Abstract
We introduce a new approach to latent state filtering and parameter estimation for a class of stochastic volatility models (SVMs) for which the likelihood function is unknown. The α-stable stochastic volatility model provides a flexible framework for capturing asymmetry and heavy tails, which is useful when modeling financial returns. However, the α-stable distribution lacks a closed form for the probability density function, which prevents the direct application of standard Bayesian filtering and estimation techniques such as sequential Monte Carlo and Markov chain Monte Carlo. To obtain filtered volatility estimates, we develop a novel approximate Bayesian computation (ABC) based auxiliary particle filter, which provides improved performance through better proposal distributions. Further, we propose a new particle based MCMC (PMCMC) method for joint estimation of the parameters and latent volatility states. With respect to other extensions of PMCMC, we introduce an efficient single filter particle Metropolis-within-Gibbs algorithm which can be applied for obtaining inference on the parameters of an asymmetric α-stable stochastic volatility model. We show the increased efficiency in the estimation process through a simulation study. Finally, we highlight the necessity for modeling asymmetric α-stable SVMs through an application to propane weekly spot prices.
Highlights
Assessing the unobserved variability of financial returns is crucial to regulators and policy makers
We illustrate the significant increase in computational efficiency of our algorithm as compared to standard approximate Bayesian computation (ABC) based particle Markov chain Monte Carlo (MCMC) discussed in Jasra et al (2013) and the ABC counterpart of Mendes et al (2015)
We study the performance of APF-ABC, the Kalman filter, as well as an implementation of sequential Monte Carlo (SMC)-ABC as in Jasra et al (2012), based on root-mean-squared error (RMSE), for three different data sets with different signal-to-noise ratios (Tables 1–3 in Appendix C of the Supplementary Material (Vankov et al, 2019))
Summary
Assessing the unobserved variability of financial returns is crucial to regulators and policy makers. A key challenge to models based on the α-stable distribution is the absence of closed form expression for the probability density function (p.d.f.) Standard estimation techniques, such as maximum likelihood and Markov chain Monte Carlo (MCMC) are unsuitable. In this paper we develop an ABC based auxiliary particle filter (APF-ABC) for efficient latent state estimation in state-space models. We develop a single filter particle Metropolis-within-Gibbs (SF-PMwG) algorithm to efficiently estimate the volatility and parameters of the asymmetric α-stable stochastic volatility model. The ABC based auxiliary particle filter only provides estimates of the latent volatility, conditional on the data and the parameters. Our paper is organized as follows: in Section 2 we provide an overview of most used filtering and estimation procedures for the stochastic volatility model under different distributional assumptions.
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