On the maximum of sums of random variables and the supremum functional for stable processes

Abstract

Let X_i, i = 1, 2, 3, … be a sequence of independent and identically distributed random variables which belong to the domain of attraction of a stable law of index a. Write S₀= 0, S_n = Σ _i=1ⁿX_i, n ≧ 1, and M_n = max_{0 ≦ k ≦ n}S_k. In the case where the X_i are such that Σ₁^∞n⁻¹Pr(S_n > 0) < ∞, we have lim_n→∞M_n = M which is finite with probability one, while in the case where Σ₁^∞n⁻¹Pr(S_n < 0) < ∞, a limit theorem for M_n has been obtained by Heyde [9]. The techniques used in [9], however, break down in the case Σ₁^∞n⁻¹Pr(S_n < 0) < ∞, Σ₁^∞n⁻¹Pr(S_n > 0) < ∞ (the case of oscillation of the random walk generated by the S_n) and the only results available deal with the case α = 2 (Erdos and Kac [5]) and the case where the X_i themselves have a symmetric stable distribution (Darling [4]). In this paper we obtain a general limit theorem for M_n in the case of oscillation.