Revision as of 12:15, 18 November 2023 by Admin (Created page with "'''Solution: D''' Let t represent the number of years since the beginning of year 1. Since the annual effective interest rate is 3% in each of years 1 through 10, and 2% each year thereafter, the present value of an amount is calculated by multiplying it by a discounting factor of <math display = "block">\frac{1}{1.03^t}\,\,\mathrm{if} \, 0 < t \leq 10\,</math> and <math display = "block">\frac{1}{(1.03)^{10}(1.02)^{t-10}}\,\,\mathrm{if} \, t >10\,</math> The balance...")
(diff) ← Older revision | Latest revision (diff) | Newer revision → (diff)

Exercise

ABy Admin
Nov 18'23

Answer

Solution: D

Let t represent the number of years since the beginning of year 1. Since the annual effective interest rate is 3% in each of years 1 through 10, and 2% each year thereafter, the present value of an amount is calculated by multiplying it by a discounting factor of

[[math]]\frac{1}{1.03^t}\,\,\mathrm{if} \, 0 \lt t \leq 10\,[[/math]]

and

[[math]]\frac{1}{(1.03)^{10}(1.02)^{t-10}}\,\,\mathrm{if} \, t \gt10\,[[/math]]

The balance is initially 0 (the account is new before the first deposit). Deposits of X are made at times t = 0, 1, 2, 3,..., 25, or equivalently at time t= k-1 for each whole number k from 1 to 26 inclusive.

For the final balance to become 0, a withdrawal of 100,000 at time t = 25 would be needed. Since the net present value of the cash flows (withdrawals minus deposits) must be zero, in a time period from a zero balance to another zero balance, we have

[[math]] \begin{aligned} {\frac{100,000}{\left(1.03\right)^{10}\left(1.02\right)^{25-10}}}-X\sum_{k=12}^{12}{\frac{1}{\left(1.03\right)^{k-1}}}-X\sum_{k=12}^{26}\frac{1}{\left(1.03\right)^{10}\left(1.02\right)^{k-1-10}}=0 \\ {\frac{100,000}{(1.03)^{10}(1.02)^{15}}}=X\sum_{k=1}^{11}{\frac{1}{(1.03)^{k-1}}}+X\sum_{k=1}^{26}{\frac{1}{(1.03)^{10}(1.02)^{k-11}}} \end{aligned} [[/math]]

Copyright 2023 . The Society of Actuaries, Schaumburg, Illinois. Reproduced with permission.

00