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I found the following R codes to fit a Tweedie Compound Poisson Gamma distribution. I have to fit it to my 399 claim amounts. I have seen the following R codes ptweedie.series(q, power, mu, phi) and dtweedie.series(y, power, mu, phi). However I fail to understand the codes fully and after importing my data into R, how to proceed? Thanks in advance.

  • To fit a glm using a tweedie distribution, see the examples at the end of this reference. For a discussion of the underlying theory, see this paper. If that is not enough, you are more likely to get a full answer if you provide your data (upload to, e.g. Dropbox and provide a link). – jlhoward Feb 16 '14 at 6:14
  • here are my 399 individual total claim amounts (6500,16600,14500,27800,9900,6000,27400,20600,3500,1150,10280,12150,1563162,3500,5500,6000,16150,4500,20000,51540,12500,141811,784760,43000,15600,26840,3000,115100,15500,12700,49200,6300,37500,4000,4600,8500,3000,7700,14600,78400,59700,20600,5000,3500,50900,32000,28850,8000,7400,59750,75900,3000,66900,104500,50300,38750,17500,66400,17670,3949,11150,9653,5000,3000,3000,14050,3000,25000,4000,4500,4750,55000,2000,5500,4750,5000,4500,3000,5000,280000,9500,4500,4500,30000,1500,8000,4500,4800,3000,8000,2500,30000,12000,3500,9600,16000,4000,5500,4000) – user3309969 Feb 16 '14 at 10:51
  • (5000,6000,1200,1000,6200,6300,5500,5000,3500,3500,1250,1300,4600,4000,3600,5000,17300,6000,8000,6000,5500,13500,2500,5500,4500,5900,7000,13000,6700,6800,5000,6200,6300,6100,3600,3300,3500,2900,3000,3150,3250,9900,8700,7300,9600,4000,4500,4100,3350,3950,4250,3850,3950,3500,4000,4550,3000,13300,13900,3000,4550,14650,14400,3500,13550 13900,3900,11000,12000,28000,9000,22000,29000,5500,3000,2500,208009850,18000,27500,20000,28000,22500,20500,27600,28500,18000,18500,18900,11700,3500,3900,20800,21000,5000,8600,10500,10600,9000,9500,12000,12500,11800,7500,9750,9000,8000,9800,5600,9700,7550,3500,6000) – user3309969 Feb 16 '14 at 10:53
  • (11550,10500,5000,12100,7000,7000,8000,8500,9500,5000,4600,4550,3700,2500,2900,5500,5850,3550,2650,4550,6500,7500,6850,8000,10250,6000,7750,6950,6900,7800,7250,25000,28000,19150,32000,28000,27000,19000,19550,16350,20150,20800,12000,25500,26800,29550,24350,13000,25000,49500,44000,27000,25800,9000,10000,8550,8000,9500,8100,11000,11000,7350,7550,4050,14000,14500,13000,15000,19500,20000,25000,30000,21000,39500,43500,21500,8900,18500,18000,19500,8700,19500,6300,12000,15000,18000,40000,36000,25000,39000,37000,30000,33000,37000,25000,18000,20000,21000,19800,35700,60000,19850,25890,52000,15000) – user3309969 Feb 16 '14 at 10:54
  • (17000,19850,8000,16500,8500,11000,10000,12000,13500,18000,6500,6850,25000,22000,32550,19000,11000,23000,21550,22000,23550,30550 35000,9800,23000,26800,23550,23850,15000,26700,26850,32000,70000,73000,71000,29000,35500,76550,78000,50000,46000,47500,57500,35000,36000,58500,57000,50100,39000,60550,48100,56550,3000,4200,3500,2700,11000,12500,12000,8790,14600,6700,10000,19300,12000,12500,20000,25990,27340,20000,15000,64000,25000,29870,32340,39000,32000,19000,15600,14000,28500,34000) @ jlhoward – user3309969 Feb 16 '14 at 10:56
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First a note: importing your dataset from the comments above yielded 398 claims, not 399. One of these was 4 orders of magnitude larger than the median claim. So I suspect a typo. In the analysis that follows I excluded that sample, leaving 397.

A quick look at the Wikipedia entry for Tweedie Distributions reveals that this is actually a family of exponential distributions distinguished by the power parameter (xi in the R documentation). Power=1 yields the Poisson distribution, power=2 yields the Gamma distribution, power=3 yields the inverse Gaussian distribution, and so on. The Tweedie distributions are also defined for non-integer power. The parameter mu is the mean, and phi is a dispersion parameter, related to variance.

So the basic question, as I understand it, is which combination of power, mu, and phi yield a distribution which best fits your claims data?

One way to assess whether a distribution fits a sample is the Q-Q plot. This plots quantiles of your sample vs. quantiles of the test distribution. If the sample is distributed as the test distribution, the Q-Q plot should be a straight line. In R code (and with X as your vector of samples):

summary(X)        # NOTE: max/median > 1e4 !!!
#     Min.  1st Qu.   Median     Mean  3rd Qu.     Max. 
# 1.00e+03 5.50e+03 1.20e+04 5.47e+05 2.50e+04 2.08e+08 
X <- X[X<max(X)]   # remove largest value (erroneous??)
hist(X,breaks=c(seq(1,1e5,1000),Inf),xlim=c(0,100000))

library(tweedie)
qqTweedie <- function(xi,p,mu,phi) {
  names <- c("Poisson","Gamma","Inverse Gaussian","Positive Stable")
  plot(qtweedie(p,xi,mu,phi),quantile(X,probs=p),
       main=paste0("Power = ",xi," (",names[xi],")"))
  qqline(X,prob=c(0.25,0.75), col="blue", lty=2,
         distribution=function(p) qtweedie(p,xi,mu,phi))
}
p <- seq(0.02,0.98,length=100)
par(mfrow=c(2,2))
lapply(c(1:4),qqTweedie,p=p,mu=1,phi=1)

Both the Gamma and the Inverse Gaussian distributions explain your data up to claims of ~40,000. The Gamma distribution underestimates the frequency of larger claims, while the Inverse Gaussian distribution overestimates their frequency. So let's try power=2.5.

par(mfrow=c(1,1))
xi <- 2.5
plot(qtweedie(p,xi,1,1),quantile(X,probs=p),main=paste0("Power = ",xi))
qqline(X,prob=c(0.25,0.75), col="blue", lty=2,
       distribution=function(p) qtweedie(p,xi,1,1))

So your claims data seems to follow a tweedie distribution with power=2.5. The next step is to estimate mu and phi, given power=2.5. This is a non-linear optimization problem in 2 dimensions, so we use package nloptr. It turns out that convergence depends on having starting parameters relatively close the the optimal values, so there is a fair amount of trial and error to get nlopt(...) to converge.

library(nloptr)
F <- function(params){ # Note: xi, Q, and p are defined external to F
  mu  <- params[1]
  phi <- params[2]
  return(sum(Q - qtweedie(p,xi,mu,phi))^2)
}
xi <- 2.5
Q <- quantile(X,p) 
opt <- nloptr(x0=c(mu=1e4,phi=.01), eval_f=F, ub=c(5e4,.1), lb = c(1,0), 
              opts = list(algorithm="NLOPT_LN_COBYLA",maxeval=1e3,print_level=1))
opt$solution
# [1] 1.884839e+04 9.735325e-03

Finally, we confirm that the solution does indeed fit the data well.

mu  <- opt$solution[1]
phi <- opt$solution[2]
par(mfrow=c(1,1))
hist(X,breaks=c(seq(1,1e5,1000),Inf),xlim=c(0,1e5))
x <- seq(1,1e5,1e3)
lines(x,dtweedie(x,xi,mu,phi),col="red")

  • First of all i thank you for your kind consideration. But actually i have data on automobile claim frequency, the Poisson model fits my data well and for my claim amount the Gamma seems ok..Now i wanted to fit both claim amount and frequency (together) using Tweedie Compound Poisson Gamma distribution. Is it tractable and how to proceed with that? @jlhoward – user3309969 Feb 17 '14 at 12:55
  • So this is back to my original comment. You want a glm using the Tweedie distribution. See also this reference. The data you provided has no predictor variables. – jlhoward Feb 17 '14 at 17:26
  • Yes..My full data set is saved in MS Excel. How can i attach it here?@ jlhoward – user3309969 Feb 17 '14 at 18:25
  • 1
    You have a reference that shows how to do exactly what you are asking, in SAS. You have links to documentation for the R functions that map to the SAS solution. You need to at least make an effort to model this yourself. If that fails, upload your full dataset somewhere, (e.g. Dropbox), and post a new question, with a link to your data, with your code, and with a precise statement of your problem. Once you've done that, perhaps someone else will try to help you. You might also consider posting on stats.stackexchange.com. – jlhoward Feb 18 '14 at 7:27
  • Okay thank you @ jlhoward – user3309969 Feb 18 '14 at 14:05

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