Chapter 15

Hi! I have some questions from Chapter 15..

1) in deriving equation 2.3, there are some mathematical workings involving ^ and v. Though the workings make sense, I'm not sure if I'm able to come up with something like this in the exam. So I'm wondering if we're expected to understand/ find out more about the mathematical workings involving ^ and v?

2) Eqn 2.3 makes sense where the layer loss cost = ground up loss * differences in the exposure curve with relativities (L+D)/M and D/M. However, for equation 2.4, I don't understand why you need to devide by [1-G(d/(M+d))]? Is there any intuitive explanation behind eqn 2.4?

3) also in page 20, the notes say 'the presence of original deductibles will increase the reinsurance rates', it means that reinsurance will be more expansive where there's original deductibles? I don't see why is that the case, although the insurer is not liable for the original deductible, so is the reinsurer and why does that make reinsurance more expansive?

4) in page 21 under the heading of Treatment of stacked limits, the notes say 'if the layers are stacked then the underlying contract is essentially 1.4m xs 100k and the reinsurance covers the range [600k, 1.1m]. If they are independent, the reinsurance only affects the 1m xs 500k contract, covering the range [1m,1.5m]'

how is the range [600k,1.1m] obtained? Also when the contracts are independent, shouldn't the reinsurance cover the range [0.5m,1.5m] instead of [1m,1.5m]?

5) under Catastrophe XL rating, what does it mean by 'long return periods' and why does it make curves difficult to estimate?

6) eqn 6.2 says C(delta I) = E(N)E[X^(delta I +D) - X^D]
= E(N)[S(D)delta I]
I don't see how to get the second line?

Thanks in advance!

 

Please can someone go through the steps of deriving equation (2.4)? The specific part I'm having trouble with is following Katherine's definition of conditional probability, my denominator is P(X > d) = S_Y(d/d+M).

But I can't convert the survival probability in terms of the exposure curve function G.

I've tried using the derivative of the LEV is the survivor function and that the integral of the survivor function is the expectation, but not really getting anywhere.

Thanks

 

Hi Katherine,

I have the same question as mario. I cannot see how to use conditional expectation E(X|X>d) = E(X)/P(X>d) to derive (2.4).

Thanks for help!

 

If the exposure curve is based on ground-up data, then a loss has to be greater than (d+M) in order to hit the layer.

So replace all the (M) in equation 2.3 with (d+M).

However, since we're trying to find a conditional expectation (as Katherine says, "we need claims to first exceed the deductible, before we think about the loss to the insurer"), we need to divide by P(X>d). Well, the analogous denominator for loss curves is (1-G(d/(d+M)).

 

Thank you for your explanation... I understand the logic behind the calculation, but still can't actually manipulate P(X>d) to actually get to the required answer in terms of G.

That is, when I try to convert P(X>d) in terms of the survivor function, and then in terms of the exposure curve function G, I can't get to the right answer.

Please can someone post the derivation of P(X>d) = (1-G(d/(d+M)) step by step? Thanks

 

Can someone please help? How did we derive the denominator for (2.4)? Is it required to know the step by step?

 

Hi,

Would you mind re-uploading the file as it doesn't seem to work?

Many thanks,