Chapter 5, Solutions Cornett, Adair, and Nofsinger
CHAPTER 5 – Time Value of Money 2: ANALYZING ANNUITY CASH FLOWS
Questions
LG1 5-1 How can you add a cash flow in year two and a cash flow in year four in year seven?
To add cash flows, they need to be moved to the same time period. The cash flows in years two and four should be moved forward with interest to year seven, then they can be added together.
LG2 5-2 People can become millionaires in their retirement years quite easily if they start saving early in employer 401(k) or 403(b) programs (or even if their employers don’t offer such programs). Demonstrate the growth of a $250 monthly contribution for 40 years earning 9 percent APR.
Using equation 5-2, we have:
LG3 5-3 When you discount multiple cash flows, how does the future period that a cash flow is paid affect its present value and its contribution to the value of all the cash flows?
Discounting reduces a future cash flow to a smaller present value. Cash flows far into the future become very small when discounted to the present. Thus, cash flows in distant future periods have small impacts on present values.
LG4 5-4 How can you use the present value of an annuity concept to determine the price of a house you can afford?
Mortgages are typically for a large enough amount of money that borrowing is required to purchase a home. The amount that one can afford for a home is a function of their current state of wealth. Mortgages allow consumers to spread the expense of a home over a longer period, typically 15 or 30 years. This allows consumers to put a smaller portion of wealth into the home (for example, a 20% down payment) and borrow the balance over the life of the loan. Due to the effect of annuity compounding, the payments for such a long lived debt make the monthly payments of a manageable nature so that they can be paid from current income.
LG5 5-5 Since perpetuity payments continue for ever, how can a present value be computed? Why isn’t the present value infinite?
Equation 5-5 is used to calculate the present value of a perpetuity. It is a limiting version of equation 5-4 in which the period N grows infinitely large. As this occurs the expression following the “1” in equation 5-4 drives to the value 0 and the numerator simply become “1.” The present value is not infinite since the terms following the PMT in equation 5-4 converge to a finite limit of 1/i. This also demonstrates how payments far into the future have infinitesimal value today.
LG6 5-6 Explain why you use the same adjustment factor, (1 + i), when you adjust annuity due payments for both future value and present value.
Adjusting an annuity due calculation involves shifting the entire series of payments forward one period. This is accomplished by multiplying by (1 + i) irrespective of whether it is a future value or present value calculation.
LG7 5-7 Use the idea of compound interest to explain why EAR is larger than APR.
The annual percentage rate does not take into account the frequency of interest compounding. Equation 5-8 illustrates the conversion from APR to EAR. The effective annual rate converts the annual percentage rate to a rate that can be compared to other annual rates.
LG8 5-8 Would you rather pay $10,000 for a five year $2,500 annuity or a ten-year $1,250 annuity? Why?
The effective annual rates for these two payment streams are 7.93% and 4.28% respectively. I would rather pay $10,000 for a five year $2,500 annuity as it earns a higher effective annual rate of interest.
LG9 5-9 The interest on your home mortgage is tax deductible. Why are the early years of the mortgage more helpful in reducing taxes than in the later years?
Mortgage payments at the beginning of the amortization schedule are predominantly interest with little principal. In later years, interest payments decline and principal payments make up an ever increasing part of the payments. Thus, the tax deductible part (the interest payment) is larger in the beginning years.
LG10 5-10 How can you use the concepts illustrated in computing the number of payments in an annuity to figure how to pay off a credit card balance? How does the magnitude of the payment impact the number of months?
Utilizing equation 5-2, you can declare the present balance for the credit card and set that equal to the PVA. The interest can be obtained as an APR and converted to and EAR using equation 5-8. This is the value to put into “i” in equation 5-2. You then decide when you want to have the credit card paid off and convert this to a monthly value of N in equation 5-2. Solving for PMT will yield the amount needed to pay the credit card off in the time frame you desire, assuming that no additional charges are made to the credit card and that the interest rate remains level.
Problems
Basic
Problems 5-1 Future Value Compute the future value in year 8 of a $1,000 deposit in year 1 and
LG1 another $1,500 deposit at the end of year 3 using a 10% interest rate.
Use equation 5-1:
FV = $1,000 × (1 + 0.10)7 + $1,500× (1 + 0.10)5 = $1,948.72 + $2,415.77 = $4,364.48
LG1 5-2 Future Value Compute the future value in year 7 of a $2,000 deposit in year 1 and another $2,500 deposit at the end of year 4 using a 8% interest rate..
Use equation 5-1:
FV = $2,000 × (1 + 0.08)6 + $2,500 × (1 + 0.08)3 = $3,173.75 + $3,149.28 = $6,323.03
LG2 5-3 Future Value of an Annuity What is the future value of a $500 annuity payment over 5 years if interest rates are 9 percent?
Use equation 5-2:
LG2 5-4 Future Value of an Annuity What is the future value of a $700 annuity payment over 4 years if interest rates are 10 percent?
Use equation 5-2:
LG3 5-5 Present Value Compute the present value of a $1,000 deposit in year 1 and another $1,500 deposit at the end of year 3 if interest rates are 10 percent.
Use equation 5-3:
PV = $1,000 ÷ (1 + 0.10)1 + $1,500 ÷ (1 + 0.10)3 = $909.09 + $1,126.97 = $2,036.06
LG3 5-6 Present Value Compute the present value of a $2,000 deposit in year 1 and another $2,500 deposit at the end of year 4 using an 8% interest rate.
Use equation 5-3:
PV = $2,000 ÷ (1 + 0.08)1 + $2,500 ÷ (1 + 0.08)4 = $1,851.85 + $1,837.57 = $3,689.43
LG4 5-7 Present Value of an Annuity What’s the present value of a $500 annuity payment over 5 years if interest rates are 9 percent?
Use equation 5-4:
LG4 5-8 Present Value of an Annuity What’s the present value of a $700 annuity payment over 4 years if interest rates are 10 percent?
Use equation 5-4:
LG5 5-9 Present Value of a Perpetuity What’s the present value, when interest rates are 7.5 percent, of a $50 payment made every year forever?
Use equation 5-5:
LG5 5-10 Present Value of a Perpetuity What’s the present value, when interest rates are 8.5 percent, of a $75 payment made every year forever?
Use equation 5-5:
LG6 5-11 Present Value of an Annuity Due If the present value of an ordinary, 7-year annuity is $6,500 and interest rates are 8.5 percent, what’s the present value of the same annuity due?
Use equation 5-7:
PVA7 due = 6,500 × (1 +0.085) = $7,052.50
LG6 5-12 Present Value of an Annuity Due If the present value of an ordinary, 6-year annuity is $8,500 and interest rates are 9.5 percent, what’s the present value of the same annuity due?
Use equation 5-7:
PVA6 due = 8,500 × (1 +0.095) = $9,307.50
LG6 5-13 Future Value of an Annuity Due If the future value of an ordinary, 7-year annuity is $6,500 and interest rates are 8.5 percent, what is the future value of the same annuity due?
Use equation 5-6:
FVA7 due = 6,500 × (1 + 0.085) = $7,052.50
(Note this is the same answer as problem 5-11, as expected)
LG6 5-14 Future Value of an Annuity Due If the future value of an ordinary, 6-year annuity is $8,500 and interest
rates are 9.5 percent, what’s the future value of the same annuity due?
Use equation 5-6:
FVA6 due = 8,500 × (1 + 0.095) = $9,307.50
(Note this is the same answer as problem 5-12, as expected)
LG7 5-15 Effective Annual Rate A loan is offered with monthly payments and an 11 percent APR. What’s the loan’s effective annual rate (EAR)?
Use equation 5-8:
LG7 5-16 Effective Annual Rate A loan is offered with monthly payments and a 12 percent APR. What’s the loan’s effective annual rate (EAR)?
Use equation 5-8:
Intermediate
Problems 5-17 Future Value Given a 6 percent interest rate, compute the year 6 future value of deposits made in years 1, 2, 3, and 4 of $1,000, $1,200, $1,200, and $1,500.
LG1
Use equation 5-1:
FV = $1,000 × (1 + 0.06)5 + $1,200× (1 + 0.06)4 + $1,200 × (1 + 0.06)3 + $1,500× (1 + 0.06)2
FV = $1,338.23 + $1,514.97 + $1,429.22 + $1,685.40 = $5,967.82
LG1 5-18 Future Value Given a 7 percent interest rate, compute the year 6 future value of deposits made in years 1, 2, 3, and 4 of $1,000, $1,300, $1,300, and $1,400.
Use equation 5-1:
FV = $1,000 × (1 + 0.07)5 + $1,300× (1 + 0.07)4 + $1,300 × (1 + 0.07)3 + $1,400× (1 + 0.07)2
FV = $1,402.55 + $1,704.03 + $1,592.56 + $1,602.86 = $6,302
LG2 5-19 Future Value of Multiple Annuities Assume that you contribute $200 per month to a retirement plan for 20 years. Then you are able to increase the contribution to $400 per month for another 20 years. Given a 7 percent interest rate, what is the value of your retirement plan after the 40 years?
Break the annuity streams into a level stream of payments of $200 for 40 years and another level stream of payments of $200 for the last 20 years. Use equation 5-2 for each payment stream and add the results:
LG2 5-20 Future Value of Multiple Annuities Assume that you contribute $150 per month to a retirement plan for 15 years. Then you are able to increase the contribution to $350 per month for the next 25 years. Given an 8 percent interest rate, what is the value of your retirement plan after the 40 years?
Break the annuity streams into a level stream of payments of $150 for 40 years and another level stream of payments of $200 for the last 25 years. Use equation 5-2 for each payment stream and add the results
LG3 5-21 Present Value Given a 6 percent interest rate, compute the present value of payments made in years 1, 2, 3, and 4 of $1,000, $1,200, $1,200, and $1,500.
Use equation 5-3:
PV = $1,000 ÷ (1 + 0.06)1 + $1,200 ÷ (1 + 0.06)2 + $1,200 ÷ (1 + 0.06)3 + $1,500 ÷ (1 + 0.06)4
PV = $943.40 + $1,068 + $1,007.54 + $1,188.14 = $4,207.08
LG3 5-22 Present Value Given a 7 percent interest rate, compute the present value of payments made in years 1, 2, 3, and 4 of $1,000, $1,300, $1,300, and $1,400.
Use equation 5-3:
PV = $1,000 ÷ (1 + 0.07)1 + $1,300 ÷ (1 + 0.07)2 + $1,300 ÷ (1 + 0.07)3 + $1,400 ÷ (1 + 0.07)4
PV = $934.58 + $1,135.47 + $1,061.19 + $1,068.05 = $4,199.29
LG2 5-23 Present Value of Multiple Annuities A small business owner visits his bank to ask for a loan. The owner states that he can repay a loan at $1,000 per month for the next three years and then $2,000 per month for two years after that. If the bank is charging customers 7.5 percent APR, how much would it be willing to lend the business owner?
Break the annuity streams into a level stream of payments of $2,000 for 5 years and another level stream of payments of $1,000 for the first 3 years. Use equation 5-4 for each payment stream and subtract the results.
LG2 5-24 Present Value of Multiple Annuities A small business owner visits his bank to ask for a loan. The owner states that she can repay a loan at $1,500 per month for the next three years and then $500 per month for two years after that. If the bank is charging customers 8.5 percent APR, how much would it be willing to lend the business owner?
Break the annuity into two streams of payments: $500 monthly for five years and $1,000 for three years. Use equation 5-4 for each annuity and add the results.
LG5 5-25 Present Value of a Perpetuity A perpetuity pays $100 per year and interest rates are 7.5 percent. How much would its value change if interest rates increased to 8.5 percent? Did the value increase or decrease?
Use equation 5-5:
The difference between these perpetuities is $156.86. The value of the perpetuity decreased with an increase in the interest rate.
LG5 5-26 Present Value of a Perpetuity A perpetuity pays $50 per year and interest rates are 9 percent. How much would its value change if interest rates decreased to 8 percent? Did the value increase or decrease?
Use equation 5-5:
The difference between these perpetuities is $69.45. The value of the perpetuity increased with a decrease in the interest rate.
LG6 5-27 Future and Present Value of an Annuity Due If you start making $50 monthly contributions today and continue them for 5 years, what’s their future value if the compounding rate is 10 percent APR? What is the present value of this annuity?
Compute the future value using equation 5-2:
Compute the present value using equation 5-4:
LG6 5-28 Future and Present Value of an Annuity Due If you start making $75 monthly contributions today and continue them for 4 years, what is their future value if the compounding rate is 12 percent APR? What is the present value of this annuity?
First calculate the future values and present values, using equations 5-2 and 5-4, respectively. Using these results, the annuity due values can be computed using equations 5-6 and 5-7, respectively.