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Working Paper

Sequential Bayesian Inference for Vector Autoregressions with Stochastic Volatility

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We develop a sequential Monte Carlo (SMC) algorithm for Bayesian inference in vector autoregressions with stochastic volatility (VAR-SV). The algorithm builds particle approximations to the sequence of the model’s posteriors, adapting the particles from one approximation to the next as the window of available data expands. The parallelizability of the algorithm’s computations allows the adaptations to occur rapidly. Our particular algorithm exploits the ability to marginalize many parameters from the posterior analytically and embeds a known Markov chain Monte Carlo (MCMC) algorithm for the model as an effective mutation kernel for fighting particle degeneracy. We show that, relative to using MCMC alone, our algorithm increases the precision of inference while reducing computing time by an order of magnitude when estimating a medium-scale VAR-SV model.
Topics
Econometrics modeling and forecasting
12.16.2019WP 19-29DOI 10.26509/frbc-wp-201929
Keywords vector autoregressions, stochastic volatility, sequential Monte Carlo, particle filter, Rao-Blackwellization
JEL Classification Codes C11, C32, C51, E17

Working Papers of the Federal Reserve Bank of Cleveland are preliminary materials circulated to stimulate discussion and critical comment on research in progress. They may not have been subject to the formal editorial review accorded official Federal Reserve Bank of Cleveland publications. The views expressed in this paper are those of the authors and do not represent the views of the Federal Reserve Bank of Cleveland or the Federal Reserve System.

Suggested Citation

Bognanni, Mark, and John Zito. 2019. “Sequential Bayesian Inference for Vector Autoregressions with Stochastic Volatility.” Federal Reserve Bank of Cleveland, Working Paper No. 19-29. https://doi.org/10.26509/frbc-wp-201929