Regenerate your example:

```
clotting <- data.frame(
u = c(5,10,15,20,30,40,60,80,100),
lot1 = c(118,58,42,35,27,25,21,19,18),
lot2 = c(69,35,26,21,18,16,13,12,12))
glm2 <- glm(lot2 ~ log(u), data=clotting, family=Gamma)
```

The `profile.glm`

function actually lives in the `MASS`

package:

```
library(MASS)
prof<-profile(glm2)
```

In order to figure out what `profile.glm`

and `plot.profile`

are doing, see `?profile.glm`

and `?plot.profile`

. However, in order to dig into the `profile`

object it may also be useful to examine the code of `MASS:::profile.glm`

and `MASS:::plot.profile`

... basically, what these tell you is that `profile`

is returning the *signed square root* of the difference between the deviance and the minimum deviance, scaled by the dispersion parameter. The reason that this is done is so that the profile for a perfectly quadratic profile will appear as a straight line (it's much easier to detect deviations from a straight line than from a parabola by eye).

The other thing that may be useful to know is how the profile is stored. Basically, it's a list of data frames (one for each parameter profiled), except that the individual data frames are a little bit weird (containing one vector component and one matrix component).

```
> str(prof)
List of 2
$ (Intercept):'data.frame': 12 obs. of 3 variables:
..$ tau : num [1:12] -3.557 -2.836 -2.12 -1.409 -0.702 ...
..$ par.vals: num [1:12, 1:2] -0.0286 -0.0276 -0.0267 -0.0258 -0.0248 ...
.. ..- attr(*, "dimnames")=List of 2
.. .. ..$ : NULL
.. .. ..$ : chr [1:2] "(Intercept)" "log(u)"
..$ dev : num [1:12] 0.00622 0.00753 0.00883 0.01012 0.0114 ...
$ log(u) :'data.frame': 12 obs. of 2 variables:
..$ tau : num [1:12] -3.516 -2.811 -2.106 -1.403 -0.701 ...
..$ par.vals: num [1:12, 1:2] -0.0195 -0.0204 -0.0213 -0.0222 -0.023 ...
.. ..- attr(*, "dimnames")=List of 2
```

It also contains attributes `summary`

and `original.fit`

that you can use to recover the dispersion and minimum deviance:

```
disp <- attr(prof,"summary")$dispersion
mindev <- attr(prof,"original.fit")$deviance
```

Now reverse the transformation for parameter 1:

```
dev1 <- prof[[1]]$tau^2
dev2 <- dev1*disp+mindev
```

Plot:

```
plot(prof[[1]][,1],dev2,type="b")
```

(This is the plot of the deviance. You can multiply by 0.5 to get the negative log-likelihood, or -0.5 to get the log-likelihood ...)

**edit**: some more general functions to transform the profile into a useful format for `lattice`

/`ggplot`

plotting ...

```
tmpf <- function(x,n) {
data.frame(par=n,tau=x$tau,
deviance=x$tau^2*disp+mindev,
x$par.vals,check.names=FALSE)
}
pp <- do.call(rbind,mapply(tmpf,prof,names(prof),SIMPLIFY=FALSE))
library(reshape2)
pp2 <- melt(pp,id.var=1:3)
pp3 <- subset(pp2,par==variable,select=-variable)
```

Now plot it with lattice:

```
library(lattice)
xyplot(deviance~value|par,type="b",data=pp3,
scales=list(x=list(relation="free")))
```

Or with ggplot2:

```
library(ggplot2)
ggplot(pp3,aes(value,deviance))+geom_line()+geom_point()+
facet_wrap(~par,scale="free_x")
```