Neo-Normal Distributions Family for MCMC Models in JAGS

mod <- "
model {
  # Likelihood
  for (i in 1:100) {
    x[i] ~ djskew.ep(2,1,0.8,1)
  }
}
"

modelv <- jags.model(textConnection(mod), n.chains=1, inits = list(".RNG.name" = "base::Wichmann-Hill",".RNG.seed" = 314159))
#> Compiling model graph
#>    Resolving undeclared variables
#>    Allocating nodes
#> Graph information:
#>    Observed stochastic nodes: 0
#>    Unobserved stochastic nodes: 100
#>    Total graph size: 103
#> 
#> Initializing model

samplesv <- coda.samples(modelv, variable.names = c("x"), n.iter = 1)
gen_datav <- (as.data.frame(as.matrix(samplesv)))
x <- as.numeric(gen_datav[1,])

model_string <- "
model {
  # Likelihood
  for (i in 1:100) {
    x[i] ~ djskew.ep(mu, tau,nu1, nu2)
  }
  
  # Prior distributions
  mu ~ dnorm(2,10000)
  tau ~ dgamma(10,10)
  nu1 ~ dgamma(10,10)
  nu2 ~ dgamma(10,10)
}
"

model <- jags.model(textConnection(model_string), data = list(x=c(x)),n.chains=2)
#> Compiling model graph
#>    Resolving undeclared variables
#>    Allocating nodes
#> Graph information:
#>    Observed stochastic nodes: 100
#>    Unobserved stochastic nodes: 4
#>    Total graph size: 107
#> 
#> Initializing model

samples<- coda.samples(model, variable.names = c("mu", "tau", "nu1", "nu2"), n.iter = 2000)

summary(samples)
#> 
#> Iterations = 1001:3000
#> Thinning interval = 1 
#> Number of chains = 2 
#> Sample size per chain = 2000 
#> 
#> 1. Empirical mean and standard deviation for each variable,
#>    plus standard error of the mean:
#> 
#>       Mean       SD  Naive SE Time-series SE
#> mu  1.9983 0.009828 0.0001554       0.000200
#> nu1 0.7453 0.067906 0.0010737       0.002470
#> nu2 1.1697 0.162207 0.0025647       0.005628
#> tau 0.9481 0.262861 0.0041562       0.010301
#> 
#> 2. Quantiles for each variable:
#> 
#>       2.5%    25%    50%    75%  97.5%
#> mu  1.9798 1.9917 1.9982 2.0046 2.0175
#> nu1 0.6302 0.6985 0.7399 0.7856 0.8973
#> nu2 0.8933 1.0543 1.1520 1.2679 1.5258
#> tau 0.5336 0.7650 0.9177 1.1027 1.5538

traceplot(samples)

model1 <- jags.model(textConnection(model_string1),  n.chains=2)
#> Compiling model graph
#>    Resolving undeclared variables
#>    Allocating nodes
#> Graph information:
#>    Observed stochastic nodes: 0
#>    Unobserved stochastic nodes: 0
#>    Total graph size: 5
#> 
#> Initializing model

samples1<- coda.samples(model1, variable.names = c("d","p","q"), n.iter = 2)

summary(samples1)
#> 
#> Iterations = 1:2
#> Thinning interval = 1 
#> Number of chains = 2 
#> Sample size per chain = 2 
#> 
#> 1. Empirical mean and standard deviation for each variable,
#>    plus standard error of the mean:
#> 
#>       Mean SD Naive SE Time-series SE
#> d 0.008864  0        0              0
#> p 0.001350  0        0              0
#> q 2.000000  0        0              0
#> 
#> 2. Quantiles for each variable:
#> 
#>       2.5%      25%      50%      75%    97.5%
#> d 0.008864 0.008864 0.008864 0.008864 0.008864
#> p 0.001350 0.001350 0.001350 0.001350 0.001350
#> q 2.000000 2.000000 2.000000 2.000000 2.000000