×
Grize, Yves L.

Applications of statistics in the field of general insurance: an overview. (English) Zbl 07762799

Int. Stat. Rev. 83, No. 1, 135-159 (2015).
Summary: This is an expository paper on applications of statistics in the field of general insurance, also called non-life insurance. Unlike life insurance where advanced statistical techniques have long been part of financial mathematics and actuarial applications, their use is only relatively recent in non-life insurance. The business model of insurance companies, especially those active in non-life insurance, has seen dramatic changes over the last 15 years. The aim of this paper is to convince the readers that especially today non-life insurance is not only an exciting ground to apply existing modern statistical tools but also a fertile environment for new and challenging statistical developments. The activities of an insurance company can be viewed as an industrial process where data management and data analysis play a key role. That is why a fundamental understanding of data-related issues (such as data quality, variability, analysis and correct interpretation) is so essential to the insurance business. These are exactly the tasks where professional statisticians excel. Also, a better understanding of the field of general insurance by statisticians will promote fruitful exchanges between actuaries and statisticians, thereby helping to bring actuarial and statistical professional societies closer to each other. Selected examples are used to cover the essential aspects of general insurance, and all of them are based on the author’s experience. The paper concludes with some remarks on the role of statisticians working in general insurance.
{©2014 The Authors. International Statistical Review © 2014 International Statistical Institute}

Cited in 3 Documents

MSC:

62-XX Statistics

Keywords:

general insurance; non-life insurance; actuarial sciences; statistical applications; statistics in business and industry; business analytics; business intelligence
Cite Review PDF
Full Text: DOI

References:

[1] Allenby, G. M., Arora, N. & Ginter, J. L. (1995). Incorporating prior knowledge into the analysis of conjoint studies. J. Marketing Res.32, 152-162.
[2] Antonio, K. & Zhang, Y. (2013). Linear Mixed Models for Predictive Modelling in Actuarial Science. Available at Social Science Research Network (SSRN): http://ssrn.com/abstract=2381505 or http://dx.doi.org/10.2139/ssrn.2381505. Accessed 28 November 2013. · doi:10.2139/ssrn.2381505
[3] Beirlant, J., Goegebeur, Y., Segers, J. & Jozef Teugels, J. (2004). Statistics of Extremes: Theory and Applications. Chichester, England :Wiley. · Zbl 1070.62036
[4] Boland, P. (2007). Statistical and Probabilistic Methods in Actuarial Sciences. CRC Press, Boca Raton, Florida USA: Chapman & Hall. · Zbl 1124.62069
[5] Bolton, R. J. & Hand, D. J. (2002). Statistical fraud detection: A review. Statist. Sci.17.3, 235-249. · Zbl 1013.62115
[6] Boskov, M. & Verrall, R. J. (1994). Premium rating by geographic area using spatial models. Astin Bull.24, (1), 131-143.
[7] Brockman, M. J. & Wright, T. S. (1992). Statistical motor rating: making efficient use of your data. J. Inst. Actuar.119, 457-543.
[8] Bühlmann, H. (1969). Experience rating and credibility. Astin Bull.5, 157-165.
[9] Bühlmann, H. & Gisler, A. (2005). A Course in Credibility Theory and its Applications. Springer, Berlin‐Heidelberg. · Zbl 1108.91001
[10] Bühlmann, H. & Straub, E. (1970). Glaubwürdigkeit für Schadensätze. Mittl. Ver. Schw. Vers. Math.70, 111-133. · Zbl 0197.46502
[11] Court of Justice of the European Union. (2011). Case C236/09, decision ruled March 1st. 2011. Available at http://www.curia.europa.eu. Accessed 14 January 2014.
[12] Clark, D. R. (2003). LDF curve‐fitting and stochastic reserving:a mximum likeklihood approach . Casualty Actuarial Society Fall‐Forum pp.41-92. Chicago.
[13] Dasu, T. & Johnson, T. (2003). Exploratory Data Mining and Data Cleaning. Hoboken, New‐Jersey USA: Wiley. · Zbl 1027.62002
[14] De Jong, P. & Heller, G. Z. (2008). Generalized Linear Models for Insurance Data. New‐York. · Zbl 1142.91046
[15] Donkers, B., Verhoef, P. C. & deJong, M. (2007). Modeling CLV: A test of competing models in the insurance industry. Quant. Market. Econ.5, 163-190.
[16] Embrechts, P., Klüppelberg, C. & Mikosch, T. (1997). Modelling Extremal Events for Insurance and Finance 1st ed. Berlin‐Heidelberg: Springer. corr. 4th printing. · Zbl 0873.62116
[17] Embrechts, P., McNeil, A. & Straumann, D.. Correlation and dependence in risk management: Properties and pitfalls. In Risk Management: Value at Risk and Beyond. 176-223, Cambridge: Cambridge University Press.
[18] Emms, P. & Haberman, S. (2005). Pricing general insurance using optimal control theory. Astin Bull.35, 427-453. · Zbl 1155.91401
[19] England, P. D. & Verrall, R. J. (2002). Stochastic claims reserving in general insurance. Br. Actuar. J.8/3, 443-518.
[20] Goulet, V. (1998). Principles and application of credibility theory. J. Actuar. Pract.6, 5-62. · Zbl 1071.91513
[21] Haberman, S. & Renshaw, A. E. (1996). Generalized linear models and actuarial science. The Statistician45, 407-436.
[22] Hachemeister, C. A. (1980). A stochastic model for loss reserving. Proceedings of Transactions of the 21st International Congress of Actuaries,Tokyo, pp. 185-194.
[23] Hogg, R. V. & Klugman, S. A. (1984). Loss Distributions. New‐York: Wiley.
[24] Jennings, P. J. (2008). Using Cluster Analysis to Define Geographical Rating Territories. Casualty Actuarial Society, Discussion Paper Program.
[25] Klugman, S. A, Panjer, H. H. & Willmot, G. E. (2012). Loss Models: from Data to Decisions. Hoboken, New‐Jersey USA: Wiley, Society of Actuaries. · Zbl 1272.62002
[26] Kuhfeld, W., Tobias, R. D. & Garratt, M. (1995). Efficient experimental designs with marketing research applications. J. Marketing Res.31, 545-557.
[27] Lemaire, J. (1998). Bonus‐Malus Systems: The European and Asian approach to merit rating. N. Am. Actuar. J.2(1):26-47. · Zbl 1081.91548
[28] Lemaire, J. (1982). Claims provisions in liability insurance. J. Forecast.1, 303-318.
[29] Lenk, P. J., De Sarbo, W. S., Green, P. E. & Young, M. R. (1996). Hierarchical Bayes conjoint analysis: Recovery of partworth heterogeneity from reduced experimental designs. Market. Sci.15, 173-191.
[30] Luce, R. D. & Tukey, J. W. (1964). Simultaneous conjoint measurement: A new type of fundamental measurement. J. Math. Psych.1, 1-17. · Zbl 0166.42201
[31] McFadden, D. L. (1974). Conditional logit analysis of qualitative choice behaviour. In Frontiers in Econometrics, Ed. P.Zarembka (Hrsg.) (ed.), pp. 105-142. New‐York: Academic Press.
[32] Mc Neil, A. & Frey, R. & Embrechts, P. (2005). Quantitative Risk Management. Princeton, New‐Jersey USA: Princeton University Press. · Zbl 1089.91037
[33] Mack, T. (1993). Distribution‐free calculation of the standard error of chain ladder reserves estimates. Astin Bull.23/2, 213-225.
[34] Murphy, K. P., Brockman, M. J. & Lee, P. K. W. (2000). Using generalized liner models to build dynamic pricing systems for personal lines insurance. In CAS Winter 2000 Forum. pp. 107-140. San‐Diego California.
[35] Norberg, R. (2004). Credibility theory. In Encyclopedia of Actuarial Science. New‐York: Wiley.
[36] Ohlsson, E. & Johansson, B. (2010). Non‐life Insurance Pricing with Generalized Linear Models. Berlin‐Heidelberg: EAA Series Springer. · Zbl 1194.91011
[37] Panjer, H. H. (1981). Recursive evaluation of a family of compound distributions. Astin Bull.12, 22-26.
[38] Pinheiro, P. J. R, Silva, J. M. A. & Centeno, M. L. (2003). Bootstrap methodology in claim reserving. J. Risk Insur.70, 701-714.
[39] Reiss, R. D. & Thomas, M. (2007). Statistical Analysis of Extreme Values: with Applications to Insurance, Finance, Hydrology and Other Fields.Birkhäuser. · Zbl 1122.62036
[40] Sacks, J., Welch, W. J., Mitchell, T. J. & Wynn, H. P. (1989). Design and analysis of computer. Experiments. Statist. Sci.4, 409-423. · Zbl 0955.62619
[41] Shapiro, A. F. & Jain, L. C. (2003). Intelligent and Other Computational Techniques in Insurance, Series on Innovative Intelligence Vol 6. Singapore: World Scientific Publishing. · Zbl 1060.91087
[42] Schmidt, K. D. (2006). Methods and models of loss reserving based on run-off triangles: A unifying survey. Casual Actuarial Society Forum Fall. pp. 269-317. Atlanta, USA.
[43] Schmidt, K. D. (2012). A bibliography on loss reserving (permanently updated by the tech. university of Dresden). Available at http://www.math.tu‐dresden.de/sto/schmidt/dsvm/reserve.pdf. Accessed 20 January 2014.
[44] Sterzynski, M. (2003). The European single insurance market: Overview and impact of the liberalization and deregulation processes. Belg. Actuar. Bull.3(1), 42-49.
[45] Taylor, G. (2001). Geographic premium rating by Whittaker spatial smoothing. Astin Bull.31(1), 147-160. · Zbl 1060.91101
[46] Van Westendorp, P. (1976). NSS‐Price Sensitivity Meter (PSM) ‐ A new approach to study consumer perception of price. Proceedings of the ESOMAR Congress. pp. 139-167. Venice Italy.
[47] Wüthrich, M. V. & Merz, M. (2008). Stochastic Claims Reserving Methods in Insurance. Chichester, England: Wiley Finance. · Zbl 1273.91011
[48] Wüthrich, M. V., Bühlmann, H. & Furrer, H. (2010). Market‐Consistent Actuarial Valuation. Berlin‐Heidelberg: Springer. · Zbl 1203.91005
[49] Zhang, Y., Dukiv, V. & Guszcza, J. (2012). A Bayesian non‐linear model for forecasting insurance loss payments. J. R. Statist. Soc. A175 Part 2, 637-656.
This reference list is based on information provided by the publisher or from digital mathematics libraries. Its items are heuristically matched to zbMATH identifiers and may contain data conversion errors. In some cases that data have been complemented/enhanced by data from zbMATH Open. This attempts to reflect the references listed in the original paper as accurately as possible without claiming completeness or a perfect matching.