Abstract
Portfolio credit derivatives are contracts that are tied to an underlying portfolio of defaultable reference assets and have payoffs that depend on the default times of these assets. The hedging of credit derivatives involves the calculation of the sensitivity of the contract value with respect to changes in the credit spreads of the underlying assets, or, more generally, with respect to parameters of the default-time distributions. We derive and analyze Monte Carlo estimators of these sensitivities. The payoff of a credit derivative is often discontinuous in the underlying default times, and this complicates the accurate estimation of sensitivities. Discontinuities introduced by changes in one default time can be smoothed by taking conditional expectations given all other default times. We use this to derive estimators and to give conditions under which they are unbiased. We also give conditions under which an alternative likelihood ratio method estimator is unbiased. We illustrate the application and verification of these conditions and estimators in the particular case of the multifactor Gaussian copula model, but the methods are more generally applicable.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Andersen, L., Sidenius, J., Basu, S.: All your hedges in one basket. Risk 16, 67–72 (2003)
Asmussen, S., Glynn, P.W.: Stochastic Simulation. Springer, New York (2007)
Bruyère, R., Cont, R., Copinot, R., Fery, L., Jaeck, J., Spitz, T., Smart, G.: Credit Derivatives and Structured Credit: A Guide for Investors. Wiley, Chichester (2006)
Broadie, M., Glasserman, P.: Estimating security price derivatives using simulation. Manag. Sci. 42, 269–285 (1996)
Chen, Z., Glasserman, P.: Fast pricing of basket default swaps. Oper. Res. 56, 286–303 (2008)
Cherubini, U., Luciano, E., Vecchiato, W.: Copula Methods in Finance. Wiley, New York (2004)
Duffie, D., Singleton, K.: Credit Risk: Pricing, Measurement, and Management. Princeton Univ. Press, Princeton (2003)
Fu, M.C., Hu, J.Q.: Conditional Monte Carlo: Gradient Estimation and Optimization Applications. Kluwer Academic, Boston (1997)
Glasserman, P.: Gradient Estimation via Perturbation Analysis. Kluwer Academic, Norwell (1991)
Glasserman, P.: Monte Carlo Methods in Financial Engineering. Springer, New York (2004)
Gong, W.B., Ho, Y.C.: Smoothed (conditional) perturbation analysis of discrete event dynamical systems. IEEE Trans. Automat. Contr. AC-32 10, 858–866 (1987)
Gupton, G., Finger, C., Bhatia, M.: CreditMetrics Technical Document. Morgan & Co., New York (1997)
Hull, J., White, A.: Valuation of a CDO and an nth-to-default CDS without Monte Carlo simulation. J. Deriv. 12(2), 8–23 (2004)
Joshi, M., Kainth, D.: Rapid and accurate development of prices and Greeks for nth-to-default credit swaps in the Li model. Quant. Finance 4, 266–275 (2004)
Laurent, J.-P., Gregory, J.: Basket default swaps, CDOs, and factor copulas. J. Risk 7(4), 103–122 (2005)
Li, D.: On default correlation: A copula function approach. J. Fixed Income 9, 43–54 (2000)
Schönbucher, P.: Credit Derivatives Pricing Models: Models, Pricing and Implementation. Wiley, New York (2003)
Suri, R., Zazanis, M.: Perturbation analysis gives strongly consistent sensitivity estimates for the M/G/1 queue. Manag. Sci. 34, 39–64 (1988)
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Chen, Z., Glasserman, P. Sensitivity estimates for portfolio credit derivatives using Monte Carlo. Finance Stoch 12, 507–540 (2008). https://doi.org/10.1007/s00780-008-0071-y
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00780-008-0071-y