Bayesian estimation of a homoskedastic Structural Vector Autoregression via Gibbs sampler
Source:R/estimate.BSVAR.R
estimate.BSVAR.Rd
Estimates the homoskedastic SVAR using the Gibbs sampler proposed by Waggoner & Zha (2003) for the structural matrix \(B\) and the equation-by-equation sampler by Chan, Koop, & Yu (2024) for the autoregressive slope parameters \(A\). Additionally, the parameter matrices \(A\) and \(B\) follow a Minnesota prior and generalised-normal prior distributions respectively with the matrix-specific overall shrinkage parameters estimated using a hierarchical prior distribution as in Lütkepohl, Shang, Uzeda, and Woźniak (2024). See section Details for the model equations.
Usage
# S3 method for class 'BSVAR'
estimate(specification, S, thin = 1, show_progress = TRUE)
Arguments
- specification
an object of class BSVAR generated using the
specify_bsvar$new()
function.- S
a positive integer, the number of posterior draws to be generated
- thin
a positive integer, specifying the frequency of MCMC output thinning
- show_progress
a logical value, if
TRUE
the estimation progress bar is visible
Value
An object of class PosteriorBSVAR containing the Bayesian estimation output and containing two elements:
posterior
a list with a collection of S
draws from the posterior distribution generated via Gibbs sampler containing:
- A
an
NxKxS
array with the posterior draws for matrix \(A\)- B
an
NxNxS
array with the posterior draws for matrix \(B\)- hyper
a
5xS
matrix with the posterior draws for the hyper-parameters of the hierarchical prior distribution
last_draw
an object of class BSVAR with the last draw of the current MCMC run as the starting value to be passed to the continuation of the MCMC estimation using estimate()
.
Details
The homoskedastic SVAR model is given by the reduced form equation:
$$Y = AX + E$$
where \(Y\) is an NxT
matrix of dependent variables, \(X\) is a KxT
matrix of explanatory variables,
\(E\) is an NxT
matrix of reduced form error terms, and \(A\) is an NxK
matrix of autoregressive slope coefficients and parameters on deterministic terms in \(X\).
The structural equation is given by
$$BE = U$$
where \(U\) is an NxT
matrix of structural form error terms, and
\(B\) is an NxN
matrix of contemporaneous relationships.
Finally, the structural shocks, U
, are temporally and contemporaneously independent and jointly normally distributed with zero mean and unit variances.
References
Chan, J.C.C., Koop, G, and Yu, X. (2024) Large Order-Invariant Bayesian VARs with Stochastic Volatility. Journal of Business & Economic Statistics, 42, doi:10.1080/07350015.2023.2252039 .
Lütkepohl, H., Shang, F., Uzeda, L., and Woźniak, T. (2024) Partial Identification of Heteroskedastic Structural VARs: Theory and Bayesian Inference. University of Melbourne Working Paper, 1–57, doi:10.48550/arXiv.2404.11057 .
Waggoner, D.F., and Zha, T., (2003) A Gibbs sampler for structural vector autoregressions. Journal of Economic Dynamics and Control, 28, 349–366, doi:10.1016/S0165-1889(02)00168-9 .
Author
Tomasz Woźniak wozniak.tom@pm.me
Examples
# simple workflow
############################################################
# upload data
data(us_fiscal_lsuw)
# specify the model and set seed
specification = specify_bsvar$new(us_fiscal_lsuw, p = 4)
#> The identification is set to the default option of lower-triangular structural matrix.
set.seed(123)
# run the burn-in
burn_in = estimate(specification, 5)
#> **************************************************|
#> bsvars: Bayesian Structural Vector Autoregressions|
#> **************************************************|
#> Gibbs sampler for the SVAR model |
#> **************************************************|
#> Progress of the MCMC simulation for 5 draws
#> Every draw is saved via MCMC thinning
#> Press Esc to interrupt the computations
#> **************************************************|
# estimate the model
posterior = estimate(burn_in, 10, thin = 2)
#> **************************************************|
#> bsvars: Bayesian Structural Vector Autoregressions|
#> **************************************************|
#> Gibbs sampler for the SVAR model |
#> **************************************************|
#> Progress of the MCMC simulation for 10 draws
#> Every 2nd draw is saved via MCMC thinning
#> Press Esc to interrupt the computations
#> **************************************************|
# workflow with the pipe |>
############################################################
set.seed(123)
us_fiscal_lsuw |>
specify_bsvar$new(p = 1) |>
estimate(S = 5) |>
estimate(S = 10, thin = 2) |>
compute_impulse_responses(horizon = 4) -> irf
#> The identification is set to the default option of lower-triangular structural matrix.
#> **************************************************|
#> bsvars: Bayesian Structural Vector Autoregressions|
#> **************************************************|
#> Gibbs sampler for the SVAR model |
#> **************************************************|
#> Progress of the MCMC simulation for 5 draws
#> Every draw is saved via MCMC thinning
#> Press Esc to interrupt the computations
#> **************************************************|
#> **************************************************|
#> bsvars: Bayesian Structural Vector Autoregressions|
#> **************************************************|
#> Gibbs sampler for the SVAR model |
#> **************************************************|
#> Progress of the MCMC simulation for 10 draws
#> Every 2nd draw is saved via MCMC thinning
#> Press Esc to interrupt the computations
#> **************************************************|