I would like to estimate power of the following problem. I am interested in comparing two groups that both follow Weibull distribution. So, group A has two parameters (shape par = a1,scale par = b1) and two parameters has group B (a2, b2). By simulating random variables from distribution of interest (for example assuming different scale and shape parameters, i.e. a1=1.5*a2, and b1=b2*0.5; or either differences between groups are just in either shape or scale parameters), apply log-likelihood ratio test to test if a1=a2 and b1=b2 (or e.g. a1=a1, when we know that b1=b2), and estimate power of the test.

The questions would be what are log-likelihoods for the full models, and how to code it in R when a)having exact data, and b) for interval-censored data ?

That is, for reduced model (when a1=a2,b1=b2) log-likelihoods for exact and interval-censored data are:

```
LL.reduced.exact <- function(par,data){sum(log(dweibull(data,shape=par[1],scale=par[2])))};
LL.reduced.interval.censored<-function(par, data.lower, data.upper) {sum(log((1-pweibull(data.lower, par[1], par[2])) – (1-pweibull(data.upper, par[1],par[2]))))}
```

What is it for the full model, when a1!=a2, b1!=b2, taking into account two different observational schemes, i.e. when 4 parameters have to be estimated (or, in case when interested in looking at diferences in shape parameters, 3 parameters have to be estimated)?

Is it possible to estimate it buy building two log-likelihoods for separate groups and add it together (i.e.**LL.full<-LL.group1+LL.group2**)?

Regarding log-likelihood for interval-censored data, censoring is non-informative and all observations are interval-censored. Any better ideas how to perform this task will be appreciated.

Please, find the R Code for exact data below to illustrate the problem. Thank you very much in advance.

```
R Code:
# n (sample size) = 500
# sim (number of simulations) = 1000
# alpha = .05
# Parameters of Weibull distributions:
#group 1: a1=1, b1=20
#group 2: a2=1*1.5 b2=b1
n=500
sim=1000
alpha=.05
a1=1
b1=20
a2=a1*1.5
b2=b1
#OR: a1=1, b1=20, a2=a1*1.5, b2=b1*0.5
# the main question is how to build this log-likelihood model, when a1!=a2, and b1=b2
# (or a1!=a2, and b1!=b2)
LL.full<-?????
LL.reduced <- function(par,data){sum(log(dweibull(data,shape=par[1],scale=par[2])))}
LR.test<-function(red,full,df) {
lrt<-(-2)*(red-full)
pvalue<-1-pchisq(lrt,df)
return(data.frame(lrt,pvalue))
}
rejections<-NULL
for (i in 1:sim) {
RV1<-rweibull (n, a1, b1)
RV2<-rweibull (n, a2, b2)
RV.Total<-c(RV1, RV2)
par.start<-c(1, 15)
mle.full<- ????????????
mle.reduced<-optim(par.start, LL, data=RV.Total, control=list(fnscale=-1))
LL.full<-?????
LL.reduced<-mle.reduced$value
LRT<-LR.test(LL.reduced, LL.full, 1)
rejections1<-ifelse(LRT$pvalue<alpha,1,0)
rejections<-c(rejections, rejections1)
}
table(rejections)
sum(table(rejections)[[2]])/sim # estimated power
```