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Sharp Large Deviations and Gibbs Conditioning for Threshold Models in Portfolio Credit Risk

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  • Fengnan Deng
  • Anand N. Vidyashankar
  • Jeffrey F. Collamore

Abstract

We obtain sharp large deviation estimates for exceedance probabilities in dependent triangular array threshold models with a diverging number of latent factors. The prefactors quantify how latent-factor dependence and tail geometry enter at leading order, yielding three regimes: Gaussian or exponential-power tails produce polylogarithmic refinements of the Bahadur-Rao $n^{-1/2}$ law; regularly varying tails yield index-driven polynomial scaling; and bounded-support (endpoint) cases lead to an $n^{-3/2}$ prefactor. We derive these results through Laplace-Olver asymptotics for exponential integrals and conditional Bahadur-Rao estimates for the triangular arrays. Using these estimates, we establish a Gibbs conditioning principle in total variation: conditioned on a large exceedance event, the default indicators become asymptotically i.i.d., and the loss-given-default distribution is exponentially tilted (with the boundary case handled by an endpoint analysis). As illustrations, we obtain second-order approximations for Value-at-Risk and Expected Shortfall, clarifying when portfolios operate in the genuine large-deviation regime. The results provide a transferable set of techniques-localization, curvature, and tilt identification-for sharp rare-event analysis in dependent threshold systems.

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  • Fengnan Deng & Anand N. Vidyashankar & Jeffrey F. Collamore, 2025. "Sharp Large Deviations and Gibbs Conditioning for Threshold Models in Portfolio Credit Risk," Papers 2509.19151, arXiv.org, revised Oct 2025.
    • Handle: RePEc:arx:papers:2509.19151
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    References listed on IDEAS

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    5. Jeffrey F. Collamore & Hasitha de Silva & Anand N. Vidyashankar, 2022. "Sharp Probability Tail Estimates for Portfolio Credit Risk," Risks, MDPI, vol. 10(12), pages 1-20, December.
    6. Achal Bassamboo & Sandeep Juneja & Assaf Zeevi, 2008. "Portfolio Credit Risk with Extremal Dependence: Asymptotic Analysis and Efficient Simulation," Operations Research, INFORMS, vol. 56(3), pages 593-606, June.
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