On large deviation principles for general random processes

Abstract

Let Z=\Z(t): t∈ R\ be a stochastic process with trajectories in space D ( R). It is assumed that there exists an essentially smooth function A: R (-∞, ∞] such that, for all α ∈ R, μ∈ dom\, A, one has equation* 1T E ( eμ (Z(T)-α T) |Z(s), \ s 0 ) = A(μ) +o(1) equation* uniformly on the event C(T):=\|Z(0)/T - α |< ηT \ , where ηT 0 as T∞. Under this condition, a uniform conditional local large deviation principle (l.l.d.p.) is established: for any fixed α, β∈ R and a positive function ηT=o(1), for T 0 sufficiently slowly as T∞, one has equation* T∞1T P ( Z(T)/T-α ∈ (β-T, β +T) | Z(s), \ s 0) = - D(β ) equation* uniformly on C(T), where D is the Legendre transform of the function A. This result is used to establish a conditional l.l.d.p. for the finite-dimen\-sional distributions of the process \ zT(s) = Z(sT)/T: s∈ [0,1]\. Under additional conditions on the magnitude of oscillations of the trajectories zT, a functional l.l.d.p. is obtained for the asymptotics of P (zT∈ (f)_T) as T∞, where f∈ D(0,1), (f) is the -neighborhood of f in the space D(0,1) with respect to the uniform metric, and T 0 sufficiently slowly. The obtained results can be extended to a more general triangular array scheme where the process itself Z=Z(T) also depends on the parameter T.