Jerry invested $2500 into an account with a 1.5% annual interest rate. Assuming that Jerry did not make any deposits or withdrawals, find the following:

Answers:

a)

I) Amount in Jerry's account if interest is compounded each second:
Number of times interest is compounded in a year (n) = 365 x 24 x 60 x 60 = 31,536,000
Annual interest rate (r) = 1.5%
Time in years (t) = 18 years
Amount in account (A) = P(1 + r/n)^(nt) = 2500(1 + 0.015/31,536,000)^(31,536,000 x 18)
A = $3026.22

II) Amount in Jerry's account if interest is compounded each minute:
Number of times interest is compounded in a year (n) = 365 x 24 x 60 = 525,600
Annual interest rate (r) = 1.5%
Time in years (t) = 18 years
Amount in account (A) = P(1 + r/n)^(nt) = 2500(1 + 0.015/525,600)^(525,600 x 18)
A = $3054.24

III) Amount in Jerry's account if interest is compounded hourly:
Number of times interest is compounded in a year (n) = 365 x 24 = 8,760
Annual interest rate (r) = 1.5%
Time in years (t) = 18 years
Amount in account (A) = P(1 + r/n)^(nt) = 2500(1 + 0.015/8,760)^(8,760 x 18)
A = $3061.80

IV) Amount in Jerry's account if interest is compounded daily:
Number of times interest is compounded in a year (n) = 365
Annual interest rate (r) = 1.5%
Time in years (t) = 18 years
Amount in account (A) = P(1 + r/n)^(nt) = 2500(1 + 0.015/365)^(365 x 18)
A = $3071.26

V) Amount in Jerry's account if interest is compounded weekly:
Number of times interest is compounded in a year (n) = 52
Annual interest rate (r) = 1.5%
Time in years (t) = 18 years
Amount in account (A) = P(1 + r/n)^(nt) = 2500(1 + 0.015/52)^(52 x 18)
A = $3081.10

VI) Amount in Jerry's account if interest is compounded monthly:
Number of times interest is compounded in a year (n) = 12
Annual interest rate (r) = 1.5%
Time in years (t) = 18 years
Amount in account (A) = P(1 + r/n)^(nt) = 2500(1 + 0.015/12)^(12 x 18)
A = $3096.99

VII) Amount in Jerry's account if interest is compounded quarterly:
Number of times interest is compounded in a year (n) = 4
Annual interest rate (r) = 1.5%
Time in years (t) = 18 years
Amount in account (A) = P(1 + r/n)^(nt) = 2500(1 + 0.015/4)^(4 x 18)
A = $3120.48

VIII) Amount in Jerry's account if interest is compounded semi-annually:
Number of times interest is compounded in a year (n) = 2
Annual interest rate (r) = 1.5%
Time in years (t) = 18 years
Amount in account (A) = P(1 + r/n)^(nt) = 2500(1 + 0.015/2)^(2 x 18)
A = $3146.43

IX) Amount in Jerry's account if interest is compounded yearly:
Number of times interest is compounded in a year (n) = 1
Annual interest rate (r) = 1.5%
Time in years (t) = 18 years
Amount in account (A) = P(1 + r/n)^(nt) = 2500(1 + 0.015/1)^(1 x 18)
A = $3221.29

X) Amount in Jerry's account if interest is compounded continuously:
Number of times interest is compounded in a year (n) = infinity
Annual interest rate (r) = 1.5%
Time in years (t) = 18 years
Amount in account (A) = Pe^(rt) = 2500e^(0.015 x 18)
A = $3239.33

b)

I) Number of years of investment in Jerry wanted to have $5000 in his account and chose interest to be compounded quarterly:

Let A be the amount that Jerry wants to have in his account, P be the initial amount invested, r be the annual interest rate, and n be the number of times interest is compounded in a year. Then, we can use the formula:

A = P(1 + r/n)^(nt)

Substituting the given values, we get:

5000 = 2500(1 + 0.015/4)^(4t)

Solving for t, we get:

t = (ln(2) / (4 ln(1 + 0.015/4)))
t = 28.75 years

Therefore, Jerry needs to invest his money for about 29 years to have $5000 in his account if he chooses quarterly compounding.

II) Number of years of investment in Jerry wanted to have $10,000 in his account and chose interest to be compounded continuously:

Using the formula for continuous compounding:

A = Pe^(rt)

Substituting the given values, we get:

10000 = 2500e^(0.015t)

Solving for t, we get:

t = (ln(4) / 0.015)
t = 184.07 years

Therefore, Jerry needs to invest his money for about 184 years to have $10,000 in his account if he chooses continuous compounding.