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European Actuarial Journal

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04-06-2019 | Original Research Paper

Heterogeneity in mortality: a survey with an actuarial focus

Author: Ermanno Pitacco

Published in: European Actuarial Journal | Issue 1/2019

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Abstract

Heterogeneity in mortality is due to differences among the individuals, which are caused by various risk factors. Some risk factors are observable while others are unobservable. The set of observable risk factors clearly depends on the type of population addressed. The impact of observable risk factors on individual mortality, in particular when they also constitute “rating factors” in the calculation of premiums and other actuarial values, is usually expressed approximately, according to some pragmatic approach. For example, additive or multiplicative adjustments to the average age-specific mortality are frequently adopted. Heterogeneity due to unobservable risk factors can conversely be expressed by adopting the concept of individual “frailty”, which, however, can be interpreted and consequently modeled in several ways, according to the causes which are considered as originating the frailty itself: congenital characteristics, environmental features, lifestyle aspects, etc. In this paper, we provide a survey of scientific contributions on heterogeneity in mortality, focusing on modeling both observable and unobservable heterogeneity. We start with an overview of methodological contributions to heterogeneity and frailty modeling, coming from both the demographical and the actuarial context. We then shift to contributions analyzing the impact of frailty, in its various interpretations, on the results (cash flows, profits, etc.) of life insurance and life annuity portfolios and related risk profiles.

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Ainslie R (2000) Annuity and insurance products for impaired lives. Working Paper. Presented to the Staple Inn Actuarial Society

Avraam D, Arnold (-Gaille) S, Jones D, Vasiev B (2014) Time-evolution of age-dependent mortality patterns in mathematical model of heterogeneous human population. Exp Gerontol 60:18–30CrossRef

Avraam D, Arnold S, Vasieva O, Vasiev B (2016) On the heterogeneity of human populations as reflected by mortality dynamics. Aging 8(11):3045–3064CrossRef

Avraam D, de Magalhaes JP, Vasiev B (2013) A mathematical model of mortality dynamics across the lifespan combining heterogeneity and stochastic effects. Exp Gerontol 48:801–811CrossRef

Balakrishnan N, Peng Y (2006) Generalized gamma frailty model. Stat Med 25(16):2797–2816MathSciNetCrossRef

Barnes MP (2010) Life expectancy for people with disabilities. NeuroRehabilitation 27(2):201–209

Beard RE (1959) Note on some mathematical mortality models. In: Wolstenholme CEW, Connor MO (eds) CIBA foundation colloquia on ageing, vol 5. Boston. pp 302–311

Brown GC (2015) Living too long. EMBO Rep 16(2):137–141CrossRef

Butt Z, Haberman S (2002) Application of frailty-based mortality models to insurance data. Actuarial Research Paper No. 142, Faculty of Actuarial Science & Insurance, City University, London. http://openaccess.city.ac.uk/2279/1/142-ARC.pdf. Accessed 30 May 2019

10.

Butt Z, Haberman S (2004) Application of frailty-based mortality models using generalized linear models. ASTIN Bull 34(1):175–197MathSciNetMATHCrossRef

11.

Corbaux F (1833) On the natural and mathematical laws concerning population, vitality, and mortality. (Chaps. XXV, XXVI). London. https://ia802703.us.archive.org/32/items/b21955207/b21955207.pdf. Accessed 30 May 2019

12.

Cummins JD, Smith BD, Vance RN, VanDerhei JL (1983) Risk Classification in life insurance. Kluwer - Nijhoff Publishing, LeidenCrossRef

13.

Daly MC, Wilson DJ (2013) Inequality and mortality: New evidence from U.S. County Panel Data. Working Paper No. 2013-13, Federal Reserve Bank of San Francisco. https://www.frbsf.org/economic-research/files/wp2013-13.pdf. Accessed 30 May 2019

14.

de Ferra C (1954) Tavola di mortalitá per una popolazione inomogenea. Giornale dell’Istituto Italiano degli Attuari 17:62–76MATH

15.

de Finetti B, Taucer R (1952) Sur l’emploi d’une base technique générale pour le risques tares. In: Conférence Internationale des Risques Aggravés, Stockholm. pp 86 – 104

16.

Deaton A, Paxson C (2001) Mortality, income, and income inequality over time in Britain and the United States. NBER Working Paper No. 8534, National Bureau of Economic Research, Cambridge, MA. http://www.nber.org/papers/w8534.pdf. Accessed 30 May 2019

17.

Dodd E, Forster JJ, Bijak J, Smith PWF (2018) Smoothing mortality data: the english life tables, 2010–2012. J R Stat Soc Ser A 181(Part 3):717–735MathSciNetCrossRef

18.

Doray LG (2008) Inference for logistic-type models for the force of mortality. Presented at the Living to 100 and Beyond Symposium. Orlando, FL. https://www.soa.org/globalassets/assets/files/resources/essays-monographs/2008-living-to-100/mono-li08-4a-doray-abstract.pdf. Accessed 30 May 2019

19.

Duchateau L, Janssen P (2008) The frailty model. Springer, BerlinMATH

20.

Gatzert N, Schmitt-Hoermann G, Schmeiser H (2012) Optimal risk classification with an application to substandard annuities. N Am Actuar J 16(4):462–486MathSciNetMATHCrossRef

21.

Gompertz B (1825) On the nature of the function expressive of the law of human mortality, and on a new mode of determining the value of life contingencies. Philos Trans R Soc Ser A 115:513–583CrossRef

22.

Haberman S (1996) Landmarks in the history of actuarial science (up to 1919). Actuarial Research Paper No. 84, Faculty of Actuarial Science & Insurance, City University, London. http://openaccess.city.ac.uk/2228/1/84-ARC.pdf. Accessed 30 May 2019

23.

Haberman S, Olivieri A (2014) Risk classification/life. In: Wiley StatsRef: statistics reference online. Wiley, Hoboken

24.

Hougaard P (1984) Life table methods for heterogeneous populations: distributions describing heterogeneity. Biometrika 71(1):75–83MathSciNetMATHCrossRef

25.

Hougaard P (1986) Survival models for heterogeneous populations derived from stable distributions. Biometrika 73(2):387–396MathSciNetMATHCrossRef

26.

Hughes M (2012) Preferred risk in life insurance. SCOR inFORM. https://www.scor.com/en/files/preferred-risk-life-insurance. Accessed 30 May 2019

27.

Hunter A (1917) Insurance on sub-standard lives. Ann Am Acad Polit Soc Sci 70:38–53CrossRef

28.

Ingle D (2013) Implications for use of credits applied to preferred knock-out criteria. Risk 29(4):42–52MathSciNet

29.

Kannisto V (1994) Development of oldest-old mortality, 1950–1990: evidence from 28 developed countries. Odense Monographs on Population Aging, 1. Odense University Press. http://www.demogr.mpg.de/Papers/Books/Monograph1/OldestOld.htm. Accessed 30 May 2019

30.

Keyfitz N, Littman G (1979) Mortality in a heterogeneous population. Popul Stud 33:333–342CrossRef

31.

Le Bras H (1976) Lois de mortalité et age limite. Population 31(3):655–692CrossRef

32.

Levinson LH (1959) A theory of mortality classes. Trans Soc Actuar 11:46–87MathSciNet

33.

Lin XS, Liu X (2007) Markov aging process and phase-type law of mortality. N Am Actuar J 11:92–109MathSciNetCrossRef

34.

Lindholm M (2017) A note on the connection between some classical mortality laws and proportional frailty. Stat Probab Lett 126:76–82MathSciNetMATHCrossRef

35.

Liu X, Lin XS (2012) A subordinated Markov model for stochastic mortality. Eur Actuar J 2(1):105–127MathSciNetMATHCrossRef

36.

Makeham WM (1867) On the law of mortality. J Inst Actuar 8:301–310CrossRef

37.

Manton KG, Stallard E, Vaupel JW (1986) Alternative models for the heterogeneity of mortality risks among the aged. J Am Stat Assoc 81:635–644CrossRef

38.

Martin J, Elliot D (1992) Creating an overall measure of severity of disability for the office of population censuses and surveys disability survey. J R Stat Soc Ser A 155(1):121–140CrossRef

39.

Martinelle S (1987) A generalized Perks formula for old-age mortality. R & D report / Statistics Sweden. Statistiska Centralbyrån, Stockholm

40.

Meyricke R, Sherris M (2013) The determinants of mortality heterogeneity and implications for pricing annuities. Insur Math Econ 53(2):379–387MathSciNetMATHCrossRef

41.

Munich Re (1999) The concept of preferred lives. Münchener Rückversicherungs - Gesellschaft

42.

Olivieri A (2006) Heterogeneity in survival models. Applications to pension and life annuities. Belg Actuar Bull 6:23–39. https://papers.ssrn.com/sol3/papers.cfm?abstract_id=913770. Accessed 30 May 2019

43.

Olivieri A, Pitacco E (2015) Introduction to Insurance Mathematics. Technical and Financial Features of Risk Transfers. EAA Series. Springer, 2nd edn

44.

Olivieri A, Pitacco E (2016) Frailty and risk classification for life annuity portfolios. Risks 4(4):39. http://www.mdpi.com/2227-9091/4/4/39. Accessed 30 May 2019

45.

Olshansky SJ (1998) On the biodemography of aging: a review essay. Popul Dev Rev 24:381–393CrossRef

46.

Olshansky SJ, Carnes BE (1997) Ever since Gompertz. Demography 34(1):1–15CrossRef

47.

Perks W (1932) On some experiments in the graduation of mortality statistics. J Inst Actuar 63:12–57CrossRef

48.

Pitacco E (2014) Health insurance. Basic actuarial models. EAA Series. Springer, BerlinMATH

49.

Pitacco E (2016a) High age mortality and frailty. Some remarks and hints for actuarial modeling. CEPAR Working Paper 2016/19. http://cepar.edu.au/sites/default/files/High_Age_Mortality_and_Frailty.pdf. Accessed 30 May 2019

50.

Pitacco E (2016b) Premiums for long-term care insurance packages: sensitivity with respect to biometric assumptions. Risks 4(1):1–22. http://www.mdpi.com/2227-9091/4/1/3. Accessed 30 May 2019

51.

Pitacco E (2017) Life annuities. Products, guarantees, basic actuarial models. CEPAR Working Paper 2017/6. http://cepar.edu.au/sites/default/files/Life_Annuities_Products_Guarantees_Basic_Actuarial_Models_Revised.pdf. Accessed 30 May 2019

52.

Pitacco E (2018) Can frailty models improve actuarial calculations in health insurance? In: Presented at the 31st international congress of actuaries, Berlin

53.

Pitacco E, Denuit M, Haberman S, Olivieri A (2009) Modelling longevity dynamics for pensions and annuity business. Oxford University Press, OxfordMATH

54.

Pollard AH (1970) Random mortality fluctuations and the binomial hypothesis. J Inst Actuar 96:251–264CrossRef

55.

Redington FM (1969) An exploration into patterns of mortality. J Inst Actuar 95:243–298CrossRef

56.

Rickayzen BD (2007) An analysis of disability-linked annuities. Actuarial Research Paper No. 180, Faculty of Actuarial Science & Insurance, City University, London. http://openaccess.city.ac.uk/2312/1/180ARP.pdf. Accessed 30 May 2019

57.

Rickayzen BD, Walsh DEP (2002) A multi-state model of disability for the United Kingdom: implications for future need for long-term care for the elderly. Br Actuar J 8(36):341–393CrossRef

58.

Rinke CR (2002) The variability of life reflected in annuity products. Hannover Re’s perspectives—current topics of international life insurance 8

59.

Rodgers GB (1979) Income and inequality as determinants of mortality: an international cross-section analysis. Popul Stud 33:343–351CrossRef

60.

Rogers O, Hunter A (1919) Numerical rating. The numerical method of determining the value of risks for insurance. Trans Actuar Soc Am XX – Part 2(62):273–331

61.

Scharf T, Shaw C (2017) Inequalities in later life. Technical report, Centre for Ageing Better, London. https://www.ageing-better.org.uk/sites/default/files/2017-12/Inequalities%20scoping%20review%20full%20report.pdf. Accessed 30 May 2019

62.

Sherris M, Zhou Q (2014) Model risk, mortality heterogeneity, and implications for solvency and tail risk. In: Mitchell OS, Maurer R, Hammond PB (eds) Recreating sustainable retirement: resilience, solvency, and tail risk. Oxford University Press, Oxford

63.

Steinsaltz DR, Wachter KW (2006) Understanding mortality rate deceleration and heterogeneity. Math Popul Stud 13(1):19–37MathSciNetMATHCrossRef

64.

Su S, Sherris M (2012) Heterogeneity of Australian population mortality and implications for a viable life annuity market. Insur Math Econ 51(2):322–332MathSciNetCrossRef

65.

Thatcher AR (1999) The long-term pattern of adult mortality and the highest attained age. J R Stat Soc Ser A 162:5–43CrossRef

66.

Thatcher AR, Kannisto V, Vaupel JW (1998) The Force of Mortality at Ages 80 to 120. Odense Monographs on Population Aging, 5. Odense University Press. http://www.demogr.mpg.de/Papers/Books/Monograph5/ForMort.htm. Accessed 30 May 2019

67.

Vaupel JW, Manton KG, Stallard E (1979) The impact of heterogeneity in individual frailty on the dynamics of mortality. Demography 16(3):439–454CrossRef

68.

Vaupel JW, Yashin AI (1985) The deviant dynamics of death in heterogeneous populations. Sociol Methodol 15:179–211MATHCrossRef

69.

Venter GG, Schill B, Barnett J (1991) Review of Report of Committee on Mortality for Disabled Lives. Casualty Actuarial Society. Arlington, Virginia. https://www.casact.org/pubs/forum/91wforum/91wf115.pdf. Accessed 30 May 2019

70.

Werth M (1995) Preferred lives. A more complete method of risk assessment. Working Paper. Presented to the Staple Inn Actuarial Society. https://www.actuaries.org.uk/system/files/documents/pdf/preferred.pdf. Accessed 30 May 2019

71.

Wienke A (2003) Frailty models. MPIDR Working Paper WP 2003-032. Max Planck Institute for Demographic Research, Rostock, Germany. http://www.demogr.mpg.de/papers/working/wp-2003-032.pdf. Accessed 30 May 2019

72.

Yashin AI, Iachine IA (1997) How frailty models can be used for evaluating longevity limits: taking advantage of an interdisciplinary approach. Demography 34(1):31–48CrossRef

73.

Yashin AI, Iachine IA, Begun AZ, Vaupel JW (2001) Hidden frailty: Myths and reality. Department of Statistics and Demography, Odense University, Denmark. https://www.researchgate.net/publication/228852668_Hidden_frailty. Accessed 30 May 2019

74.

Yashin AI, Manton KG, Vaupel JW (1985) Mortality and ageing in a heterogeneous population: a stochastic process model with observed and unobserved variables. Theor Popul Biol 27(2):154–175MATHCrossRef

Title: Heterogeneity in mortality: a survey with an actuarial focus
Author: Ermanno Pitacco
Publication date: 04-06-2019
Publisher: Springer Berlin Heidelberg
Published in: European Actuarial Journal / Issue 1/2019
Print ISSN: 2190-9733
Electronic ISSN: 2190-9741
DOI: https://doi.org/10.1007/s13385-019-00207-z

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