Chapter 5, Solutions Cornett, Adair, and Nofsinger
26
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: 07 . 330 , 170 , 1 $ 0.09/12 1 12 / 09 . 0 1 250 FVA 480 40 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? 5-1
Chapter 5, Solutions Cornett, Adair, and Nofsinger
CHAPTER 5 – ANALYSIS OF ANNUITY CASH FLOWSChapter 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 $250 monthly contribution
for 40 years earning 9 percent APR.
Using equation 5-2, we have:
07.330,170,1$
0.09/12
480
40
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?
5-1
Chapter 5, Solutions Cornett, Adair, and Nofsinger
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-
5-2
Chapter 5, Solutions Cornett, Adair, and Nofsinger
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:
5
5
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:
4
4
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.
5-3
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 $50 payment made every
year forever?
Use equation 5-5:
50$ perpetuity a of PV
LG5 5-10 Present Value of a Perpetuity What’s the present value,
when interest rates are 8.5 percent, of a $75 payment made every
year forever?
Use equation 5-5:
75$ perpetuity a of PV
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:
EAR
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:
EAR
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
5-5
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:
01.148,629$9267.520200$2415.796,2200$
0.07/12
240480
2040
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
45.856,713$0264.951200$0078.491,3150$
0.08/12
300480
2540
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:
Chapter 5, Solutions Cornett, Adair, and Nofsinger
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.
70.662,67$92.147,32$62.810,99$
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.
70.048,56$11.678,31$59.370,24$
LG5 5-25 Present Value of a Perpetuity A perpetuity pays $100 per
year and interest rates are 7.5 percent. How much would its value
change if interest rates increased to 8.5 percent? Did the value
increase or decrease?
Use equation 5-5:
47.176,1$ 085.0
100$ perpetuity a of PV
The difference between these perpetuities is $156.86. The value of
the perpetuity decreased with an increase in the interest
rate.
5-7
Chapter 5, Solutions Cornett, Adair, and Nofsinger
LG5 5-26 Present Value of a Perpetuity A perpetuity pays $50 per
year and interest rates are 9 percent. How much would its value
change if interest rates decreased to 8 percent? Did the value
increase or decrease?
Use equation 5-5:
00.625$ 08.0
50$ perpetuity a of PV
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:
98.903,3$00833.14343706824.7750$12/10.01 0.10/12
112/10.01 0$5FVA
88.372,2$00833.106536757.4750$00833.1
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.
70.591,4$2226.6175$
0.12/12
5-8
05.848,2$97395951.3775$
PVA48 due = $2,848.05 × (1 +0.12/12) = $2,876.53
LG7 5-29 Compound Frequency Payday loans are very short-term loans
that charge very high interest rates. You can borrow $250 today and
repay $300 in two weeks. What is the compounded annual rate implied
by this 20 percent rate charged for only two weeks?
20% for two weeks needs to be compounded 26 times to form a
year.
(1 + i)26 – 1 = (1 + 0.20)26 – 1 = 113.475 = 11,347.5%
LG7 5-30 Compound Frequency Payday loans are very short-term loans
that charge very high interest rates. You can borrow $500 today and
repay $575 in two weeks. What is the compounded annual rate implied
by this 15 percent rate charged for only two weeks?
15% for two weeks needs to be compounded 26 times to form a
year.
(1 + i)26 – 1 = (1 + 0.15)26 – 1 = 36.857 = 3,685.7%
LG8 5-31 Annuity Interest Rate What’s the interest rate of a
5-year, annual $5,000 annuity with present value of $20,000?
Use equation 5-2 and solve for i:
%93.7
i
i i
or TVM calculator: N=5, PV=-20,000, PMT=5,000, FV=0, CPT I =
7.93%
LG8 5-32 Annuity Interest Rate What’s the interest rate of a
7-year, annual $4,000 annuity with present value of $20,000?
Use equation 5-2 and solve for i:
%20.9
i
i i
or TVM calculator: N=7, PV=-20,000, PMT=4,000, FV=0, CPT I =
9.20%
LG8 5-33 Annuity Interest Rate What annual interest rate would you
need to earn if you wanted a $1,000 per month contribution to grow
to $75,000 in 5 years?
5-9
%732.
i/12
i i
Now convert the monthly interest rate to an annual rate by
multiplying by 12 which yields 8.78%.
or TVM calculator: N=60, PV=0, PMT=-1,000, FV=75,000, CPT I =
0.732%
LG8 5-34 Annuity Interest Rate What annual interest rate would you
need to earn if you wanted a $500 per month contribution to grow to
$45,000 in 6 years?
Use equation 5-2 and solve for i:
%60809.
i/12
i i
Now convert the monthly interest rate to an annual rate by
multiplying by 12 which yields 7.30%.
or TVM calculator: N=72, PV=0, PMT=-500, FV=45,000, CPT I =
0.608%
LG9 5-35 Loan Payments You wish to buy a $25,000 car. The dealer
offers you a 4-year loan with a 10 percent APR. What are the
monthly payments? How would the payment differ if you paid interest
only? What would the consequences of such a decision be?
Use equation 5-9:
If you only paid interest over the length of the loan and your
principal balance was repaid at the end of the 48 months, your
payment would be $208.33 per month (= $25,000×0.10÷12) for interest
only and you would owe $25,000 at the end of the 48 months,
too.
LG9 5-36 Loan Payments You wish to buy a $10,000 dining room set.
The furniture store offers you a 3-year loan with a 11 percent APR.
What are the monthly payments? How would the payment differ if you
paid interest only? What would the consequences of such a decision
be?
Use equation 5-9:
39.327$03273872.0000,10$
12/11.1
If you only paid interest over the length of the loan and your
principal balance was repaid at the end of the 36 months, your
payment would be $91.67 per month (= $10,000×0.11÷12) for interest
only and you would owe $10,000 at the end of the 36 months,
too.
LG10 5-37 Number of Annuity Payments Joey realizes that he has
charged too much on his credit card and has racked up $5,000 in
debt. If he can pay $150 each month and the card charges 17 percent
APR (compounded monthly), how long will it take him to pay off the
debt?
Rewrite equation 5-9 in terms of N:
months 4.45
N
LG10 5-38 Number of Annuity Payments Phoebe realizes that she has
charged too much on her credit card and has racked up $6,000 in
debt. If she can pay $200 each month and the card charges 18
percent APR (compounded monthly), how long will it take her to pay
off the debt?
Rewrite equation 5-9 in terms of N:
months 15.40
N
Advanced Problems 5-39 Future Value Given a 8 percent interest
rate, compute the year 7 future value if
deposits of $1,000 and LG1 $2,000 are made in years 1, and 3,
respectively, and a withdrawal of $500 is made in year 4.
Use equation 5-1:
FV = $1,000 × (1 + 0.08)6 + $2,000× (1 + 0.08)4 - $500× (1 + 0.08)3
= $1,586.87 + $2,720.98 – $629.86 = $3,677.99
LG1 5-40 Future Value Given a 9 percent interest rate, compute the
year 6 future value if deposits of $1,500 and $2,500 are made in
years 2, and 3, respectively, and a withdrawal of $700 is made in
year 5.
5-11
Use equation 5-1:
FV = $1,500 × (1 + 0.09)4 + $2,500× (1 + 0.09)3 - $700× (1 + 0.09)1
= $2,117.37 + $3,237.57 – $763 = $4,591.94
LG4 5-41 Low Financing or Cash Back? A car company is offering a
choice of deals. You LG9 can receive $500 cash back on the
purchase, or a 3 percent APR, 4-year loan. The price of
the car is $15,000 and you could obtain a 4-year loan from your
credit union, at 7 percent APR. Which deal is cheaper?
Compare two cases. The first case is to elect the 3% APR and fully
finance $15,000 over 48 months. Using equation 5-9, the payment
under this scenario would be:
01.332$
0.03/121
The second case is to take the $500 cash back, apply it to the
purchase and finance only $14,500 through your credit union at 7%.
The payment under this scenario would be:
22.347$
0.07/121
The lower payment represents the more advantageous scenario that
you should choose, electing the 3% financing through the car
dealer.
LG4 5-42 Low Financing or Cash Back? A car company is offering a
choice of deals. You LG9 can receive $1,000 cash back on the
purchase, or a 2 percent APR, 5-year loan. The price of
the car is $20,000 and you could obtain a 5-year loan from your
credit union, at 7 percent APR. Which deal is cheaper?
Compare two cases. The first case is to elect the 2% APR and fully
finance $20,000 over 60 months. Using equation 5-9, the payment
under this scenario would be:
56.350$
0.02/121
The second case is to take the $1,000 cash back, apply it to the
purchase and finance only $19,000 through your credit union at 7%.
The payment under this scenario would be:
5-12
22.376$
0.07/121
The lower payment represents the more advantageous scenario that
you should choose, electing the 2% financing through the car
dealer.
LG9 5-43 Amortization Schedule Create the amortization schedule for
a loan of $15,000, paid monthly over 3 years using a 9 percent
APR.
Month Beginning Balance
Total Payment
Interest Paid
Principal Paid
Ending Balance
1 $15,000.00 $477.00 $112.50 $364.50 $14,635.50 2 14,635.50 477.00
109.77 367.23 14,268.27 3 14,268.27 477.00 107.01 369.98 13,898.29
4 13,898.29 477.00 104.24 372.76 13,525.53 5 13,525.53 477.00
101.44 375.55 13,149.98 6 13,149.98 477.00 98.62 378.37 12,771.61 7
12,771.61 477.00 95.79 381.21 12,390.40 8 12,390.40 477.00 92.93
384.07 12,006.33 9 12,006.33 477.00 90.05 386.95 11,619.38
10 11,619.38 477.00 87.15 389.85 11,229.53 11 11,229.53 477.00
84.22 392.77 10,836.76 12 10,836.76 477.00 81.28 395.72 10,441.03
13 10,441.03 477.00 78.31 398.69 10,042.35 14 10,042.35 477.00
75.32 401.68 9,640.67 15 9,640.67 477.00 72.31 404.69 9,235.98 16
9,235.98 477.00 69.27 407.73 8,828.25 17 8,828.25 477.00 66.21
410.78 8,417.47 18 8,417.47 477.00 63.13 413.86 8,003.60 19
8,003.60 477.00 60.03 416.97 7,586.63 20 7,586.63 477.00 56.90
420.10 7,166.54 21 7,166.54 477.00 53.75 423.25 6,743.29 22
6,743.29 477.00 50.57 426.42 6,316.87 23 6,316.87 477.00 47.38
429.62 5,887.25 24 5,887.25 477.00 44.15 432.84 5,454.41 25
5,454.41 477.00 40.91 436.09 5,018.32 26 5,018.32 477.00 37.64
439.36 4,578.96 27 4,578.96 477.00 34.34 442.65 4,136.31 28
4,136.31 477.00 31.02 445.97 3,690.33 29 3,690.33 477.00 27.68
449.32 3,241.02 30 3,241.02 477.00 24.31 452.69 2,788.33 31
2,788.33 477.00 20.91 456.08 2,332.24 32 2,332.24 477.00 17.49
459.50 1,872.74 33 1,872.74 477.00 14.05 462.95 1,409.79 34
1,409.79 477.00 10.57 466.42 943.37
5-13
Chapter 5, Solutions Cornett, Adair, and Nofsinger
35 943.37 477.00 7.08 469.92 473.45 36 473.45 477.00 3.55 473.45
0.00
LG9 5-44 Amortization Schedule Create the amortization schedule for
a loan of $5,000, paid monthly over 2 years using a 8 percent
APR.
Month Beginning Balance
Total Payment
Interest Paid
Principal Paid
Ending Balance
1 $5,000.00 $226.14 $33.33 $192.80 $4,807.20 2 4,807.20 $226.14
$32.05 194.09 4,613.11 3 4,613.11 $226.14 $30.75 195.38 4,417.73 4
4,417.73 $226.14 $29.45 196.68 4,221.04 5 4,221.04 $226.14 $28.14
198.00 4,023.04 6 4,023.04 $226.14 $26.82 199.32 3,823.73 7
3,823.73 $226.14 $25.49 200.64 3,623.08 8 3,623.08 $226.14 $24.15
201.98 3,421.10 9 3,421.10 $226.14 $22.81 203.33 3,217.77
10 3,217.77 $226.14 $21.45 204.68 3,013.09 11 3,013.09 $226.14
$20.09 206.05 2,807.04 12 2,807.04 $226.14 $18.71 207.42 2,599.62
13 2,599.62 $226.14 $17.33 208.81 2,390.81 14 2,390.81 $226.14
$15.94 210.20 2,180.61 15 2,180.61 $226.14 $14.54 211.60 1,969.01
16 1,969.01 $226.14 $13.13 213.01 1,756.00 17 1,756.00 $226.14
$11.71 214.43 1,541.57 18 1,541.57 $226.14 $10.28 215.86 1,325.71
19 1,325.71 $226.14 $8.84 217.30 1,108.42 20 1,108.42 $226.14 $7.39
218.75 889.67 21 889.67 $226.14 $5.93 220.21 669.46 22 669.46
$226.14 $4.46 221.67 447.79 23 447.79 $226.14 $2.99 223.15 224.64
24 224.64 $226.14 $1.50 224.64 0.00
LG4 5-45 Investing for Retirement Monica has decided that she wants
to build enough LG9 retirement wealth that, if invested at 8
percent per year, will provide her with $3,500 of
monthly income for 30 years. To date, she has saved nothing, but
she still has 25 years until she retires. How much money does she
need to contribute per month to reach her goal?
First, calculate the amount you would need to have in 25 years time
to yield the $3,500 monthly payments for an additional 30 years.
Use equation 5-4 to calculate this present value:
5-14
23.992,476$
This amount will become the future value in the next calculation,
assuming 8% interest and 300 level monthly payments. Use equation
5-2 and solve for the monthly payment:
56.501$
0.08/12
300
PMT
LG4 5-46 Investing for Retirement Ross has decided that he wants to
build enough retirement LG9 wealth that, if invested at 7 percent
per year, will provide him with $4,000 of monthly
income for 30 years. To date, he has saved nothing, but he still
has 20 years until he retires. How much money does he need to
contribute per month to reach his goal?
First, calculate the amount you would need to have in 20 years time
to yield the $4,000 monthly payments for an additional 30 years.
Use equation 5-4 to calculate this present value:
27.230,601$
This amount will become the future value in the next calculation,
assuming 7% interest and 240 level monthly payments. Use equation
5-2 and solve for the monthly payment:
16.154,1$
0.07/12
240
PMT
LG9 5-47 Loan Balance Rachel purchased a $15,000 car two years ago
using an 8 percent, 4- year loan. He has decided that he would sell
the car now, if he could get a price that would pay off the balance
of his loan. What is the minimum price Rachel would need to receive
for his car?
First calculate the monthly payment that she has been paying using
equation 5-9:
19.366$
0.08/121
The loan balance is the principal amount outstanding. The duration
of remaining payments is 24, the interest rate is 8% annual and the
monthly payment is $366.19 from the previous calculation. Use these
values to calculate the present value of the loan using equation
5-4:
5-15
66.096,8$
This is the minimum price the car needs to be sold for and it
represents her break even price.
LG9 5-48 Loan Balance Hank purchased a $20,000 car two years ago
using an 9 percent, 5-year loan. He has decided that he would sell
the car now, if he could get a price that would pay off the balance
of his loan. What’s the minimum price Hank would need to receive
for his car?
First calculate the monthly payment that he has been paying using
equation 5-9:
17.415$
0.09/121
The loan balance is the principal amount outstanding. The duration
of remaining payments is 36, the interest rate is 9% annual and the
monthly payment is $415.17 from the previous calculation. Use these
values to calculate the present value of the loan using equation
5-4:
77.055,13$
This is the minimum price the car needs to be sold for and it
represents his break even price.
LG9 5-49 Teaser Rate Mortgage A mortgage broker is offering a
$183,900 30-year mortgage with a teaser rate. In the first two
years of the mortgage, the borrower makes monthly payments on only
a 4 percent APR interest rate. After the second year, the mortgage
interest rate charged increases to 7 percent APR. What are the
monthly payments in the first two years? What are the monthly
payments after the second year?
Use equation 5-9 to calculate the payment using the teaser
rate:
97.877$
12/04.01
Now calculate the outstanding loan balance after the first 24
payments using equation 5-4:
5-16
62.291,177$
Now use this amount for the present value, the new interest rate of
7% over the remaining 336 payments in equation to calculate the new
payment amount after expiration of the teaser rate, using equation
5-9:
89.204,1$
12/07.01
LG9 5-50 Teaser Rate Mortgage A mortgage broker is offering a
$279,000 30-year mortgage with a teaser rate. In the first two
years of the mortgage, the borrower makes monthly payments on only
a 4.5 percent APR interest rate. After the second year, the
mortgage interest rate charged increases to 7.5 percent APR. What
are the monthly payments in the first two years? What are the
monthly payments after the second year?
Use equation 5-9 to calculate the payment using the teaser
rate:
65.413,1$
12/045.01
Now calculate the outstanding loan balance after the first 24
payments using equation 5-4:
04.791,269$
Now use this amount for the present value, the new interest rate of
7.5% over the remaining 336 payments in equation to calculate the
new payment amount after expiration of the teaser rate, using
equation 5-9:
25.923,1$
12/075.01
5-51 Excel Problem Consider a person who begins contributing to a
retirement plan at age 25 and contributes for 40 years until
retirement at age 65. For the first ten years, she
5-17
Chapter 5, Solutions Cornett, Adair, and Nofsinger
contributes $3,000 per year. She increases the contribution rate to
$5,000 per year in years 11 through 20. This is followed by
increases to $10,000 per year in years 21 through 31 and to $15,000
per year for the last ten years. This money earns a 9 percent
return, first compute the value of the retirement plan when she
turns age 65. Then compute the annual payment she would receive
over the next 40 years if the wealth was converted to an annuity
payment at 8 percent.
End of Age Contribution Total Wealth 25 $3,000.00 $3,000.00 26
$3,000.00 $6,270.00 27 $3,000.00 $9,834.30 28 $3,000.00 $13,719.39
29 $3,000.00 $17,954.13 30 $3,000.00 $22,570.00 31 $3,000.00
$27,601.30 32 $3,000.00 $33,085.42 33 $3,000.00 $39,063.11 34
$3,000.00 $45,578.79 35 $5,000.00 $54,680.88 36 $5,000.00
$64,602.16 37 $5,000.00 $75,416.35 38 $5,000.00 $87,203.83 39
$5,000.00 $100,052.17 40 $5,000.00 $114,056.87 41 $5,000.00
$129,321.98 42 $5,000.00 $145,960.96 43 $5,000.00 $164,097.45 44
$5,000.00 $183,866.22 45 $10,000.00 $210,414.18 46 $10,000.00
$239,351.45 47 $10,000.00 $270,893.08 48 $10,000.00 $305,273.46 49
$10,000.00 $342,748.07 50 $10,000.00 $383,595.40 51 $10,000.00
$428,118.99 52 $10,000.00 $476,649.70 53 $10,000.00 $529,548.17 54
$10,000.00 $587,207.50 55 $15,000.00 $655,056.18 56 $15,000.00
$729,011.23 57 $15,000.00 $809,622.25 58 $15,000.00 $897,488.25 59
$15,000.00 $993,262.19 60 $15,000.00 $1,097,655.79 61 $15,000.00
$1,211,444.81 62 $15,000.00 $1,335,474.84
5-18
63 $15,000.00 $1,470,667.58 64 $15,000.00 $1,618,027.66
PMT = ($135,688.06)
Research It! Retirement Income Calculators The Internet provides
some excellent retirement income calculators. You can find one by
Googling “retirement income calculator.” Many of the calculators
allow you to determine your predicted annual income from a
retirement nest egg under different assumptions. For example, you
can spend only the investment income generated from the nest egg.
Most retirees try not to touch the principal. Or, you can spend
both the income and the nest egg itself. These calculators let you
input the size of the retirement wealth and the investment return
to be earned. They then make time value computations to determine
the annual income the nest egg will provide.
Go to a retirement income calculator like the one at MSN Money. Use
the calculator to create a retirement scenario. Use the TVM
equations or a financial calculator to check the Internet
results.
(http://moneycentral.msn.com/investor/calcs/n_retire/main.asp)
SOLUTION: Assuming the principal amount is exhausted and the amount
of savings at my retirement at age 65, here is what the calculator
gives.
Summary
Given a certain amount of savings, how much can I spend annually
during retirement?
Your annual income is estimated to be $70,000.
Information entered 1. Savings Amount saved $1,000,000 Rate of
return 7% Inflation rate 3.8% Average effective tax rate 22.6% 2.
Retirement years Retirement age 65 years Life expectancy 85 years
Estate amount $0
Chapter 5, Solutions Cornett, Adair, and Nofsinger
Using a financial calculator, the following inputs are needed to
determine the projected annual payment:
n = 20 years i = 1.07/1.038 -1 = 3.083% PV = $1,000,000
CPT PMT = $67,732.56 (The calculator rounds this amount to the
nearest $10,000 for an estimate of $70,000 gross annually.)
Integrated Mini Case: Paying on your Stafford loan
Consider Gunther, a new freshman who has just received a Stafford
student loan and started college. He plans to obtain the maximum
loan from Stafford at the beginning of each year. Although Gavin
does not have to make any payments while he is in school, the 6.8
percent interest owed (compounded monthly) accrues and is added to
the balance of the loan.
Stafford loan limits: Freshman $2,625 Sophomore $3,500 Junior
$5,500 Senior $5,500
After graduation, Gavin gets a six month grace period. This means
that monthly payments are still not required, but interest is still
accruing. After the grace period, the standard repayment plan is to
amortize the debt using monthly payments for 10 years.
a. Show a time line of when the loans will be taken. b. What will
be the loan balance when Gavin graduates after his fourth year of
school? c. What is the loan balance six months after graduation? d.
Using the standard repayment plan and a 6.8 percent APR interest
rate, compute the
monthly payments Gavin owes after the grace period.
SOLUTION: a. Show a time line of when the loans will be
taken.
Cash Flows $2,625 $3,500 $5,500 $5,500
Period 0 6.8% 1 6.8% 2 6.8% 3 6.8% 4 6.8% 5 years
5-20
Chapter 5, Solutions Cornett, Adair, and Nofsinger
b. What will be the loan balance when Gavin graduates after his
fourth year of school?
Each payment needs to be moved forward with 6.8% interest to the
middle of years 4 and 5 to calculate the outstanding accrued loan
balance as of the date payments are set to begin:
FV4 = $2,625 × (1.068)4 + $3,500 × (1.068)3 + $5,500 × (1.068)2 +
$5,500 × (1.068)1
FV4 = $3,415.19 + $4,263.65 + $6,273.43 + $5,874.00 =
$19,826.27
c. What is the loan balance six months after graduation?
Each payment needs to be moved forward with 6.8% interest to the
middle of years 4 and 5 to calculate the outstanding accrued loan
balance as of the date payments are set to begin:
FV4.5= $2,625 × (1.068)4.5 + $3,500 × (1.068)3.5 + $5,500 ×
(1.068)2.5 + $5,500 × (1.068)1.5
FV4.5= $3,529.39 + $4,406.23 + $6,483.22 + $6,070.43 =
$20,489.27
Note, this can be checked by multiplying $19,826.27 by
1.0680.5.
d. Using the standard repayment plan and a 6.8 percent APR interest
rate, compute the monthly payments Gavin owes after the grace
period.
Using equation 5-9, the monthly payments will be:
79.235$
12/068.01
Combined Chapter 4 and Chapter 5 Problems
4&5-1 Future Value Consider that you are 35 years old and have
just changed to a new job. You have $80,000 in the retirement plan
from your former employer. You can roll that money into the
retirement plan of the new employer. You will also contribute
$5,000 each year into your new employer’s plan. If the rolled-over
money and the new contributions both earn a 7 percent return, how
much should you expect to have when you retire in 30 years?
The future value can be calculated by adding the accumulated value
of $80,000 brought forward with interest 30 years to a 30 year
annuity of $5,000 per year, both using the 7% interest assumption.
Use equations 5-1 and 5-2 and add the results:
33.284,081,1$93.303,472$40.980,608$
0.07
Chapter 5, Solutions Cornett, Adair, and Nofsinger
4&5-2 Future Value Consider that you are 45 years old and have
just changed to a new job. You have $150,000 in the retirement plan
from your former employer. You can roll that money into the
retirement plan of the new employer. You will also contribute
$8,000 each year into your new employer’s plan. If the rolled-over
money and the new contributions both earn an 8 percent return, how
much should you expect to have when you retire in 20 years?
The future value can be calculated by adding the accumulated value
of $150,000 brought forward with interest 20 years to a 20 year
annuity of $8,000 per year, both using the 8% interest assumption.
Use equations 5-1 and 5-2 and add the results:
28.239,065,1$71.095,366$57.143,699$
0.08
20 20
65 Abe
4&5-3 Future Value and Number of Annuity Payments Your client
has been given a trust fund valued at $1 million. He cannot access
the money until he turns 65 years old, which is in 25 years. At
that time, he can withdrawal $25,000 per month. If the trust fund
is invested at a 5.5 percent rate, how many months will it last
your client once he starts to withdraw the money?
Using equation 5-1, $1 million will accumulate for 25 more years at
5.5% interest for a future value:
35.392,813,3$055.01000,000,1$FVA 25 65 Abe
months 263
N
4&5-4 Future Value and Number of Annuity Payments Your client
has been given a trust fund valued at $1.5 million. She cannot
access the money until she turns 65 years old, which is in 15
years. At that time, she can withdraw $20,000 per month. If the
trust fund is invested at a 5 percent rate, how many months will it
last your client once she starts to withdraw the money?
Using equation 5-1, $1.5 million will accumulate for 15 more years
at 5% interest for a future value:
27.392,118,3$05.01000,500,1$FVA 15 65 Abe
5-22
months 253
N
4&5-5 Present Value and Annuity Payments A local furniture
store is advertising a deal in which you buy a $3,000 dining room
set and do not need to pay for two years (no interest cost is
incurred). How much money would you have to deposit now in a
savings account earning 5 percent APR, compounded monthly, to pay
the $3,000 bill in two years? Alternatively, how much would you
have to deposit in the savings account each month to be able to pay
the bill?
Use equation 5-1 and solve for the lump sum payment:
08.715,2$12/05.01$3,000 PV 24
monthper 11.119$
24
PMT
4&5-6 Present Value and Annuity Payments A local furniture
store is advertising a deal in which you buy a $5,000 living room
set with 3 years before you need to make any payments (no interest
cost is incurred). How much money would you have to deposit now in
a savings account earning 4 percent APR, compounded monthly, to pay
the $5,000 bill in three years? Alternatively, how much would you
have to deposit in the savings account each month to be able to pay
the bill?
Use equation 5-1 and solve for the lump sum payment:
49.435,4$12/04.01$5,000PV 36
95.130$
0.04/12
36
PMT
4&5-7 House Appreciation and Mortgage Payments Say that you
purchase a house for $200,000 by getting a mortgage for $180,000
and paying a $20,000 down payment. If you get a 30-year mortgage
with a 7 percent interest rate, what are the monthly payments? What
would the loan balance be in 10 years? If the house appreciates at
3 percent per year, what will be the value of the house in 10
years? How much of this value is your equity?
Use equation 5-9 to calculate your monthly payment:
5-23
54.197,1$
12/07.01
In ten years, you will have 240 payments of $1,197.54 left to pay.
The present value can be calculated using equation 5-4:
71.461,154$
An appreciation of 3% per year will result in a forecast future
value of the home using the original purchase price in equation
5-1:
28.783,268$03.1000,200$FV 10 years 10
The amount of equity is the difference between the home’s value and
the outstanding balance on the mortgage:
Equity = $268,783.28 - $154,461.17 = $114,321.57
4&5-8 House Appreciation and Mortgage Payments Say that you
purchase a house for $150,000 by getting a mortgage for $135,000
and paying a $15,000 down payment. If you get a 15-year mortgage
with a 7 percent interest rate, what are the monthly payments? What
would the loan balance be in 5 years? If the house appreciates at 4
percent per year, what will be the value of the house in 5 years?
How much of this value is your equity?
Use equation 5-9 to calculate your monthly payment:
42.213,1$
12/07.01
In ten years, you will have 120 payments of $1,213.42 left to pay.
The present value can be calculated using equation 5-4:
44.507,104$
An appreciation of 4% per year will result in a forecast future
value of the home using the original purchase price in equation
5-1:
5-24
94.497,182$04.1000,150$FV 5 5years
The amount of equity is the difference between the home’s value and
the outstanding balance on the mortgage:
Equity = $182,497.94-$104,507.44=$77,990.50
4&5-9 Construction Loan You have secured a loan from your bank
for 2 years to build your home. The terms of the loan are that you
will borrow $100,000 now and an additional $100,000 in one year.
Interest of 10 percent APR will be charged on the balance monthly.
Since no payments will be made during the two-year loan, the
balance will grow at the 10% compounded rate. At the end of the two
years, the balance will be converted to a traditional 30-year
mortgage at a 6 percent interest rate. What will you paying monthly
mortgage payments (Principal and Interest only)?
Use equation 5-1 to calculate the capitalized value of your
mortgage at the end of year 2:
41.510,232$0.10/121000,100$12/10.01000,100$FV 1224 2
This is the amount that you will need to finance over 30 years at
6%. Use equation 5-9 to compute the monthly payment:
02.394,1$
12/06.01
4&5-10 Construction Loan You have secured a loan from your bank
for 2 years to build your home. The terms of the loan are that you
will borrow $100,000 now and an additional $50,000 in one year.
Interest of 9 percent APR will be charged on the balance monthly.
Since no payments will be made during the two-year loan, the
balance will grow. At the end of the two years, the balance will be
converted to a traditional 30-year mortgage at a 7 percent interest
rate. What will you pay as monthly mortgage payments (Principal and
Interest only)?
Use equation 5-1 to calculate the capitalized value of your
mortgage at the end of year 2:
69.331,174$0.09/121000,50$12/09.01000,100$FV 1224 2
This is the amount that you will need to finance over 30 years at
7%. Use equation 5-9 to compute the monthly payment:
5-25
83.159,1$
12/07.01