Finding suitable starting values can be difficult for sufficiently complex problems. However for setting the starting values (the documentation of which is not great, but exists) you should learn to read the error messages. Here is a replicate of your unsuccessful attempt using
start=1 with a built-in data set:
>quine.nb1 <- glm.nb(Days ~ Sex + Age + Eth + Lrn, data = quine,
Error in glm.fitter(x = X, y = Y, w = w, start = start, etastart = etastart, :
length of 'start' should equal 7 and correspond to initial coefs for
c("(Intercept)", "SexM", "AgeF1", "AgeF2", "AgeF3", "EthN", "LrnSL", )
It tells you exactly what it is expecting: a vector of values for each coefficient to be estimated.
quine.nb1 <- glm.nb(Days ~ Sex + Age + Eth + Lrn, data = quine,
works, because I gave a vector of length 7. You might have to play around with the actual values in it to get a model that always predicts positive values. It is likely that the default algorithm of generating starting values in
glm.nb gives negative prediction somewhere, and the
sqrt link cannot tolerate that (unlike the
log). If you are having trouble finding valid starting values by hand, you can try running a simpler model, and expand estimates from it by 0's for the other parameters to get a good starting location.
EDIT: building up a model
Suppose you can't find valid starting values for your complicated model. Then start with a simple one, for example
> nb0 <- glm.nb(Days ~ Sex, data=quine, link=sqrt)
Now let's add the next variable using the previous starting values by adding 0 estimates for the effect of the new variable (in this case
Age has four levels, so needs 3 coefficients):
> nb1 <- glm.nb(Days ~ Sex+Age, data=quine, link=sqrt, start=c(coef(nb0), 0,0,0))
(Intercept) SexM AgeF1 AgeF2 AgeF3
3.9127405 -0.1155013 -0.5551010 0.7475166 0.5933048
You usually want to keep adding 0's and not, say, 100's, because a coefficient of 0 means that the new variable has no effect - which is exactly what the simpler model that you just fitted assumes.