12.7 Stochastic Volatility Models
An important financial application of MCMC methods is the estimation of stochastic volatility models; see Jacquier, Polson, and Rossi (1994) and the references therein. We start with a univariate stochastic volatility model. The mean and volatility equations of an asset return rt are
where {xit|i = 1, … , p} are explanatory variables available at time t − 1, the βj are parameters, {ϵt} is a Gaussian white noise sequence with mean 0 and variance 1, {vt} is also a Gaussian white noise sequence with mean 0 and variance 
, and {ϵt} and {vt} are independent. The log transformation is used to ensure that ht is positive for all t. The explanatory variables xit may include lagged values of the return (e.g., xit = rt−i). In Eq. (12.21), we assume that |α1| < 1 so that the log volatility process ln ht is stationary. If necessary, a higher order AR(p) model can be used for ln ht.
Denote the coefficient vector of the mean equation by 
= (β0, β1, … , βp)′ and the parameter vector of the volatility equation by . Suppose that is the collection of observed ...
Get Analysis of Financial Time Series, Third Edition now with the O’Reilly learning platform.
O’Reilly members experience books, live events, courses curated by job role, and more from O’Reilly and nearly 200 top publishers.
