Why does glm.nb throw a "missing value" error only on very specific inputs

glm.nb throws an unusual error on certain inputs. While there are a variety of values that cause this error, changing the input even very slightly can prevent the error.

A reproducible example:

``````set.seed(11)
pop <- rnbinom(n=1000,size=1,mu=0.05)
glm.nb(pop~1,maxit=1000)
``````

Running this code throws the error:

``````Error in while ((it <- it + 1) < limit && abs(del) > eps) { :
missing value where TRUE/FALSE needed
``````

At first I assumed that this had something to do with the algorithm not converging. However, I was surprised to find that changing the input even very slightly can prevent the error. For example:

``````pop[1000] <- pop[1000] + 1
glm.nb(pop~1,maxit=1000)
``````

I've found that it throws this error on 19.4% of the seeds between 1 and 500:

``````fit.with.seed = function(s) {
set.seed(s)
pop <- rnbinom(n=1000, size=1, mu=0.05)
m = glm.nb(pop~1, maxit=1000)
}

errors = sapply(1:500, function(s) {
is.null(tryCatch(fit.with.seed(s), error=function(e) NULL))
})

mean(errors)
``````

I've found only one mention of this error anywhere, on a thread with no responses.

What could be causing this error, and how can it be fixed (other than randomly permuting the inputs every time `glm.nb` throws an error?)

ETA: Setting `control=glm.control(maxit=200,trace = 3)` finds that the `theta.ml` algorithm breaks by getting very large, then becoming `-Inf`, then becoming `NaN`:

``````theta.ml: iter67 theta =5.77203e+15
theta.ml: iter68 theta =5.28327e+15
theta.ml: iter69 theta =1.41103e+16
theta.ml: iter70 theta =-Inf
theta.ml: iter71 theta =NaN
``````
• This won't solve your problem, but it may speed up the search for someone more knowledgeable: setting `control=glm.control(maxit=200,trace = 3)` sheds some important light on exactly what's going wrong in `theta.ml`. Commented Jul 31, 2012 at 22:56
• Can you post your `sessionInfo()`? I can't replicate the error on 2.15.1 on Windows in either 32 or 64-bit. Commented Jul 31, 2012 at 23:10
• I'm also using 2.15.1, but on a Mac. See above Commented Jul 31, 2012 at 23:13
• FWIW I also get the error and am also in 2.15.1 on a Mac. Commented Jul 31, 2012 at 23:15
• for what it's worth you may be able to get this to work with `bbmle::mle2(Y~dnbinom(mu=exp(logmu),size=exp(logk),parameters(logmu=~ X1 + X2 + offset(X3)), start=..., ...)` Commented Jul 31, 2012 at 23:35

It's a bit crude, but in the past I have been able to work around problems with `glm.nb` by resorting to straight maximum likelihood estimation (i.e. no clever iterative estimation algorithms as used in `glm.nb`)

Some poking around/profiling indicates that the MLE for the theta parameter is effectively infinite. I decided to fit it on the inverse scale, so that I could put a boundary at 0 (a fancier version would set up a log-likelihood function that would revert to Poisson at theta=zero, but that would undo the point of trying to come up with a quick, canned solution).

With two of the bad examples given above, this works reasonably well, although it does warn that the parameter fit is on the boundary ...

``````library(bbmle)
m1 <- mle2(Y~dnbinom(mu=exp(logmu),size=1/invk),
data=d1,
parameters=list(logmu~X1+X2+offset(X3)),
start=list(logmu=0,invk=1),
method="L-BFGS-B",
lower=c(rep(-Inf,12),1e-8))
``````

The second example is actually more interesting because it demonstrates numerically that the MLE for theta is essentially infinite even though we have a good-sized data set that is exactly generated from negative binomial deviates (or else I'm confused about something ...)

``````set.seed(11);pop <- rnbinom(n=1000,size=1,mu=0.05);glm.nb(pop~1,maxit=1000)
m2 <- mle2(pop~dnbinom(mu=exp(logmu),size=1/invk),
data=data.frame(pop),
start=list(logmu=0,invk=1),
method="L-BFGS-B",
lower=c(-Inf,1e-8))
``````
• +1. One thing that worries me is that it gives an `ABNORMAL_TERMINATION_IN_LNSRCH` message). I'm currently investigating how this method compares to `glm.nb` in the cases where `glm.nb` does work. I've also had a surprising amount of success by very slightly altering the inputs in the cases where `glm.nb` breaks (though it disturbs me that I don't know why that works). Commented Aug 1, 2012 at 2:35
• you could also try this with other bounded optimizers, e.g. `library(optimx); ... ; mle2(...,optimizer="optimx",method="bobyqa")` Commented Dec 27, 2012 at 16:45

Edit: The code and answer has been simplified to one sample, like in the question.

Yes, theta can approach Inf in small samples and sparse data (many zeroes, small mean and large skew). I have found that fitting glm.nb fails when the data are all zeroes and returns:

Error in while ((it <- it + 1) < limit && abs(del) > eps) { : missing value where TRUE/FALSE needed

The following code simulates small samples with a small mean and theta. To prevent the loop from crashing, glm.nb is not fitted when the data are all zeroes.

``````en1 <- 10
mu1 <- 0.5
size1 <- 0.5
temp <- matrix(nrow=10000, ncol=2)
# theta == Inf is rare so use a large number of reps
for (r in 1:10000){
dat1 <- rnbinom(n=en1, size=size1, mu=mu1)
temp[r, 1:2] <- c(mean(dat1), ifelse(max(dat1)!=0, glm.nb(dat1~1)\$theta, NA))
}
temp <- as.data.frame(temp)
names(temp) <- c("mean1","theta1")
temp[which(is.na(temp\$theta1)),]
# note that it's rare to get all zeroes in the sample
sum(is.na(temp\$theta1))/dim(temp)[1]
# a log scale helps see what's happening
with(temp, plot(mean1, log10(theta1)))
# estimated thetas should equal size1 = 0.5
abline(h=log10(0.5), col="red")
text(2.5, 5, "n1 = n2 = 10", col="red", cex=2, adj=1)
text(1, 4, "extreme thetas", col="red", cex=2)
``````

See that estimated thetas can be extremely large when the sample size is small (in the first plot below): Lesson learnt: don't expect high quality results from glm.nb for small samples and sparse data; get larger samples (e.g. in the second plot below).

• this is nice. Maybe change the labels on your graph so they read `n = 10`, `n = 100` rather than `n1 = n2 = 10` etc. ? Commented Jul 17, 2022 at 23:06
• Done. Also note that n = 100 is still not perfect. I would be cautious about choosing between glm.nb and glm(family=poisson) based only on the estimated theta. There are better methods for estimating theta. Commented Jul 19, 2022 at 2:49