14.6 Effect of exposure on maximum likelihood estimation
In Section 7.4, the effect of exposure on discrete distributions is discussed. When aggregate data from a large group of insureds is obtained, maximum likelihood estimation is still possible. The following example illustrates this fact for the Poisson distribution.
EXAMPLE 14.9
Determine the maximum likelihood estimate of the Poisson parameter for the data in Table 14.8.
Table 14.8 Automobile claims by year.
| Year | Exposure | Claims |
| 1986 | 2,145 | 207 |
| 1987 | 2,452 | 227 |
| 1988 | 3,112 | 341 |
| 1989 | 3,458 | 335 |
| 1990 | 3,698 | 362 |
| 1991 | 3,872 | 359 |
Let Let λ be the Poisson parameter for a single exposure. If year κ has ek exposures, then the number of claims has a Poisson distribution with parameter λek. If nk is the number of claims in year κ, the likelihood function is
The maximum likelihood estimate is found by
In this example the answer is what we expected it to be: the average number of claims per exposure. This technique will work for any distribution in the (a, b, 0)5 and compound classes. But care must be taken in the interpretation of the model. For example, if we use a negative binomial distribution, we are assuming that each exposure ...
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