I am trying to compute this posterior distribution in R. The problem is that the numerator, which is the product of a bunch of dbern(p_i, y_i) < 1, is too small. (My n is about 1500). Hence, R spits out 0, and the posterior values for all \theta are also 0.

To clarify, each y_i has its own p_i, together these p_i's make a vector of n elements for n y's. Each theta has its own n-element vector of p_i.

A reproducible example (of the numerator)

```
p <- sample(seq(0.001,0.999,by=0.01), 1500, replace=T)
y <- sample(c(0,1), 1500, replace=T)
dbern(y, p) # 1500-element vector, each element < 1
prod(dbern(y, p)) # produces 0
exp(sum(log(dbern(y, p)))) # produces 0
```

EDIT (context): I am doing a Bayesian change point analysis (jstor.org/stable/25791783 - Western and Kleykamp 2004). Unlike the continuous y in the paper, my y is binary, so I'm using the data augmentation method in Albert and Chib (1993). With that method, the likelihood of y is Bernoulli, with p = cdf-normal(x'B).

So how does p depends on theta? It's because theta is the change point. One of the x's is a time dummy -- if theta=10, for example, then the time dummy = 1 for all observations after day 10, and = 0 for all observations before day 10.

Thus, p depends on x, x depends on theta -- thus, p depends on theta.

I need the above quantity because is the full conditional of theta in Gibbs sampling.

`log.likelihood`

– Nishanth Apr 21 '13 at 2:44`p_i|theta`

is defined? – Ben Bolker Apr 22 '13 at 1:41