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Stochastic Volatility Models

library(bvhar)
etf <- etf_vix[1:55, 1:3]
# Split-------------------------------
h <- 5
etf_eval <- divide_ts(etf, h)
etf_train <- etf_eval$train
etf_test <- etf_eval$test

Models with Stochastic Volatilities

By specifying cov_spec = set_sv(), var_bayes() and vhar_bayes() fits VAR-SV and VHAR-SV with shrinkage priors, respectively.

set_sv()
#> Model Specification for SV with Cholesky Prior
#> 
#> Parameters: Contemporaneous coefficients, State variance, Initial state
#> Prior: Cholesky
#> ========================================================
#> Setting for 'shape':
#> [1]  rep(3, dim)
#> 
#> Setting for 'scale':
#> [1]  rep(0.01, dim)
#> 
#> Setting for 'initial_mean':
#> [1]  rep(1, dim)
#> 
#> Setting for 'initial_prec':
#> [1]  0.1 * diag(dim)

SSVS

(fit_ssvs <- vhar_bayes(etf_train, num_chains = 2, num_iter = 20, bayes_spec = set_ssvs(), cov_spec = set_sv(), include_mean = FALSE, minnesota = "longrun"))
#> Call:
#> vhar_bayes(y = etf_train, num_chains = 2, num_iter = 20, bayes_spec = set_ssvs(), 
#>     cov_spec = set_sv(), include_mean = FALSE, minnesota = "longrun")
#> 
#> BVHAR with Stochastic Volatility
#> Fitted by Gibbs sampling
#> Number of chains: 2
#> Total number of iteration: 20
#> Number of burn-in: 10
#> ====================================================
#> 
#> Parameter Record:
#> # A draws_df: 10 iterations, 2 chains, and 177 variables
#>      phi[1]  phi[2]   phi[3]   phi[4]   phi[5]   phi[6]  phi[7]   phi[8]
#> 1   -0.2154  -0.918  -0.7346   2.1794   1.7256   0.2252  -1.092   0.5860
#> 2   -0.2785   0.361  -0.1798  -0.0515   0.2544  -0.1548  -0.450  -0.3199
#> 3    0.0353   0.931   0.2222   0.0171  -0.2469  -0.0554   0.117   1.4097
#> 4    0.5949   0.525   0.1028   0.0410   0.0271  -0.0455  -0.951   0.7377
#> 5    0.3498   0.290   0.0491   0.2809  -0.0988  -0.1612  -2.714   0.2611
#> 6    0.2042  -0.608  -0.7952   1.0893  -0.2569   0.1259  -0.668   0.0569
#> 7    2.8408   0.429   0.8159  -0.1145  -0.4483  -0.0771  -1.257   0.3496
#> 8    1.2273   0.108  -0.2173   0.6008   0.2836  -0.5716   0.109   0.5889
#> 9    0.8396  -0.286   0.4581   1.8056  -1.0432   0.7261   0.666   0.0355
#> 10  -1.5707  -2.630   2.8384   2.5789  -0.1900  -0.6488   0.906  -0.0653
#> # ... with 10 more draws, and 169 more variables
#> # ... hidden reserved variables {'.chain', '.iteration', '.draw'}

Horseshoe

(fit_hs <- vhar_bayes(etf_train, num_chains = 2, num_iter = 20, bayes_spec = set_horseshoe(), cov_spec = set_sv(), include_mean = FALSE, minnesota = "longrun"))
#> Call:
#> vhar_bayes(y = etf_train, num_chains = 2, num_iter = 20, bayes_spec = set_horseshoe(), 
#>     cov_spec = set_sv(), include_mean = FALSE, minnesota = "longrun")
#> 
#> BVHAR with Stochastic Volatility
#> Fitted by Gibbs sampling
#> Number of chains: 2
#> Total number of iteration: 20
#> Number of burn-in: 10
#> ====================================================
#> 
#> Parameter Record:
#> # A draws_df: 10 iterations, 2 chains, and 211 variables
#>       phi[1]   phi[2]   phi[3]    phi[4]   phi[5]    phi[6]   phi[7]     phi[8]
#> 1    0.09387  -0.2328   0.4597  -0.18840   0.8345   0.01655  -0.9590   0.038319
#> 2   -0.09961  -0.6774   0.2270   0.16758   0.5573   0.00551   0.2524   0.064362
#> 3   -0.19695  -0.7337   0.0183   0.40152  -0.2635  -0.00795   0.0042   0.057482
#> 4   -0.09827  -0.1309  -0.1432  -0.00451   0.1331   0.00148   0.0495   0.020706
#> 5    0.11908   0.0935  -0.2156   0.22296  -0.1274  -0.00820  -0.0373  -0.005457
#> 6   -0.02723   0.0708   0.4767  -0.20709   0.1779  -0.00173   0.0112  -0.044320
#> 7    0.03845  -0.0797   0.4981  -0.24877   0.1477   0.02493   0.6637  -0.011321
#> 8   -0.00283   0.1016   0.4239   0.12436   0.0137  -0.01699   0.6482  -0.000937
#> 9   -0.06436   0.1563   0.4189   0.61076   0.1722  -0.01553   0.2497  -0.000081
#> 10   0.07825   0.1444   0.1608   0.70196   0.0251  -0.01597   0.1062  -0.001968
#> # ... with 10 more draws, and 203 more variables
#> # ... hidden reserved variables {'.chain', '.iteration', '.draw'}

Normal-Gamma prior

(fit_ng <- vhar_bayes(etf_train, num_chains = 2, num_iter = 20, bayes_spec = set_ng(), cov_spec = set_sv(), include_mean = FALSE, minnesota = "longrun"))
#> Call:
#> vhar_bayes(y = etf_train, num_chains = 2, num_iter = 20, bayes_spec = set_ng(), 
#>     cov_spec = set_sv(), include_mean = FALSE, minnesota = "longrun")
#> 
#> BVHAR with Stochastic Volatility
#> Fitted by Metropolis-within-Gibbs
#> Number of chains: 2
#> Total number of iteration: 20
#> Number of burn-in: 10
#> ====================================================
#> 
#> Parameter Record:
#> # A draws_df: 10 iterations, 2 chains, and 184 variables
#>       phi[1]   phi[2]    phi[3]  phi[4]    phi[5]     phi[6]   phi[7]   phi[8]
#> 1   -0.03503   0.4053   0.80020   2.371  -0.00209  -5.31e-03   0.3870  -0.1045
#> 2    0.39979   0.2931   0.91785   1.872   0.00119   2.77e-02   3.3153  -0.1662
#> 3   -0.35569  -0.0641   0.66248   0.597   0.00706   2.32e-03   1.6667  -0.3047
#> 4    0.06540  -0.0491   0.85497   0.114   0.04083  -5.44e-04   2.7827  -0.3749
#> 5   -0.02658   0.0935   0.23675   1.310  -0.00705  -3.19e-01   1.6540  -0.8789
#> 6    0.10168  -0.0181   0.16812   1.184   0.01823  -3.29e-01   0.7259   0.2146
#> 7    0.10309   0.0822  -0.01360   0.860  -0.01033   1.22e-01  -0.2534   0.3281
#> 8   -0.00631   0.3102  -0.03173  -0.237   0.04021   2.47e-01  -0.6211  -0.0877
#> 9    0.01706   0.1839  -0.00247   0.300   0.13999   8.23e-05   0.8887   0.0405
#> 10   0.00980  -0.0195  -0.10148   0.313  -0.13060  -2.48e-02   0.0501  -0.0344
#> # ... with 10 more draws, and 176 more variables
#> # ... hidden reserved variables {'.chain', '.iteration', '.draw'}

Dirichlet-Laplace prior

(fit_dl <- vhar_bayes(etf_train, num_chains = 2, num_iter = 20, bayes_spec = set_dl(), cov_spec = set_sv(), include_mean = FALSE, minnesota = "longrun"))
#> Call:
#> vhar_bayes(y = etf_train, num_chains = 2, num_iter = 20, bayes_spec = set_dl(), 
#>     cov_spec = set_sv(), include_mean = FALSE, minnesota = "longrun")
#> 
#> BVHAR with Stochastic Volatility
#> Fitted by Gibbs sampling
#> Number of chains: 2
#> Total number of iteration: 20
#> Number of burn-in: 10
#> ====================================================
#> 
#> Parameter Record:
#> # A draws_df: 10 iterations, 2 chains, and 178 variables
#>       phi[1]    phi[2]     phi[3]  phi[4]  phi[5]    phi[6]    phi[7]    phi[8]
#> 1   -0.00311   0.37352  -0.082172  -0.807  1.1321   0.08043   0.12454   0.91372
#> 2   -0.01038  -0.23419  -0.007526   2.195  0.1480  -0.01890  -0.00529   0.27287
#> 3    0.00177   0.03662   0.001190   1.423  0.0979   0.00538   0.08416   0.41598
#> 4    0.01179   0.00554   0.000542   0.279  0.6115   0.02157   0.04629   0.01362
#> 5   -0.02628  -0.28438   0.080120   0.844  0.3990   0.10118  -0.03440  -0.00467
#> 6    0.03825  -0.25445   0.043289   1.368  1.6698  -0.00774   0.05832  -0.07363
#> 7   -0.02246  -0.23139  -0.001047   1.187  1.1587   0.03060   0.02282   0.10864
#> 8   -0.06698  -0.37957  -0.027255   0.824  1.7303  -0.01655   0.02071  -0.14264
#> 9    0.27838  -0.20076  -0.007266   0.903  0.0744   0.11441   0.02485   0.08739
#> 10   0.11393   0.15785  -0.062115   0.493  0.1708   0.07095  -0.00281  -0.14318
#> # ... with 10 more draws, and 170 more variables
#> # ... hidden reserved variables {'.chain', '.iteration', '.draw'}

Bayesian visualization

autoplot() also provides Bayesian visualization. type = "trace" gives MCMC trace plot.

autoplot(fit_hs, type = "trace", regex_pars = "tau")

type = "dens" draws MCMC density plot.

autoplot(fit_hs, type = "dens", regex_pars = "tau")

These binaries (installable software) and packages are in development.
They may not be fully stable and should be used with caution. We make no claims about them.