24_deb_pkg_gov/R/powerAnalysis.R

# This is semi-generic code for doing a power analysis of a logistic regression with 4
# levels in a factor
# when there's some pilot values already available and defined
#modelled heavily the simulation example explained in:
#http://meeting.spsp.org/2016/sites/default/files/Lane%2C%20Hennes%2C%20West%20SPSP%20Power%20Workshop%202016.pdf

library('batman')
library('reshape')

l2p <- function(b) {
 odds <- exp(b) 
 prob <- odds/(1+odds)
 return(prob)
}


#Matt: 
makeDataNew <- function(n) {
  tDF <- data.frame(
    ## don't sim the outcome
    #up.fac.mean=rnorm(n=n, mean=-0.1296376, sd=1.479847), # up.fac.mean
    mmt=rlnorm(n=n, mean=1.685715, sd = 0.2532059), # mmt
    #mmt=rlogis(n=n, location = 1.685715),
    ## this generates a 50-50 split of milestones --v
    #milestones=rbinom(n=n, size=1, prob=c(0.247, 0.753)), #milestones
    milestones=rbinom(n=n, size=1, prob=.247), #milestones
    age=rnorm(n=n, mean=4351.578, sd=1408.811) # age
  )
  #sDF <- melt(tDF, id.vars = 0) #AKA the index is the unique id, as far as that goes
  ## can name these in the data.frame constructor method directly
  #colnames(tDF) <- c('up.fac.mean', 'mmt', 'milestones', 'age')
  return(tDF)
}

makeDataNew2 <- function(n) {
  tDF <- data.frame(
    ## don't sim the outcome
    #up.fac.mean=rnorm(n=n, mean=-0.1296376, sd=1.479847), # up.fac.mean
    formal.score=rlnorm(n=n, mean=6.220282, sd = 2.544058) # formal.score
  )
  tDF[is.na(tDF) | tDF=="Inf"] = NA
  #sDF <- melt(tDF, id.vars = 0) #AKA the index is the unique id, as far as that goes
  ##colnames(tDF) <- c('up.fac.mean', 'formal.score')
  return(tDF)
}


powerCheck <- function(n, nSims) { #run a power calculation on the dataset given
  #set up some empty arrays b/c R
  signif0 <- rep(NA, nSims)
  signif1 <- rep(NA, nSims)
  signif2 <- rep(NA, nSims)
  signif3 <- rep(NA, nSims)
  signifM <- rep(NA, nSims)
  for (s in 1:nSims) {           # repeatedly we will....
    simData <- makeDataNew(n)       # make some data
    ## outcome goes here --v
    # e.g. simData$up.fac.mean <- (usefuleffsizeA * mmt) + (usefuleffsizeB * milestones) + rnorm(n=1, mean=0, sd=1) ##plus some noise
    simData$up.fac.mean <- (-2.075 * simData$mmt) + (0.4284  * simData$milestones) + rnorm(n=1, mean=0, sd=1)
    #have updated for kkex through here, now need to look at the underproduction work
    #m1.sim <- lm(up.fac.mean ~ ((mmt)/ (milestones/age)), data=simData)
    ## could leave age out for now?
    #m1.sim <- lm(up.fac.mean ~ mmt + milestones + age, data=simData)
    m1.sim <- lm(up.fac.mean ~ mmt + milestones, data=simData)
    p0 <- coef(summary(m1.sim))[1,4] #intercept
    p1 <- coef(summary(m1.sim))[2,4] #mmt
    p2 <- coef(summary(m1.sim))[3,4] #milestones
    #p3 <- coef(summary(m1.sim))[4,4] #age
    signif0[s] <- p0 <=.05
    signif1[s] <- p1 <=.05
    signif2[s] <- p2 <=.05
    #signif3[s] <- p3 <=.05
    signifM[s] <- p0 <=.05 & p1 <=.05 & p2 <=.05 #& p3 <=.05
  }  
  power <- c(mean(signif0), mean(signif1), mean(signif2), mean(signif3), mean(signifM))
  return(power)
}

powerCheck2 <- function(n, nSims) { #run a power calculation on the dataset given
  #set up some empty arrays b/c R
  signif0 <- rep(NA, nSims)
  signif1 <- rep(NA, nSims)
  signifM <- rep(NA, nSims)
  for (s in 1:nSims) {           # repeatedly we will....
    simData <- makeDataNew2(n)       # make some data
    #have updated for kkex through here, now need to look at the underproduction work
    #m1.sim <- lm(up.fac.mean ~ ((mmt)/ (milestones/age)), data=simData)
    ## outcome goes here --v
    simData$up.fac.mean <- (0.5 * simData$formal.score) + rnorm(1, mean=0, sd=1) ##plus some noise
    m1.sim <- lm(up.fac.mean ~ formal.score, data=simData)
    p0 <- coef(summary(m1.sim))[1,4] 
    p1 <- coef(summary(m1.sim))[2,4]
    signif0[s] <- p0 <=.05 
    signif1[s] <- p1 <=.05
    signifM[s] <- p0 <=.05 & p1 <=.05 
  }  
  power <- c(mean(signif0), mean(signif1), mean(signifM))
  return(power)
}