Model fitting using normalized power priors for two groups (treatment and control group, no covariates) with random \(a_0\)
two.grp.random.a0(
data.type,
y.c,
n.c,
v.c,
historical,
prior.mu.c.shape1 = 1,
prior.mu.c.shape2 = 1,
prior.a0.shape1 = rep(1, 10),
prior.a0.shape2 = rep(1, 10),
lower.limits = rep(0, 10),
upper.limits = rep(1, 10),
slice.widths = rep(0.1, 10),
nMC = 10000,
nBI = 250
)The function returns a S3 object with a summary method. If data.type is "Normal", posterior samples of \(\mu_c\), \(\tau\) and \(a_0\) are returned.
For all other data types, posterior samples of \(\mu_c\) and \(a_0\) are returned. If there are \(K\) historical datasets,
then \(a_0 = (a_{01},\cdots,a_{0K})\).
Character string specifying the type of response. The options are "Normal", "Bernoulli", "Poisson" and "Exponential".
Sum of responses for the control group.
Sample size of the control group.
(For normal data only) sample variance of responses for the control group.
Matrix of historical dataset(s). If data.type is "Normal", historical is a matrix with three columns:
The first column contains the sum of responses for the control group.
The second column contains the sample size of the control group.
The third column contains the sample variance of responses for the control group.
For all other data types, historical is a matrix with two columns:
The first column contains the sum of responses for the control group.
The second column contains the sample size of the control group.
Each row represents a historical dataset.
First hyperparameter of the initial prior for \(\mu_c\). The default is 1. Does not apply if data.type is "Normal".
Second hyperparameter of the initial prior for \(\mu_c\). The default is 1. Does not apply if data.type is "Normal".
Vector of the first shape parameters of the independent beta priors for \(a_0\). The length of the vector should be equal to the number of historical datasets. The default is a vector of one's.
Vector of the second shape parameters of the independent beta priors for \(a_0\). The length of the vector should be equal to the number of historical datasets. The default is a vector of one's.
Vector of lower limits for parameters to be used by the slice sampler. The length of the vector should be equal to the number of historical datasets. The default is 0 for all parameters (may not be appropriate for all situations).
Vector of upper limits for parameters to be used by the slice sampler. The length of the vector should be equal to the number of historical datasets. The default is 1 for all parameters (may not be appropriate for all situations).
Vector of initial slice widths used by the slice sampler. The length of the vector should be equal to the number of historical datasets. The default is 0.1 for all parameter (may not be appropriate for all situations).
Number of iterations (excluding burn-in samples) for the slice sampler or Gibbs sampler. The default is 10,000.
Number of burn-in samples for the slice sampler or Gibbs sampler. The default is 250.
If data.type is "Bernoulli", "Poisson" or "Exponential", a single response from the treatment group is assumed to follow Bern(\(\mu_t\)), Pois(\(\mu_t\)) or Exp(rate=\(\mu_t\)), respectively,
where \(\mu_t\) is the mean of responses for the treatment group. If data.type is "Normal", a single response from the treatment group is assumed to follow \(N(\mu_t, \tau^{-1})\)
where \(\tau\) is the precision parameter.
The distributional assumptions for the control group data are analogous.
If data.type is "Bernoulli", the initial prior for \(\mu_t\) is beta(prior.mu.t.shape1, prior.mu.t.shape2).
If data.type is "Poisson", the initial prior for \(\mu_t\) is Gamma(prior.mu.t.shape1, rate=prior.mu.t.shape2).
If data.type is "Exponential", the initial prior for \(\mu_t\) is Gamma(prior.mu.t.shape1, rate=prior.mu.t.shape2).
The initial priors used for the control group data are analogous.
If data.type is "Normal", historical datasets are assumed to have the same precision parameter \(\tau\) as the current dataset for computational simplicity.
The initial prior for \(\tau\) is the Jeffery's prior, \(\tau^{-1}\). The initial prior for the \(\mu_c\) is the uniform improper prior.
Posterior samples of \(\mu_c\) and \(\tau\) are obtained through Gibbs sampling.
Independent beta(prior.a0.shape1,prior.a0.shape1) priors are used for \(a_0\). Posterior samples of \(a_0\) are obtained through slice sampling. The default lower limits for the parameters are 0. The default upper limits
for the parameters are 1. The default slice widths for the parameters are 0.1.
The defaults may not be appropriate for all situations, and the user can specify the appropriate limits
and slice width for each parameter.
Neal, Radford M. Slice sampling. Ann. Statist. 31 (2003), no. 3, 705--767.
power.two.grp.random.a0
data.type <- "Bernoulli"
y.c <- 70
n.c <- 100
# Simulate three historical datasets
historical <- matrix(0, ncol=2, nrow=3)
historical[1,] <- c(70, 100)
historical[2,] <- c(60, 100)
historical[3,] <- c(50, 100)
# Set parameters of the slice sampler
lower.limits <- rep(0, 3) # The dimension is the number of historical datasets
upper.limits <- rep(1, 3)
slice.widths <- rep(0.1, 3)
set.seed(1)
result <- two.grp.random.a0(data.type=data.type, y.c=y.c, n.c=n.c, historical=historical,
lower.limits=lower.limits, upper.limits=upper.limits,
slice.widths=slice.widths, nMC=10000, nBI=250)
summary(result)
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