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Continuous-time methods in the study of discretely sampled functionals of Lévy processes. I. The positive process case

Published online by Cambridge University Press:  01 July 2016

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Abstract

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In this paper we develop a constructive approach to studying continuously and discretely sampled functionals of Lévy processes. Estimates for the rate of convergence of the discretely sampled functionals to the continuously sampled functionals are derived, reducing the study of the latter to that of the former. Laguerre reduction series for the discretely sampled functionals are developed, reducing their study to that of the moment generating function of the pertinent Lévy processes and to that of the moments of these processes in particular. The results are applied to questions of contingent claim valuation, such as the explicit valuation of Asian options, and illustrated in the case of generalized inverse Gaussian Lévy processes.

Type
General Applied Probability
Copyright
Copyright © Applied Probability Trust 2007 

References

Aase Nielsen, J. and Sandmann, K. (1995). Equity linked life insurance. Insurance Math. Econom. 16, 225253.Google Scholar
Aase Nielsen, J. and Sandmann, K. (1996). Uniqueness of the fair premium for equity-linked life insurance contracts. Geneva Papers Risk Insurance Theory 21, 65102.Google Scholar
Aase Nielsen, J. and Sandmann, K. (2002). The fair premium of an equity-linked life and pension insurance. In Advances in Finance and Stochastics, eds Schönbucher, P. and Sandmann, K., Springer, Heidelberg, pp. 218255.Google Scholar
Barndorff-Nielsen, O. E. and Shephard, N. (2001). Modelling by Lévy processes for financial econometrics. In Lévy Processes, Birkhäuser, Boston, MA, pp. 283318.Google Scholar
Bauer, H. (1996). Probability Theory. De Gruyter, Berlin.CrossRefGoogle Scholar
Doetsch, G. (1971). Handbuch der Laplacetransformation I. Birkhäuser, Basel.Google Scholar
Duffie, D. (1996). Dynamic Asset Pricing Theory, 2nd edn. Princeton University Press.Google Scholar
Dufresne, D. (2000). Laguerre series for Asian and other options. Math. Finance 10, 407428.CrossRefGoogle Scholar
Eberlein, E. (2001). Application of generalized hyperbolic Lévy motions to finance. In Lévy Processes, Birkhäuser, Boston, MA, pp. 319336.Google Scholar
Erdélyi, A. et al. (1981). Higher Transcendental Functions, Vol. II. Krieger, Malabar, FL.Google Scholar
Hämmerlin, G. and Hoffmann, K. H. (1989). Numerische Mathematik. Springer, Heidelberg.CrossRefGoogle Scholar
Hull, J. C. and White, A. (1987). The pricing of options on assets with stochastic volatilities. J. Finance 42, 281300.CrossRefGoogle Scholar
Jørgensen, B. (1982). Statistical Properties of the Generalized Inverse Gaussian Distribution. Springer, Heidelberg.Google Scholar
Kallenberg, O. (2002). Foundations of Modern Probability, 2nd edn. Springer, New York.Google Scholar
Lebedev, N. N. (1972). Special Functions and Their Applications. Dover, New York.Google Scholar
LIFFE (2004). Exchange contract no. 59. One month Euro overnight index average (EONIA) indexed contract. The London International Financial Futures and Options Exchange. Available at http://www.euronext.com/trader/contractspecifications/derivative/wide/0,5786,1732_627725,00.html?euronextCode=EON-LON-FUT.Google Scholar
Musiela, M. and Rutkowski, M. (1997). Martingale Methods in Financial Modelling. Springer, New York.Google Scholar
Nicolato, E. and Venardos, E. (2003). Option pricing in stochastic volatility models of the Ornstein–Uhlenbeck type. Math. Finance 13, 445466.Google Scholar
Prause, K. (1999). The generalized hyperbolic model. , Universität Freiburg.Google Scholar
Raible, S. (2000). Lévy processes in finance. , Universität Freiburg.Google Scholar
Sansone, G. (1991). Orthogonal Functions. Dover, New York.Google Scholar
Schröder, M. (2005a). Laguerre series in contingent claim valuation, with applications to Asian options. Math. Finance 15, 491531.Google Scholar
Schröder, M. (2005b). Continuous time methods in the study of discretely sampled functionals of Lévy processes, II: the case of exponential Lévy processes. Working paper.Google Scholar
Schröder, M. (2005c). Continuous time methods in the study of discretely sampled functionals of Lévy processes, III: stochastic volatility models of OU type. Working paper.Google Scholar
Schröder, M. (2006a). On ladder height densities and Laguerre series in the study of stochastic functionals. I. Basic methods and results. Adv. Appl. Prob. 38, 969994.Google Scholar
Schröder, M. (2006b). On ladder height densities and Laguerre series in the study of stochastic functionals. II. Exponential functionals of Brownian motion and Asian option values. Adv. Appl. Prob. 38, 9951027.CrossRefGoogle Scholar
Thangavelu, S. (1993). Lectures on Hermite and Laguerre Expansions. Princeton University Press.Google Scholar