Revision as of 01:49, 20 January 2024 by Admin (Created page with "Ten years ago <math>\mathrm{J}</math>, then age 25 , purchased a fully discrete 10 -payment whole life policy of 10,000 . All actuarial calculations for this policy were based on the following: (i) Mortality follows the Standard Ultimate Life Table (ii) <math>\quad i=0.05</math> (iii) The equivalence principle In addition: (i) <math>\quad L_{10}</math> is the present value of future losses random variable at time 10. (ii) At the end of policy year 10 , the interes...")
(diff) ← Older revision | Latest revision (diff) | Newer revision → (diff)
ABy Admin
Jan 20'24

Exercise

Ten years ago [math]\mathrm{J}[/math], then age 25 , purchased a fully discrete 10 -payment whole life policy of 10,000 .

All actuarial calculations for this policy were based on the following:

(i) Mortality follows the Standard Ultimate Life Table

(ii) [math]\quad i=0.05[/math]

(iii) The equivalence principle

In addition:

(i) [math]\quad L_{10}[/math] is the present value of future losses random variable at time 10.

(ii) At the end of policy year 10 , the interest rate used to calculate [math]L_{10}[/math] is changed to [math]0 \%[/math].

Calculate the increase in [math]E\left[L_{10}\right][/math] that results from this change.

  • 5035
  • 6035
  • 7035
  • 8035
  • 9035

Copyright 2024. The Society of Actuaries, Schaumburg, Illinois. Reproduced with permission.

ABy Admin
Jan 20'24

Answer: E

[math]L_{10}=10,000 A_{35}=965.30[/math]

[math]L_{10}^{*}=10,000[/math]

[math]L_{10}^{*}-L_{10}=10,000-965.30=9034.70[/math]

Copyright 2024. The Society of Actuaries, Schaumburg, Illinois. Reproduced with permission.

00