Default Clustering in Large Pools: Large Deviations

We study large deviations and rare default clustering events in a dynamic large heterogeneous portfolio of interconnected components. Defaults come as Poisson events and the default intensities of the different components in the system interact through the empirical default rate and via systematic effects that are common to all components. We establish the large deviations principle for the empirical default rate for such an interacting particle system. The rate function is derived in an explicit form that is amenable to numerical computations and derivation of the most likely path to failure for the system itself. Numerical studies illustrate the theoretical findings. An understanding of the role of the preferred paths to large default rates and the most likely ways in which contagion and systematic risk combine to lead to large default rates would give useful insights into how to optimally safeguard against such events.

[1]  Paul Glasserman,et al.  LARGE DEVIATIONS IN MULTIFACTOR PORTFOLIO CREDIT RISK , 2007 .

[2]  K. Spiliopoulos,et al.  Recovery Rates in Investment-Grade Pools of Credit Assets: A Large Deviations Analysis , 2010, 1006.2711.

[3]  K. Giesecke,et al.  Exploring the Sources of Default Clustering , 2017, Journal of Financial Economics.

[4]  Markus Fischer,et al.  On Large Deviations for Small Noise Itô Processes , 2012, Advances in Applied Probability.

[5]  P. Glasserman Tail Approximations for Portfolio Credit Risk , 2004 .

[6]  S. Ethier,et al.  Markov Processes: Characterization and Convergence , 2005 .

[7]  Paul Glasserman,et al.  Importance Sampling for Portfolio Credit Risk , 2005, Manag. Sci..

[8]  Amir Dembo,et al.  Large portfolio losses , 2002, Finance Stochastics.

[9]  Josselin Garnier,et al.  Large Deviations for a Mean Field Model of Systemic Risk , 2012, SIAM J. Financial Math..

[10]  M. Freidlin,et al.  Random Perturbations of Dynamical Systems , 1984 .

[11]  Srinivasa R. S. Varadhan,et al.  Asymptotic probabilities and differential equations , 1966 .

[12]  K. Spiliopoulos,et al.  Default clustering in large portfolios: Typical events. , 2011, 1104.1773.

[13]  Christoph Meinerding ASSET ALLOCATION AND ASSET PRICING IN THE FACE OF SYSTEMIC RISK: A LITERATURE OVERVIEW AND ASSESSMENT , 2012 .

[14]  J. Gärtner On the McKean‐Vlasov Limit for Interacting Diffusions , 1988 .

[15]  Amir Dembo,et al.  Large Deviations Techniques and Applications , 1998 .

[16]  E. Olivieri,et al.  Large deviations and metastability: Large deviations and statistical mechanics , 2005 .

[17]  Justin A. Sirignano,et al.  LARGE PORTFOLIO ASYMPTOTICS FOR LOSS FROM DEFAULT , 2011, 1109.1272.

[18]  W. Runggaldier,et al.  Large portfolio losses: A dynamic contagion model , 2007, 0704.1348.

[19]  P. D. Pra,et al.  Heterogeneous credit portfolios and the dynamics of the aggregate losses , 2008, 0806.3399.

[20]  Justin A. Sirignano,et al.  Fluctuation Analysis for the Loss from Default , 2013, 1304.1420.

[21]  J. Lynch,et al.  A weak convergence approach to the theory of large deviations , 1997 .