Hostname: page-component-8448b6f56d-sxzjt Total loading time: 0 Render date: 2024-04-23T20:09:10.465Z Has data issue: false hasContentIssue false
  • English
  • Français

COMPARISON OF APPROXIMATIONS FOR COMPOUND POISSON PROCESSES

Published online by Cambridge University Press:  25 June 2015

Raffaello Seri  and
Christine Choirat
Raffaello Seri*
Affiliation:
Dipartimento di Economia, Università degli Studi dell'Insubria, Via Monte Generoso 71, 21100 Varese, Italy
Christine Choirat
Affiliation:
IQSS Harvard University, 1737 Cambridge Street, CGIS Knafel Building, Cambridge, MA 02138, USA E-Mail: cchoirat@iq.harvard.edu
*
E-Mail: raffaello.seri@uninsubria.it
Get access Rights & Permissions [Opens in a new window]

Abstract

In this paper, we compare the error in several approximation methods for the cumulative aggregate claim distribution customarily used in the collective model of insurance theory. In this model, it is usually supposed that a portfolio is at risk for a time period of length t. The occurrences of the claims are governed by a Poisson process of intensity μ so that the number of claims in [0,t] is a Poisson random variable with parameter λ = μ t. Each single claim is an independent replication of the random variable X, representing the claim severity. The aggregate claim or total claim amount process in [0,t] is represented by the random sum of N independent replications of X, whose cumulative distribution function (cdf) is the object of study. Due to its computational complexity, several approximation methods for this cdf have been proposed. In this paper, we consider 15 approximations put forward in the literature that only use information on the lower order moments of the involved distributions. For each approximation, we consider the difference between the true distribution and the approximating one and we propose to use expansions of this difference related to Edgeworth series to measure their accuracy as λ = μ t diverges to infinity. Using these expansions, several statements concerning the quality of approximations for the distribution of the aggregate claim process can find theoretical support. Other statements can be disproved on the same grounds. Finally, we investigate numerically the accuracy of the proposed formulas.

Keywords

Collective risk theorycompound Poisson processEdgeworth series
Type
Research Article
Information
ASTIN Bulletin: The Journal of the IAA , Volume 45 , Issue 3 , September 2015 , pp. 601 - 637
Copyright
Copyright © Astin Bulletin 2015 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Abramowitz, M. and Stegun, I.A. (1964) Handbook of Mathematical Functions with Formulas, Graphs, and Mathematical Tables, National Bureau of Standards Applied Mathematics Series, vol. 55. Washington, DC: U.S. Government Printing Office.Google Scholar
Babu, G.J., Singh, K. and Yang, Y. (2003) Edgeworth expansions for compound Poisson processes and the bootstrap. Annals of the Institute of Statistical Mathematics, 55, 8394.CrossRefGoogle Scholar
Bartlett, D.K. (1965) Excess ratio distribution in risk theory. Transactions of the Society of Actuaries, XVII, 435463.Google Scholar
Beard, R.E., Pentikäinen, T. and Pesonen, E. (1990) Risk Theory: The Stochastic Basis of Insurance. London: Chapman and Hall.Google Scholar
Beekman, J.A. (1969) A ruin function approximation. Transactions of the Society of Actuaries, XXI, 4148.Google Scholar
Berger, G. (1972) Integration of the normal power approximation. ASTIN Bulletin, 7, 9096.CrossRefGoogle Scholar
Bohman, H. and Esscher, F. (1963a) Studies in risk theory with numerical illustrations concerning distribution functions and stop-loss premiums. Skandinavisk Aktuarietidskrift, 46, 173225.Google Scholar
Bohman, H. and Esscher, F. (1963b) Studies in risk theory with numerical illustrations concerning distribution functions and stop-loss premiums. Skandinavisk Aktuarietidskrift, 46, 140.Google Scholar
Bowers, N.L. (1966) Expansion of probability density functions as a sum of gamma densities with applications to risk theory. Transactions of the Society of Actuaries, XVIII, 125147.Google Scholar
Bowers, N.L. (1967) An approximation to the distribution of annuity costs. Transactions of the Society of Actuaries, XIX, 295309.Google Scholar
Brockett, P.L. (1983) On the misuse of the central limit theorem in some risk calculations. The Journal of Risk and Insurance, 50, 727731.CrossRefGoogle Scholar
Buckley, M.J. and Eagleson, G.K. (1988) An approximation to the distribution of quadratic forms in normal random variables. Australian Journal of Statistics, 30A, 150159.CrossRefGoogle Scholar
Bühlmann, H. (1974) Book review of “Two stochastic processes, by J. A. Beekman. Published by Almqvist & Wiksell, Stockholm.” ASTIN Bulletin, 8, 131132.CrossRefGoogle Scholar
Chaubey, Y.P., Garrido, J. and Trudeau, S. (1998) On the computation of aggregate claims distributions: some new approximations. Insurance: Mathematics and Economics, 23, 215230.Google Scholar
Choirat, C. and Seri, R. (2013) Computational aspects of Cui-Freeden statistics for equidistribution on the sphere. Mathematics of Computation, 82, 21372156.CrossRefGoogle Scholar
Cramér, H. (1946) Mathematical Models of Statistics. Princeton, NJ: Princeton University Press.Google Scholar
Cramér, H. (1955) Collective Risk Theory: A Survey of the Theory from the Point of View of the Theory of Stochastic Processes. Reprinted from the Jubilee Volume of Försäkringsaktiebolaget Skandia. Stockholm: Skandia Insurance Company.Google Scholar
DasGupta, A. (2008) Asymptotic Theory of Statistics and Probability. Springer Texts in Statistics. New York, NY: Springer.Google Scholar
Embrechts, P. and Frei, M. (2009) Panjer recursion versus FFT for compound distributions. Mathematical Methods of Operations Research, 69, 497508.CrossRefGoogle Scholar
Feller, W. (1971) An Introduction to Probability Theory and its Applications. Vol II. 2nd ed. Wiley Series in Probability and Mathematical Statistics. New York, NY: John Wiley and Sons, Inc.Google Scholar
Fisher, R.A. (1928) Statistical Methods for Research Workers, 2nd ed. Biological methods and manuals No. 5. Edinburgh: Oliver and Boyd.Google Scholar
Gendron, M. and Crepeau, H. (1989) On the computation of the aggregate claim distribution when individual claims are inverse Gaussian. Insurance: Mathematics and Economics, 8, 251258.Google Scholar
Grübel, R. and Hermesmeier, R. (1999) Computation of compound distributions I: Aliasing errors and exponential tilting. ASTIN Bulletin, 29, 197214.CrossRefGoogle Scholar
Grübel, R. and Hermesmeier, R. (2000) Computation of compound distributions II: Discretization errors and Richardson extrapolation. ASTIN Bulletin, 30, 309331.CrossRefGoogle Scholar
Gut, A. (2005) Probability: A Graduate Course. Springer Texts in Statistics. New York, NY: Springer.Google Scholar
Haldane, J.B.S. (1938) The approximate normalization of a class of frequency distributions. Biometrika, 29, 392404.CrossRefGoogle Scholar
Hall, P. (1983) Chi squared approximations to the distribution of a sum of independent random variables. Annals of Probability, 11, 10281036.CrossRefGoogle Scholar
Hall, P. (1992) The Bootstrap and Edgeworth Expansion. Springer Series in Statistics. New York: Springer-Verlag.CrossRefGoogle Scholar
Hardy, M.R. (2004) Approximating the aggregate claims distribution. In Encyclopedia of Actuarial Science, pp. 7686. New York, NY: John Wiley and Sons.Google Scholar
Heilmann, W.-R. (1988) Fundamentals of Risk Theory. Karlsruhe: Verlag Versicherungs wirtschaft.Google Scholar
Hill, G.W. and Davis, A.W. (1968) Generalized asymptotic expansions of Cornish-Fisher type. Annals of Mathematical Statistics, 39, 12641273.CrossRefGoogle Scholar
Hipp, C. (1985) Asymptotic expansions in the central limit theorem for compound and Markov processes. Zeitschrift für Wahrscheinlichkeitstheorie und verwandte Gebiete, 69, 361385.CrossRefGoogle Scholar
Hovinen, E. (1969) Procedures and basic statistics to be used in magnitude control of equalisation reserves in Finland. ASTIN Bulletin, 5, 227238.CrossRefGoogle Scholar
Kauppi, L. and Ojantakanen, P. (1969) Approximations of the generalised Poisson function. ASTIN Bulletin, 5, 213228.CrossRefGoogle Scholar
Kolassa, J.E. (2006) Series Approximation Methods in Statistics, 3rd ed. Lecture Notes in Statistics, vol. 88. New York, NY: Springer.Google Scholar
Lee, S.C.K. and Lin, X.S. (2010) Modeling and evaluating insurance losses via mixtures of Erlang distributions. North American Actuarial Journal, 14, 107130.CrossRefGoogle Scholar
Lee, Y.-S. and Lee, M.C. (1992) On the derivation and computation of the Cornish-Fisher expansion. Australian Journal of Statistics, 34, 443450.CrossRefGoogle Scholar
Marsh, L.M. (1973) An expansion for the distribution function of a random sum. Journal of Applied Probability, 10, 869874.CrossRefGoogle Scholar
Mikosch, T. (2006) Non-Life Insurance Mathematics: An Introduction with Stochastic Processes. Berlin: Springer Verlag.Google Scholar
Olver, F.W.J., Lozier, D.W., Boisvert, R. F. and Clark, C.W. ed. (2010) NIST Handbook of Mathematical Functions. U.S. Department of Commerce National Institute of Standards and Technology, Washington, DC.Google Scholar
Papush, D.E., Patrik, G.S. and Podgaits, F. (2001) Approximations of the aggregate loss distribution. Casualty Actuarial Society Forum, Winter, 175186.Google Scholar
Pentikäinen, T. (1977) On the approximation of the total amount of claims. ASTIN Bulletin, 9, 281289.CrossRefGoogle Scholar
Pentikäinen, T. (1987) Approximative evaluation of the distribution function of aggregate claims. ASTIN Bulletin, 17, 1539.CrossRefGoogle Scholar
Pesonen, E. (1969a) Computation of the Poisson process by means of divergent series. Skandinavisk Aktuarietidskrift, Suppl. 3, 2533.Google Scholar
Pesonen, E. (1969b) NP-approximation of risk processes. Skandinavisk Aktuarietidskrift, Suppl. 3, 6369.Google Scholar
Pfenninger, F. (1974) Eine neue Methode zur Berechnung der Ruinwahrscheinlichkeit mittels Laguerre-Entwicklung. Blätter der Deutschen Gesellschaft für Versicherungsmathematik, 11, 491532.Google Scholar
Philipson, C. (1968) A review of the collective theory of risk. Skandinavisk Aktuarietidskrift, 1–2, 4568.Google Scholar
Ramsay, C.M. (1991) A note of the normal power approximation. ASTIN Bulletin, 21, 147150.CrossRefGoogle Scholar
Reijnen, R., Albers, W. and Kallenberg, W.C.M. (2005) Approximations for stop-loss reinsurance premiums. Insurance: Mathematics and Economics, 36, 237250.Google Scholar
Seal, H.L. (1975/76) A note on the use of Laguerre polynomials in the inversion of Laplace transforms. Blätter der Deutschen Gesellschaft für Versicherungsmathematik, 12, 131134.Google Scholar
Seal, H.L. (1977) Approximations to risk theory's F(x,t) by means of the gamma distribution. ASTIN Bulletin, 9, 213218.CrossRefGoogle Scholar
Skovgaard, I.M. (1981) Transformation of an Edgeworth expansion by a sequence of smooth functions. Scandinavian Journal of Statistics, 8, 207217.Google Scholar
Taylor, G.C. (1977) Concerning the use of Laguerre polynomials for inversion of Laplace transforms in risk theory. Blätter der Deutschen Gesellschaft für Versicherungsmathematik, 13, 8592.Google Scholar
Thompson, P. (1969) The standard deviation of excess losses. Transactions of the Society of Actuaries, XIX, 267272.Google Scholar
Tricomi, F. G. and Erdélyi, A. (1951) The asymptotic expansion of a ratio of gamma functions. Pacific Journal of Mathematics, 1, 133142.CrossRefGoogle Scholar
von Chossy, R. and Rappl, G. (1983) Some approximation methods for the distribution of random sums. Insurance: Mathematics and Economics, 2, 251270.Google Scholar
Whittaker, E.T. and Watson, G.N. (1996) A Course of Modern Analysis. Cambridge Mathematical Library. Reprint of the fourth (1927) edition. Cambridge: Cambridge University Press.CrossRefGoogle Scholar
Wilson, E.B. and Hilferty, M.M. (1931) The distribution of chi-square. Proceedings of the National Academy of Sciences, 17, 684688.CrossRefGoogle ScholarPubMed