Abstract
In this paper, we propose a novel framework for estimating systemic risk measures and risk allocations based on Markov Chain Monte Carlo (MCMC) methods. We consider a class of allocations whose jth component can be written as some risk measure of the jth conditional marginal loss distribution given the so-called crisis event. By considering a crisis event as an intersection of linear constraints, this class of allocations covers, for example, conditional Value-at-Risk (CoVaR), conditional expected shortfall (CoES), VaR contributions, and range VaR (RVaR) contributions as special cases. For this class of allocations, analytical calculations are rarely available, and numerical computations based on Monte Carlo (MC) methods often provide inefficient estimates due to the rare-event character of the crisis events. We propose an MCMC estimator constructed from a sample path of a Markov chain whose stationary distribution is the conditional distribution given the crisis event. Efficient constructions of Markov chains, such as the Hamiltonian Monte Carlo and Gibbs sampler, are suggested and studied depending on the crisis event and the underlying loss distribution. The efficiency of the MCMC estimators is demonstrated in a series of numerical experiments.
Highlights
In portfolio risk management, risk allocation is an essential step to quantifying the risk of each unit of a portfolio by decomposing the total risk of the whole portfolio
Based on the samples generated by the Monte Carlo (MC) method, we propose heuristics to determine the parameters of the Hamiltonian Monte Carlo (HMC) and Gibbs sampler (GS) methods, for which no manual interaction is required
The efficiency of Markov Chain Monte Carlo (MCMC) can indirectly be inspected through the acceptance rate (ACR) and the autocorrelation plot (ACP); ACR is the percentage of times a candidate Xis accepted among the N iterations, and ACP is the plot of the autocorrelation function of the generated sample path
Summary
Risk allocation is an essential step to quantifying the risk of each unit of a portfolio by decomposing the total risk of the whole portfolio. We consider a general class of systemic risk allocations in the form of risk measures of a conditional loss distribution given a crisis event, which includes CoVaR, CoES, MES, and Euler allocations as special cases. MCMC estimator for systemic risk allocations is that the support of the target distribution π is subject to constraints determined by the crisis event. For such target distributions, simple MCMC methods, such as random walk MH, are not efficient since a candidate is immediately rejected if it violates the constraints; see Section 3.2 for details. An R script reproducing the numerical experiments is available as Supplementary Material
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