Revision as of 18:58, 25 July 2024 by Admin (Created page with "According to the loss ratio method, the indicated differential change factor for region <math>i</math> equals the projected loss ratio for region <math>i</math> divided by the projected loss ratio for the base level: {| class="table table-bordered" |- ! Region <math>i</math> !! <math>R_{i,I}/R_{i,C}</math> !!<math>R_{i,I} </math> |- | A || 1 || 1 |- | B|| 1.098 || 1.3176 |- | C || 0.8366 || 0.9412 |} Given a targeted overall change factor of 1.12, the indicated chan...")
Exercise
ABy Admin
Jul 25'24
Answer
According to the loss ratio method, the indicated differential change factor for region [math]i[/math] equals the projected loss ratio for region [math]i[/math] divided by the projected loss ratio for the base level:
| Region [math]i[/math] | [math]R_{i,I}/R_{i,C}[/math] | [math]R_{i,I} [/math] |
|---|---|---|
| A | 1 | 1 |
| B | 1.098 | 1.3176 |
| C | 0.8366 | 0.9412 |
Given a targeted overall change factor of 1.12, the indicated change factor for the base rate equals
[[math]]
1.12 \cdot \frac{\sum_{i} w_i R_{C,i}}{\sum_{i} w_i R_{I,i}} = 1.105.
[[/math]]
Hence the base rate should be increased by 10.5%. The earned premium at current rates for region A's accident year 1 equals $500,000 with an exposure of 4,000; therefore, the current base rate is $125 per exposure unit. Since we have the current base rate, we can derive the rates for each region using the indicated rate differentials derived above:
| Region | New Rate per Exposure Unit |
|---|---|
| A | $138.13 |
| B | $182 |
| C | $130 |