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I would like to be able to plot the profile deviance for a parameter estimate fitted using the function glm() in R. The profile Deviance is the deviance function for different values of the parameter estimate in question, after estimating all other parameters. I need to plot the deviance for several values around the fitted parameter, to check the assumption of quadratic deviance function.

My model is predicting reconviction of offenders. The formula is of the form: reconv ~ [other variables] + sex, where reconv is a binary yes/no factor, and sex is binary male/female factor. I'd like to plot the profile deviance of the parameter estimated for sex=female (sex=male is the reference level).

The glm() function estimated the parameter as -0.22, with std error 0.12.

[I'm asking this question because there was no answer I could find, but I worked it out, and wanted to post a solution to be of use to others. Of course, additional help is welcome. :-)]

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3 Answers

up vote 6 down vote accepted

See the profileModel package by Ioannis Kosmidis. He had a paper in the R Journal (R News it would appear) illustrating the package:

Ioannis Kosmidis. The profilemodel R package: Profiling objectives for models with linear predictors. R News, 8(2):12-18, October 2008.

The PDF is here (entire newsletter).

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Thanks Gavin. That looks like exactly the kind of thing I was looking for. I didn't realise people would reply so quickly. My answer was just a bit of code, it seems a bit redundant now :-/ –  MatW Mar 20 '12 at 14:10
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No, do post it --- as many examples of different ways to do things might help an unsuspecting user in the future. –  Gavin Simpson Mar 20 '12 at 14:12
    
I've just discovered I can't post for seven hours because my reputation isn't high enough. I'll post it later. Thanks for your help. –  MatW Mar 20 '12 at 14:15
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See ?profile.glm (and example("profile.glm")) in the MASS package -- I think it will do everything you want (this is not loaded by default, but it is mentioned in ?profile, which might have been the first place you looked ...) (Note that the profiles are generally plotted on a signed-square-root scale, so that a truly quadratic profile will appear as a straight line.)

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Thanks Ben. I did try that, but didn't understand exactly what the plot was telling me, since I was expecting an inverse quadratic shape rather than a straight line. It makes more sense now - thanks. –  MatW Mar 20 '12 at 14:05
    
OK, fair enough. In future it would be wise to add these details to your question (e.g., "I found profile.glm, but it didn't seem to be giving sensible answers for my question"). –  Ben Bolker Mar 20 '12 at 14:32
    
+1 That is a useful comment on profile.glm() @BenBolker; something like this cropped up somewhere (CV?) last week and I was stumped for the few minutes I spent with profile.glm() before going back to the day job. I missed the "signed-square-root" bit. –  Gavin Simpson Mar 20 '12 at 15:01
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The way I found to do this involves using the offset() function (as detailed in Pawitan, Y. (2001) 'In All Likelihood' p172). The answers given by @BenBolker and @GavinSimpson are better than this, in that they referenced packages which will do everything this does and a lot more. I'm posting this because its another way round it, and also, plotting things "manually" is sometimes nice for learning. It taught me a lot.

sexi <- as.numeric(data.frame$sex)-1      #recode a factor as 0/1 numeric

beta <- numeric(60)              #Set up vector to Store the betas
deviance <- numeric(60)          #Set up vector to Store the deviances

for (i in 1:60){

  beta[i] <- 0.5 - (0.01*i)  
  #A vector of values either side of the fitted MLE (in this case -0.22)

  mod <- update(model,
                   .~. - sex             #Get rid of the fitted variable
                   + offset(   I(sexi*beta[i])   )   #Replace with offset term.
                )
  deviance[i] <- mod$deviance                        #Store i'th deviance
}

best <- which.min(deviance)                   
#Find the index of best deviance. Should be the fitted value from the model

deviance0 <- deviance - deviance[best]         
#Scale deviance to zero by subtracting best deviance

betahat <- beta[best]    #Store best beta. Should be the fitted value.
stderror <- 0.12187      #Store the std error of sex, found in summary(model)

quadratic <- ((beta-betahat)^2)*(1/(stderror^2))  
#Quadratic reference function to check quadratic assumption against

x11()                                    
plot(beta,deviance0,type="l",xlab="Beta(sex)",ylim=c(0,4))    
lines(beta,quadratic,lty=2,col=3)           #Add quadratic reference line
abline(3.84,0,lty=3)                #Add line at Deviance = 3.84
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