Chapter 11 - God Spiked the Integers

This chapter described some of the most common generalized linear models, those used to model counts. It is important to never convert counts to proportions before analysis, because doing so destroys information about sample size. A fundamental difficulty with these models is that parameters are on a different scale, typically log-odds (for binomial) or log-rate (for Poisson), than the outcome variable they describe. Therefore computing implied predictions is even more important than before.

Place each answer inside the code chunk (grey box). The code chunks should contain a text response or a code that completes/answers the question or activity requested. Problems are labeled Easy (E), Medium (M), and Hard(H).

Finally, upon completion, name your final output .html file as: YourName_ANLY505-Year-Semester.html and publish the assignment to your R Pubs account and submit the link to Canvas. Each question is worth 5 points.

Questions

11E1. If an event has probability 0.35, what are the log-odds of this event?

p <- 0.35
odds <- p/(1-p)
log_odds <- log(odds)
log_odds
## [1] -0.6190392
#The log-odds of this event is -0.62.

11E2. If an event has log-odds 3.2, what is the probability of this event?

log_odds <- 3.2
odds <- exp(log_odds)
p <- odds/(1+odds)
p
## [1] 0.9608343
#The probability of this event is 0.96.

11E3. Suppose that a coefficient in a logistic regression has value 1.7. What does this imply about the proportional change in odds of the outcome?

exp(1.7)
## [1] 5.473947
#This indicates that we will see 1.7 times change in the log-odds of the outcome, or 5.47 times change in the odds of the outcome.

11E4. Why do Poisson regressions sometimes require the use of an offset? Provide an example.

#Offset is required when time/distance varies across cases. For example, six cases over 1 year should not amount to the same as six cases over 10 years.

11M1. As explained in the chapter, binomial data can be organized in aggregated and disaggregated forms, without any impact on inference. But the likelihood of the data does change when the data are converted between the two formats. Can you explain why?

#The aggregated model contains an extra factor in its log-probabilities due to the way the data organized. When we use dbinom(), it contains a term for all the orders the successes could appear in trials. It counts all the ways you could see successes in trials.
#This makes the aggregated probabilities larger, so the PSIS/WAIC scores end up being smaller.

11M2. If a coefficient in a Poisson regression has value 1.7, what does this imply about the change in the outcome?

#For a one unit change in the predictor variable, the difference in the log of outcome is expected to change by 1.7.

11M3. Explain why the logit link is appropriate for a binomial generalized linear model.

#The logit link maps a parameter that is defined as a probability mass, and therefore constrained to lie between 0 and 1, which is the output of binomial generalized linear model.

11M4. Explain why the log link is appropriate for a Poisson generalized linear model.

#The log link maps a parameter that is defined over only positive real values onto a linear model. This works well with Poisson distribution, where the outcome are counts and always positive values.

11M5. What would it imply to use a logit link for the mean of a Poisson generalized linear model? Can you think of a real research problem for which this would make sense?

#Using logit link implies that a lambda parameter of the Poisson likelihood always falls in [0, +inf) range.

11M6. State the constraints for which the binomial and Poisson distributions have maximum entropy. Are the constraints different at all for binomial and Poisson? Why or why not?

#The constraints for binomial distribution are that the events are discrete and the expect value is constant.
#Poisson distribution constraints are that the variance is equal to expected value and both are constant.
#Poisson has more constraints than binomial, because it is a special case of binomial distribution and it has its own constraints.

11M7. Use quap to construct a quadratic approximate posterior distribution for the chimpanzee model that includes a unique intercept for each actor, m11.4 (page 330). Compare the quadratic approximation to the posterior distribution produced instead from MCMC. Can you explain both the differences and the similarities between the approximate and the MCMC distributions? Relax the prior on the actor intercepts to Normal(0,10). Re-estimate the posterior using both ulam and quap. Do the differences increase or decrease? Why?

library(rethinking)
data("chimpanzees")
d <- chimpanzees
d$recipient <- NULL

# map
q2 <- map(alist(
  pulled_left ~ dbinom( 1 , p ) ,
  logit(p) <- a[actor] + (bp + bpC*condition)*prosoc_left ,
  a[actor] ~ dnorm(0,10),
  bp ~ dnorm(0,10),
  bpC ~ dnorm(0,10)
) ,
data=d)
pairs(q2)

#Posterior mean and standard deviation are very close. MCMC model's posterior std is slightly higher.

11M8. Revisit the data(Kline) islands example. This time drop Hawaii from the sample and refit the models. What changes do you observe?

data(Kline)
d <- Kline
d$P <- scale( log(d$population) )
d$contact_id <- ifelse( d$contact=="high" , 2 , 1 )
d
##       culture population contact total_tools mean_TU            P contact_id
## 1    Malekula       1100     low          13     3.2 -1.291473310          1
## 2     Tikopia       1500     low          22     4.7 -1.088550750          1
## 3  Santa Cruz       3600     low          24     4.0 -0.515764892          1
## 4         Yap       4791    high          43     5.0 -0.328773359          2
## 5    Lau Fiji       7400    high          33     5.0 -0.044338980          2
## 6   Trobriand       8000    high          19     4.0  0.006668287          2
## 7       Chuuk       9200    high          40     3.8  0.098109204          2
## 8       Manus      13000     low          28     6.6  0.324317564          1
## 9       Tonga      17500    high          55     5.4  0.518797917          2
## 10     Hawaii     275000     low          71     6.6  2.321008320          1

11H1. Use WAIC or PSIS to compare the chimpanzee model that includes a unique intercept for each actor, m11.4 (page 330), to the simpler models fit in the same section. Interpret the results.

d <- chimpanzees

m11.1 <- map(
  alist(
    pulled_left ~ dbinom(1, p),
    logit(p) <- a ,
    a ~ dnorm(0,10)
  ),
  data=d )


m11.2 <- map(
  alist(
    pulled_left ~ dbinom(1, p) ,
    logit(p) <- a + bp*prosoc_left ,
    a ~ dnorm(0,10) ,
    bp ~ dnorm(0,10)
  ),
  data=d )

m11.3 <- map(
  alist(
    pulled_left ~ dbinom(1, p) ,
    logit(p) <- a + (bp + bpC*condition)*prosoc_left ,
    a ~ dnorm(0,10) ,
    bp ~ dnorm(0,10) ,
    bpC ~ dnorm(0,10)
  ), data=d )

m11.4 <- map(
  alist(
    pulled_left ~ dbinom(1, p),
    logit(p) <- a[actor] + (bp + bpC*condition)*prosoc_left,
    a[actor] ~ dnorm(0, 10),
    bp ~ dnorm(0, 10),
    bpC ~ dnorm(0, 10)
  ),
  data = d)

compare(m11.1,m11.2,m11.3,m11.4)
##           WAIC        SE    dWAIC      dSE      pWAIC       weight
## m11.4 547.3890 18.746728   0.0000       NA 14.3094736 1.000000e+00
## m11.2 680.5695  9.278089 133.1805 18.16391  2.0361138 1.202872e-29
## m11.3 682.5411  9.406530 135.1521 18.11456  3.1004237 4.488406e-30
## m11.1 687.8069  7.017341 140.4180 18.97530  0.9320247 3.225705e-31
#H11.4 with the unique intercepts for each chimp wins.