| We study the application of saddlepoint approximations to statistical inference when the moment generating function (MGF) of the distribution of interest is an explicit or an implicit function of the MGF of another random variable which is assumed to be observed. In other words, let W (s) be the MGF of the random variable W of interest. We study the case when W (s) = h{ G (s); lambda}, where G (s) is an MGF of G for which a random sample can be obtained, and h is a smooth function. If G&d4; (s) estimates G (s), then W&d4; s=h&cubl0; G&d4;s ;l&d4; &cubr0; estimates W (s). Generally, it can be shown that W&d4; (s) converges to W (s) by the strong law of large numbers, which implies that Fˆ (t), the cumulative distribution function (CDF) corresponding to W&d4; (s), converges to F (t), the CDF of W, almost surely. If we set W&d4;* s =h&cubl0;G&d4; *s ;l&d4;* &cubr0; , where G&d4;* (s) and l&d4;* are the empirical MGF and the estimator of lambda from bootstrapping, the corresponding CDF Fˆ* (t) can be used to construct the confidence band of F (t).;In this dissertation, we show that the saddlepoint inversion of W&d4; (s) is not only fast, reliable, stable, and accurate enough for a general statistical inference, but also easy to use without deep knowledge of the probability theory regarding the stochastic process of interest.;For the first part, we consider nonparametric estimation of the density and the CDF of the stationary waiting times W and Wq of an M/G/1 queue. These estimates are computed using saddlepoint inversion of W&d4; (s) determined from the Pollaczek-Khinchin formula. Our saddlepoint estimation is compared with estimators based on other approximations, including the Cramer-Lundberg approximation.;For the second part, we consider the saddlepoint approximation for the busy period distribution FB (t) in a M/G/1 queue. The busy period B is the first passage time for the queueing system to pass from an initial arrival (1 in the system) to 0 in the system. If B (s) is the MGF of B, then B (s) is an implicitly defined function of G (s) and lambda, the inter-arrival rate, through the well-known Kendall-Takacs functional equation. As in the first part, we show that the saddlepoint approximation can be used to obtain FˆB (t), the CDF corresponding to B&d4; (s) and simulation results show that confidence bands of FB (t) based on bootstrapping perform well. |
