This was annoying me, so I decided to work it out from first principles.
Re-fit the model:
d <- data.frame(weight=
lm.D9 <- lm(weight ~ group, d)
Values returned by standard accessors:
(AIC1 <- AIC(lm.D9))
(LL1 <- logLik(lm.D9))
> -20.08824 (df=3)
Reconstruct from first principles:
n <- nrow(d)
ss0 <- summary(lm.D9)$sigma
ss <- ss0*(n-1)/n
(LL2 <- sum(dnorm(d$weight,fitted(lm.D9),
This is a tiny bit off, haven't found the glitch.
Number of parameters:
npar <- length(coef(lm.D9))+1
(AIC2 <- -2*LL2+2*npar)
Still off by more than numeric fuzz, but only about one part in a million.
Now let's see what
stepAIC is doing:
MASS::stepAIC(lm.D9) ## start: AIC = -12.58
extractAIC(lm.D9) ## same value (see MASS::stepAIC for details)
stats:::extractAIC.lm ## examine the code
RSS1 <- deviance(lm.D9) ## UNSCALED sum of squares
RSS2 <- sum((d$weight-fitted(lm.D9))^2) ## ditto, from first principles
AIC3 <- n*log(RSS1/n)+2*2 ## formula used within extractAIC
You can work out the formula used above from sigma-hat=RSS/n -- or see Venables and Ripley MASS for the derivation.
Add missing terms: uncounted variance parameter, plus normalization constant
(AIC3 + 2 - 2*(-n/2*(log(2*pi)+1)))
This is exactly the same (to 1e-14) as