# Hierarchical Normal Example (nimble)

#### 2021-04-15

In this vignette, we explain how one can compute marginal likelihoods, Bayes factors, and posterior model probabilities using a simple hierarchical normal model implemented in nimble. The nimble documentation provides a comprehensive overview. This vignette uses the same models and data as the Stan vignette and Jags vignette.

## Model and Data

The model that we will use assumes that each of the $$n$$ observations $$y_i$$ (where $$i$$ indexes the observation, $$i = 1,2,...,n$$) is normally distributed with corresponding mean $$\theta_i$$ and a common known variance $$\sigma^2$$: $$y_i \sim \mathcal{N}(\theta_i, \sigma^2)$$. Each $$\theta_i$$ is drawn from a normal group-level distribution with mean $$\mu$$ and variance $$\tau^2$$: $$\theta_i \sim \mathcal{N}(\mu, \tau^2)$$. For the group-level mean $$\mu$$, we use a normal prior distribution of the form $$\mathcal{N}(\mu_0, \tau^2_0)$$. For the group-level variance $$\tau^2$$, we use an inverse-gamma prior of the form $$\text{Inv-Gamma}(\alpha, \beta)$$.

In this example, we are interested in comparing the null model $$\mathcal{H}_0$$, which posits that the group-level mean $$\mu = 0$$, to the alternative model $$\mathcal{H}_1$$, which allows $$\mu$$ to be different from zero. First, we generate some data from the null model:

library(bridgesampling)

### generate data ###
set.seed(12345)

mu <- 0
tau2 <- 0.5
sigma2 <- 1

n <- 20
theta <- rnorm(n, mu, sqrt(tau2))
y <- rnorm(n, theta, sqrt(sigma2))

Next, we specify the prior parameters $$\mu_0$$, $$\tau^2_0$$, $$\alpha$$, and $$\beta$$:

### set prior parameters ###
mu0 <- 0
tau20 <- 1
alpha <- 1
beta <- 1

## Specifying the Models

Next, we implement the models in nimble. This requires to first transform the code into a nimbleModel, then we need to set the data, and then we can compile the model. Given that nimble is build on BUGS, the similarity between the nimble code and the Jags code is not too surprising.

library("nimble")

# models
codeH0 <- nimbleCode({
invTau2 ~ dgamma(1, 1)
tau2 <- 1/invTau2
for (i in 1:20) {
theta[i] ~ dnorm(0, sd = sqrt(tau2))
y[i] ~ dnorm(theta[i], sd = 1)
}
})
codeH1 <- nimbleCode({
mu ~ dnorm(0, sd = 1)
invTau2 ~ dgamma(1, 1)
tau2 <- 1/invTau2
for (i in 1:20) {
theta[i] ~ dnorm(mu, sd = sqrt(tau2))
y[i] ~ dnorm(theta[i], sd = 1)
}
})

## steps for H0:
modelH0 <- nimbleModel(codeH0)
modelH0$setData(y = y) # set data cmodelH0 <- compileNimble(modelH0) # make compiled version from generated C++ ## steps for H1: modelH1 <- nimbleModel(codeH1) modelH1$setData(y = y) # set data
cmodelH1 <- compileNimble(modelH1) # make compiled version from generated C++

## Fitting the Models

Fitting a model with nimble requires one to first create an MCMC function from the (compiled or uncompiled) model. This function then needs to be compiled again. With this object we can then create the samples. Note that nimble uses a reference object semantic so we do not actually need the samples object, as the samples will be saved in the MCMC function objects. But as runMCMC returns them anyway, we nevertheless save them.

One usually requires a larger number of posterior samples for estimating the marginal likelihood than for simply estimating the model parameters. This is the reason for using a comparatively large number of samples for these simple models.

# build MCMC functions, skipping customization of the configuration.
mcmcH0 <- buildMCMC(modelH0,
monitors = modelH0$getNodeNames(stochOnly = TRUE, includeData = FALSE)) mcmcH1 <- buildMCMC(modelH1, monitors = modelH1$getNodeNames(stochOnly = TRUE,
includeData = FALSE))
# compile the MCMC function via generated C++
cmcmcH0 <- compileNimble(mcmcH0, project = modelH0)
cmcmcH1 <- compileNimble(mcmcH1, project = modelH1)

# run the MCMC.  This is a wrapper for cmcmc$run() and extraction of samples. # the object samplesH1 is actually not needed as the samples are also in cmcmcH1 samplesH0 <- runMCMC(cmcmcH0, niter = 1e5, nburnin = 1000, nchains = 2, progressBar = FALSE) samplesH1 <- runMCMC(cmcmcH1, niter = 1e5, nburnin = 1000, nchains = 2, progressBar = FALSE) ## Computing the (Log) Marginal Likelihoods Computing the (log) marginal likelihoods via the bridge_sampler function is now easy: we only need to pass the compiled MCMC function objects (of class "MCMC_refClass") which contain all information necessary. We use silent = TRUE to suppress printing the number of iterations to the console: # compute log marginal likelihood via bridge sampling for H0 H0.bridge <- bridge_sampler(cmcmcH0, silent = TRUE) # compute log marginal likelihood via bridge sampling for H1 H1.bridge <- bridge_sampler(cmcmcH1, silent = TRUE) We obtain: print(H0.bridge) ## Bridge sampling estimate of the log marginal likelihood: -37.52918 ## Estimate obtained in 4 iteration(s) via method "normal". print(H1.bridge) ## Bridge sampling estimate of the log marginal likelihood: -37.80257 ## Estimate obtained in 4 iteration(s) via method "normal". We can use the error_measures function to compute an approximate percentage error of the estimates: # compute percentage errors H0.error <- error_measures(H0.bridge)$percentage
H1.error <- error_measures(H1.bridge)\$percentage

We obtain:

print(H0.error)
## [1] "0.2%"
print(H1.error)
## [1] "0.22%"

## Bayesian Model Comparison

To compare the null model and the alternative model, we can compute the Bayes factor by using the bf function. In our case, we compute $$\text{BF}_{01}$$, that is, the Bayes factor which quantifies how much more likely the data are under the null versus the alternative model:

# compute Bayes factor
BF01 <- bf(H0.bridge, H1.bridge)
print(BF01)
## Estimated Bayes factor in favor of H0.bridge over H1.bridge: 1.31441

In this case, the Bayes factor is close to one, indicating that there is not much evidence for either model. We can also compute posterior model probabilities by using the post_prob function:

# compute posterior model probabilities (assuming equal prior model probabilities)
post1 <- post_prob(H0.bridge, H1.bridge)
print(post1)
## H0.bridge H1.bridge
## 0.5679244 0.4320756

When the argument prior_prob is not specified, as is the case here, the prior model probabilities of all models under consideration are set equal (i.e., in this case with two models to 0.5). However, if we had prior knowledge about how likely both models are, we could use the prior_prob argument to specify different prior model probabilities:

# compute posterior model probabilities (using user-specified prior model probabilities)
post2 <- post_prob(H0.bridge, H1.bridge, prior_prob = c(.6, .4))
print(post2)
## H0.bridge H1.bridge
## 0.6634826 0.3365174