[R] Profile confidence intervals and LR chi-square test

Tue Nov 14 18:42:32 CET 2006

Thank you to Prof Ripley and Henric Nilsson for their observation that I
was using "anova" inappropriately for the question that I was trying to
answer. Note that the Wald statistics and confidence interval were
calculable in the previous email but that I prefered using the more
accurate deviance statistics.  I will demonstrate my error for the
benefit of those new users of R (like me) that may not have appreciated
how the "anova" function is working SEQUENTIALLY, and what SEQUENTIALLY
actually means in this context.

Since the "anova" function is a sequential test of the current model,
only the statistic for the last term in the model formula is a true
deviance chi-square statistic for (full model) .vs. (full model - term).
For instance, using the data upon which this question was based,
consider the following 2 models:

----------------------

> fit0 <- glm(y ~ 1, data=d, family=binomial(link=logit),
na.action=na.omit)
> fit1 <- update(fit0, . ~ . + x1 + x2 + x3)

----------------------

Here, fit0 is the null (intercept-only) model and fit1 is the full model
(without interactions because interactions are not biologically
plausible in this medical dataset). Now notice the result of the "anova"
function for the full model:

----------------------

> anova(fit1, test='Chisq')

...

     Df Deviance Resid. Df Resid. Dev P(>|Chi|)
NULL                    99    137.989          
x1    1    8.267        98    129.721     0.004
x2    1    5.639        97    124.083     0.018
x3    1    3.433        96    120.650     0.064

-----------------------

It is incorrect to interpret the deviance chi-square test presented
above for x1 (P=0.004) as the deviance chi-square statistic comparing
(y~x1+x2+x3) .vs. (y~x2+x3) as the statistic calculated is for (y~1)
.vs. (y~x1). Similarly, the deviance chi-square statistic calculated for
x2 (P=0.018) is NOT for (y~x1+x2+x3) .vs. (y~x1+x3) but for (y~x1) .vs.
(y~x1+x2).  Lastly, the deviance chi-square statistic for x3(P=0.064) is
probably the most intuitive because it is for the comparison of
(y~x1+x2+x3) .vs. (y~x1+x2), the result we would typically want to
present for x3 in the full model.  So how do you get the correct
deviance chi-square statistics for x1 and x2 in the full model?  There
are a couple of ways of arriving at the same answer as I will
demonstrate for the case of x1.

Option#1: Reorder the full model so that x1 is the last term in the
model formula

-----------------------

> fit2 <- glm(y ~ x2 + x3 + x1, data=d, family=binomial(link=logit),
na.action=na.omit)
> anova(fit2, test='Chisq')
...

     Df Deviance Resid. Df Resid. Dev P(>|Chi|)
NULL                    99    137.989          
x2    1    7.305        98    130.683     0.007
x3    1    3.821        97    126.862     0.051
x1    1    6.212        96    120.650     0.013

-----------------------

Notice that the deviance chi-square statistics for all of the variables
have changed, despite fit2 being identical in content to fit1. Just the
order of the terms in the model formula have changed from fit1 to fit2.
The deviance statistic for x1 is now the correct one for the full model,
that is for the comparison (y~x1+x2+x3) .vs. (y~x2+x3).

Option#2: Compare the full model to a reduced model that does not
include x1.

-----------------------

> fit3 <- update(fit1, . ~ . - x1)
> anova(fit1, fit3, test='Chisq')
...

Model 1: y ~ x1 + x2 + x3
Model 2: y ~ x2 + x3
  Resid. Df Resid. Dev Df Deviance P(>|Chi|)
1        96    120.650                      
2        97    126.862 -1   -6.212     0.013

-----------------------

Fit3 is the same model as fit1 except that it is missing the x1 term.
Therefore, any change in the deviance chi-square statistic is due to the
deletion of x1 from full model. Notice that the difference in residual
deviances between fit3 and fit1 (126.862 - 120.650 = 6.212) is the same
the difference b/t x1 and x3 in option#1.

Brant