TY - UNPB
T1 - Efficient estimation of time-varying parameter models with stochastic volatility
AU - Turatti, Douglas Eduardo
PY - 2021
Y1 - 2021
N2 - This paper develops an efficient estimation procedure for time-varying parameter autoregressive models with stochastic volatility. Necessary restrictions are imposed on the time-varying autoregressive parameters, thus stability conditions are satisfied. We show that a conditional Gaussian likelihood representation is available with marginalization of linear latent states, thus only non-linear states need to be simulated. The sampling is based on a multivariate extension of the Numerically Accelerated Importance Sampling together with a Rao Blackwellization step to construct a highly efficient maximum likelihood estimator. A simulation study highlights the precision of the procedure in the joint estimation of parameters and latent states. The models are applied to the analysis of inflation dynamics. Estimates of the time-varying parameters indicate the importance of the random innovations in explaining the inflation process, while the trend component is more stable than previously found in the literature. An out-of sample forecasting exercise showed superior results with respect to several benchmark models, especially for long-term forecasting.
AB - This paper develops an efficient estimation procedure for time-varying parameter autoregressive models with stochastic volatility. Necessary restrictions are imposed on the time-varying autoregressive parameters, thus stability conditions are satisfied. We show that a conditional Gaussian likelihood representation is available with marginalization of linear latent states, thus only non-linear states need to be simulated. The sampling is based on a multivariate extension of the Numerically Accelerated Importance Sampling together with a Rao Blackwellization step to construct a highly efficient maximum likelihood estimator. A simulation study highlights the precision of the procedure in the joint estimation of parameters and latent states. The models are applied to the analysis of inflation dynamics. Estimates of the time-varying parameters indicate the importance of the random innovations in explaining the inflation process, while the trend component is more stable than previously found in the literature. An out-of sample forecasting exercise showed superior results with respect to several benchmark models, especially for long-term forecasting.
KW - Time-varying parameter models
KW - stochastic volatility
KW - Numerically Accelerated Importance Sampling
KW - forecasting inflation
U2 - 10.2139/ssrn.3236806
DO - 10.2139/ssrn.3236806
M3 - Working paper
BT - Efficient estimation of time-varying parameter models with stochastic volatility
ER -