞T-1 E (eT μ, ζT; |ζT| MT)∈ (-∞, ∞], μ∈ Rd,\] which is equal to the Legendre--Fenchel transform LD of the rate function D. Conversely, if the above limit A(· ) exists and is an essentially smooth function, then the LLDP is satisfied with the rate function D equal to LA. This "relaxed version" of the G\"artner--Ellis theorem's main condition does not involve the restrictive integrability assumptions from the latter and is most adequate to the nature of the local large deviation problem.