Source: Ann. Statist. Volume 32, Number 6
(2004), 2712-2730.
We consider the problem of approximating the moment generating function (MGF) of a truncated random variable in terms of the MGF of the underlying (i.e., untruncated) random variable. The purpose of approximating the MGF is to enable the application of saddlepoint approximations to certain distributions determined by truncated random variables. Two important statistical applications are the following: the approximation of certain multivariate cumulative distribution functions; and the approximation of passage time distributions in ion channel models which incorporate time interval omission. We derive two types of representation for the MGF of a truncated random variable. One of these representations is obtained by exponential tilting. The second type of representation, which has two versions, is referred to as an exponential convolution representation. Each representation motivates a different approximation. It turns out that each of the three approximations is extremely accurate in those cases “to which it is suited.” Moreover, there is a simple rule of thumb for deciding which approximation to use in a given case, and if this rule is followed, then our numerical and theoretical results indicate that the resulting approximation will be extremely accurate.
References
Ball, F. G., Butler, R. W. and Wood, A. T. A. (2004). Saddlepoint approximations in ion channel models. Unpublished manuscript.
Ball, F. G., Milne, R. K. and Yeo, G. F. (1991). Aggregated semi-Markov processes incorporating time interval omission. Adv. in Appl. Probab. 23 772--797.
Barndorff-Nielsen, O. E. and Cox, D. R. (1989). Asymptotic Techniques for Use in Statistics. Chapman and Hall, London.
Barndorff-Nielsen, O. E. and Cox, D. R. (1994). Inference and Asymptotics. Chapman and Hall, London.
Butler, R. W. (2000). Reliabilities for feedback systems and their saddlepoint approximation. Statist. Sci. 15 279--298.
Butler, R. W. (2004). An Introduction to Saddlepoint Methods. Book in preparation.
Butler, R. W. and Sutton, R. K. (1998). Saddlepoint approximation for multivariate cumulative distribution functions and probability computations in sampling theory and outlier testing. J. Amer. Statist. Soc. 93 596--604.
Butler, R. W. and Wood, A. T. A. (2002a). Laplace approximations for hypergeometric functions with matrix argument. Ann. Statist. 30 1155--1177.
Butler, R. W. and Wood, A. T. A. (2002b). Saddlepoint approximation for moment generating functions of truncated random variables. Research report, Division of Statistics, Univ. Nottingham.
Chung, K. L. (1974). A Course in Probability Theory, 2nd ed. Academic Press, New York.
Daniels, H. E. (1954). Saddlepoint approximations in statistics. Ann. Math. Stat. 25 631--650.
Mathematical Reviews (MathSciNet):
MR66602
Daniels, H. E. (1987). Tail probability approximations. Internat. Statist. Rev. 55 37--48.
Mathematical Reviews (MathSciNet):
MR962940
Daniels, H. E. and Young, G. A. (1991). Saddlepoint approximation for the Studentized mean, with an application to the bootstrap. Biometrika 78 169--179.
DiCiccio, T. J. and Martin, M. A. (1991). Approximations of marginal tail probabilities for a class of smooth functions with applications to Bayesian and conditional inference. Biometrika 78 891--902.
Fraser, D. A. S., Reid, N. and Wong, A. (1991). Exponential linear models: A two-pass procedure for saddlepoint approximation. J. Roy. Statist. Soc. Ser. B 53 483--492.
Jensen, J. L. (1995). Saddlepoint Approximations. Oxford Univ. Press.
Jing, B.-Y. and Robinson, J. (1994). Saddlepoint approximations for marginal and conditional probabilities of transformed random variables. Ann. Statist. 22 1115--1132.
Kawata, T. (1972). Fourier Analysis in Probability Theory. Academic Press, New York.
Mathematical Reviews (MathSciNet):
MR464353
Lugannani, R. and Rice, S. (1980). Saddlepoint approximation for the distribution of the sum of independent random variables. Adv. in Appl. Probab. 12 475--490.
Mathematical Reviews (MathSciNet):
MR569438
Reid, N. (1988). Saddlepoint methods and statistical inference (with discussion). Statist. Sci. 3 213--238.
Mathematical Reviews (MathSciNet):
MR968390
Skovgaard, I. M. (1987). Saddlepoint expansions for conditional distributions. J. Appl. Probab. 24 875--887.
Mathematical Reviews (MathSciNet):
MR913828
Temme, N. M. (1982). The uniform asymptotic expansion of a class of integrals related to cumulative distribution functions. SIAM J. Math. Anal. 13 239--253.
Mathematical Reviews (MathSciNet):
MR647123
