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Copyright © 2003 Pearson Education, Inc. Slide 4-1
Chapter 4Chapter 4
Time Value of Time Value of MoneyMoney
Copyright © 2003 Pearson Education, Inc. Slide 4-2
Learning Goals1. Discuss the role of time value in finance, the use of
computational aids, and the basic patterns of cash
flow.
2. Understand the concept of future value and present
value, their calculation for a single amounts, and the
relationship of present value to future value.
3. Find the future value and the present value of both an
ordinary annuity and an annuity due, and the present
value of a perpetuity.
Copyright © 2003 Pearson Education, Inc. Slide 4-3
Learning Goals4. Calculate both the future value and the present value
of a mixed stream of cash flows.
5. Understand the effect that compounding interest more
frequently than annually has on future value and the
effective annual rate of interest.
6. Describe the procedures involved in (1) determining
deposits to accumulate to a future sum, (2) loan
amortization, (3) finding interest or growth rates, and
(4) finding an unknown number of periods.
Copyright © 2003 Pearson Education, Inc. Slide 4-4
The Role of Time Value in Finance
• Most financial decisions involve costs & benefits that
are spread out over time.
• Time value of money allows comparison of cash flows
from different periods.
Question?
Would it be better for a company to invest $100,000 in a product that would return a total of $200,000 after one year, or one that would return
$220,000 after two years?
Copyright © 2003 Pearson Education, Inc. Slide 4-5
Answer!
It depends on the interest rate!
The Role of Time Value in Finance
• Most financial decisions involve costs & benefits that
are spread out over time.
• Time value of money allows comparison of cash flows
from different periods.
Copyright © 2003 Pearson Education, Inc. Slide 4-6
Basic Concepts
• Future Value: compounding or growth over time
• Present Value: discounting to today’s value
• Single cash flows & series of cash flows can be
considered
• Time lines are used to illustrate these relationships
Copyright © 2003 Pearson Education, Inc. Slide 4-7
Computational Aids
• Use the Equations
• Use the Financial Tables
• Use Financial Calculators
• Use Spreadsheets
Copyright © 2003 Pearson Education, Inc. Slide 4-8
Computational Aids
Copyright © 2003 Pearson Education, Inc. Slide 4-9
Computational Aids
Copyright © 2003 Pearson Education, Inc. Slide 4-10
Computational Aids
Copyright © 2003 Pearson Education, Inc. Slide 4-11
Computational Aids
Copyright © 2003 Pearson Education, Inc. Slide 4-12
Advantages of Computers & Spreadsheets
• Spreadsheets go far beyond the computational
abilities of calculators.
• Spreadsheets have the ability to program logical
decisions.
• Spreadsheets display not only the calculated values of
solutions but also the input conditions on which
solutions are based.
• Spreadsheets encourage teamwork.
• Spreadsheets enhance learning.
• Spreadsheets communicate as well as calculate.
Copyright © 2003 Pearson Education, Inc. Slide 4-13
Basic Patterns of Cash Flow
• The cash inflows and outflows of a firm can be
described by its general pattern.
• The three basic patterns include a single amount, an
annuity, or a mixed stream:
Copyright © 2003 Pearson Education, Inc. Slide 4-14
Simple Interest
• Year 1: 5% of $100 = $5 + $100 = $105
• Year 2: 5% of $100 = $5 + $105 = $110
• Year 3: 5% of $100 = $5 + $110 = $115
• Year 4: 5% of $100 = $5 + $115 = $120
• Year 5: 5% of $100 = $5 + $120 = $125
With simple interest, you don’t earn interest on interest.
Copyright © 2003 Pearson Education, Inc. Slide 4-15
Compound Interest
• Year 1: 5% of $100.00 = $5.00 + $100.00 = $105.00
• Year 2: 5% of $105.00 = $5.25 + $105.00 = $110.25
• Year 3: 5% of $110.25 = $5 .51+ $110.25 = $115.76
• Year 4: 5% of $115.76 = $5.79 + $115.76 = $121.55
• Year 5: 5% of $121.55 = $6.08 + $121.55 = $127.63
With compound interest, a depositor earns interest on interest!
Copyright © 2003 Pearson Education, Inc. Slide 4-16
Time Value Terms
• PV0 = present value or beginning amount
• k = interest rate
• FVn = future value at end of “n” periods
• n = number of compounding periods
• A = an annuity (series of equal payments or
receipts)
Copyright © 2003 Pearson Education, Inc. Slide 4-17
Four Basic Models
• FVn = PV0(1+k)n = PV(FVIFk,n)
• PV0 = FVn[1/(1+k)n] = FV(PVIFk,n)
• FVAn = A (1+k)n - 1 = A(FVIFAk,n)
k
• PVA0 = A 1 - [1/(1+k)n] = A(PVIFAk,n) k
Copyright © 2003 Pearson Education, Inc. Slide 4-18
Future Value Example
You deposit $2,000 today at 6%
interest. How much will you have in 5
years?
$2,000 x (1.06)5 = $2,000 x FVIF6%,5
$2,000 x 1.3382 = $2,676.40
Algebraically and Using FVIF Tables
Copyright © 2003 Pearson Education, Inc. Slide 4-19
Future Value Example
You deposit $2,000 today at 6%
interest. How much will you have in 5
years?
Using Excel
PV 2,000$ k 6.00%n 5FV? $2,676
Excel Function
=FV (interest, periods, pmt, PV)
=FV (.06, 5, , 2000)
Copyright © 2003 Pearson Education, Inc. Slide 4-20
Future Value Example A Graphic View of Future Value
Copyright © 2003 Pearson Education, Inc. Slide 4-21
Compounding More Frequently than Annually
• Compounding more frequently than once a year
results in a higher effective interest rate because you
are earning on interest on interest more frequently.
• As a result, the effective interest rate is greater than
the nominal (annual) interest rate.
• Furthermore, the effective rate of interest will increase
the more frequently interest is compounded.
Copyright © 2003 Pearson Education, Inc. Slide 4-22
Compounding More Frequently than Annually
• For example, what would be the difference in future
value if I deposit $100 for 5 years and earn 12%
annual interest compounded (a) annually, (b)
semiannually, (c) quarterly, an (d) monthly?
Annually: 100 x (1 + .12)5 = $176.23
Semiannually: 100 x (1 + .06)10 = $179.09
Quarterly: 100 x (1 + .03)20 = $180.61
Monthly: 100 x (1 + .01)60 = $181.67
Copyright © 2003 Pearson Education, Inc. Slide 4-23
Compounding More Frequently than Annually
Annually SemiAnnually Quarterly Monthly
PV 100.00$ 100.00$ 100.00$ 100.00$
k 12.0% 0.06 0.03 0.01
n 5 10 20 60
FV $176.23 $179.08 $180.61 $181.67
On Excel
Copyright © 2003 Pearson Education, Inc. Slide 4-24
Continuous Compounding• With continuous compounding the number of
compounding periods per year approaches infinity.
• Through the use of calculus, the equation thus
becomes:
FVn (continuous compounding) = PV x (ekxn)
where “e” has a value of 2.7183.
• Continuing with the previous example, find the Future
value of the $100 deposit after 5 years if interest is
compounded continuously.
Copyright © 2003 Pearson Education, Inc. Slide 4-25
Continuous Compounding• With continuous compounding the number of
compounding periods per year approaches infinity.
• Through the use of calculus, the equation thus
becomes:
FVn (continuous compounding) = PV x (ekxn)
where “e” has a value of 2.7183.
FVn = 100 x (2.7183).12x5 = $182.22
Copyright © 2003 Pearson Education, Inc. Slide 4-26
Nominal & Effective Rates• The nominal interest rate is the stated or contractual rate of
interest charged by a lender or promised by a borrower.
• The effective interest rate is the rate actually paid or earned.
• In general, the effective rate > nominal rate whenever
compounding occurs more than once per year
EAR = (1 + k/m) m -1
Copyright © 2003 Pearson Education, Inc. Slide 4-27
Nominal & Effective Rates
• For example, what is the effective rate of interest on
your credit card if the nominal rate is 18% per year,
compounded monthly?
EAR = (1 + .18/12) 12 -1
EAR = 19.56%
Copyright © 2003 Pearson Education, Inc. Slide 4-28
Present Value• Present value is the current dollar value of a future
amount of money.
• It is based on the idea that a dollar today is worth
more than a dollar tomorrow.
• It is the amount today that must be invested at a given
rate to reach a future amount.
• Calculating present value is also known as
discounting.
• The discount rate is often also referred to as the
opportunity cost, the discount rate, the required return,
or the cost of capital.
Copyright © 2003 Pearson Education, Inc. Slide 4-29
Present Value Example
How much must you deposit today in order to
have $2,000 in 5 years if you can earn 6%
interest on your deposit?
$2,000 x [1/(1.06)5] = $2,000 x PVIF6%,5
$2,000 x 0.74758 = $1,494.52
Algebraically and Using PVIF Tables
Copyright © 2003 Pearson Education, Inc. Slide 4-30
Present Value Example
How much must you deposit today in order to
have $2,000 in 5 years if you can earn 6%
interest on your deposit?
FV 2,000$ k 6.00%n 5PV? $1,495
Excel Function
=PV (interest, periods, pmt, FV)
=PV (.06, 5, , 2000)
Using Excel
Copyright © 2003 Pearson Education, Inc. Slide 4-31
Present Value Example A Graphic View of Present Value
Copyright © 2003 Pearson Education, Inc. Slide 4-32
Annuities• Annuities are equally-spaced cash flows of equal size.
• Annuities can be either inflows or outflows.
• An ordinary (deferred) annuity has cash flows that
occur at the end of each period.
• An annuity due has cash flows that occur at the
beginning of each period.
• An annuity due will always be greater than an
otherwise equivalent ordinary annuity because interest
will compound for an additional period.
Copyright © 2003 Pearson Education, Inc. Slide 4-33
Annuities
Copyright © 2003 Pearson Education, Inc. Slide 4-34
Future Value of an Ordinary Annuity
• Annuity = Equal Annual Series of Cash Flows
• Example: How much will your deposits grow to if you
deposit $100 at the end of each year at 5% interest for
three years.
FVA = 100(FVIFA,5%,3) = $315.25
Year 1 $100 deposited at end of year = $100.00
Year 2 $100 x .05 = $5.00 + $100 + $100 = $205.00
Year 3 $205 x .05 = $10.25 + $205 + $100 = $315.25
Using the FVIFA Tables
Copyright © 2003 Pearson Education, Inc. Slide 4-35
Future Value of an Ordinary Annuity
• Annuity = Equal Annual Series of Cash Flows
• Example: How much will your deposits grow to if you
deposit $100 at the end of each year at 5% interest for
three years.
Using Excel
PMT 100$ k 5.0%n 3FV? 315.25$
Excel Function
=FV (interest, periods, pmt, PV)
=FV (.06, 5,100, )
Copyright © 2003 Pearson Education, Inc. Slide 4-36
Future Value of an Annuity Due
• Annuity = Equal Annual Series of Cash Flows
• Example: How much will your deposits grow to if you
deposit $100 at the beginning of each year at 5%
interest for three years.
FVA = 100(FVIFA,5%,3)(1+k) = $330.96
Using the FVIFA Tables
FVA = 100(3.152)(1.05) = $330.96
Copyright © 2003 Pearson Education, Inc. Slide 4-37
Future Value of an Annuity Due
• Annuity = Equal Annual Series of Cash Flows
• Example: How much will your deposits grow to if you
deposit $100 at the beginning of each year at 5%
interest for three years.
Using Excel
Excel Function
=FV (interest, periods, pmt, PV)
=FV (.06, 5,100, )
=315.25*(1.05)
PMT 100.00$ k 5.00%n 3FV $315.25FVA? 331.01$
Copyright © 2003 Pearson Education, Inc. Slide 4-38
Present Value of an Ordinary Annuity
• Annuity = Equal Annual Series of Cash Flows
• Example: How much could you borrow if you could
afford annual payments of $2,000 (which includes
both principal and interest) at the end of each year for
three years at 10% interest?
PVA = 2,000(PVIFA,10%,3) = $4,973.70
Using PVIFA Tables
Copyright © 2003 Pearson Education, Inc. Slide 4-39
Present Value of an Ordinary Annuity
• Annuity = Equal Annual Series of Cash Flows
• Example: How much could you borrow if you could
afford annual payments of $2,000 (which includes
both principal and interest) at the end of each year for
three years at 10% interest?
Using Excel
PMT 2,000$ I 10.0%n 3PV? $4,973.70
Excel Function
=PV (interest, periods, pmt, FV)
=PV (.10, 3, 2000, )
Copyright © 2003 Pearson Education, Inc. Slide 4-40
Present Value of a Mixed Stream
• A mixed stream of cash flows reflects no particular
pattern
• Find the present value of the following mixed stream
assuming a required return of 9%.
Using Tables
Year Cash Flow PVIF9%,N PV
1 400 0.917 366.80$
2 800 0.842 673.60$
3 500 0.772 386.00$
4 400 0.708 283.20$
5 300 0.650 195.00$
PV 1,904.60$
Copyright © 2003 Pearson Education, Inc. Slide 4-41
Present Value of a Mixed Stream
• A mixed stream of cash flows reflects no particular
pattern
• Find the present value of the following mixed stream
assuming a required return of 9%.
Using EXCEL
Year Cash Flow
1 400
2 800
3 500
4 400
5 300
NPV $1,904.76
Excel Function
=NPV (interest, cells containing CFs)
=NPV (.09,B3:B7)
Copyright © 2003 Pearson Education, Inc. Slide 4-42
Future Value of a Mixed Stream
Copyright © 2003 Pearson Education, Inc. Slide 4-43
Future Value of a Mixed Stream
Copyright © 2003 Pearson Education, Inc. Slide 4-44
Present Value of a Perpetuity
• A perpetuity is a special kind of annuity.
• With a perpetuity, the periodic annuity or cash flow
stream continues forever.
PV = Annuity/k
• For example, how much would I have to deposit today in
order to withdraw $1,000 each year forever if I can earn
8% on my deposit?
PV = $1,000/.08 = $12,500
Copyright © 2003 Pearson Education, Inc. Slide 4-45
Loan Amortization
Copyright © 2003 Pearson Education, Inc. Slide 4-46
Determining Interest or Growth Rates• At times, it may be desirable to determine the
compound interest rate or growth rate implied by a
series of cash flows.
• For example, you invested $1,000 in a mutual fund in
1994 which grew as shown in the table below?
1994 1,000$ 1995 1,127 1996 1,158 1997 2,345 1998 3,985 1999 4,677 2000 5,525
It is important to notethat although 7 years show, there are only 6 time periods
between the initial deposit and the final value.
Copyright © 2003 Pearson Education, Inc. Slide 4-47
Determining Interest or Growth Rates• At times, it may be desirable to determine the
compound interest rate or growth rate implied by a
series of cash flows.
• For example, you invested $1,000 in a mutual fund in
1994 which grew as shown in the table below?1994 1,000$ 1995 1,127 1996 1,158 1997 2,345 1998 3,985 1999 4,677 2000 5,525
Thus, $1,000 is the presentvalue, $5,525 is the futurevalue, and 6 is the numberof periods. Using Excel,
we get:
Copyright © 2003 Pearson Education, Inc. Slide 4-48
Determining Interest or Growth Rates• At times, it may be desirable to determine the
compound interest rate or growth rate implied by a
series of cash flows.
• For example, you invested $1,000 in a mutual fund in
1994 which grew as shown in the table below?1994 1,000$ 1995 1,127 1996 1,158 1997 2,345 1998 3,985 1999 4,677 2000 5,525
PV 1,000$ FV 5,525$ n 6k? 33.0%
Copyright © 2003 Pearson Education, Inc. Slide 4-49
Determining Interest or Growth Rates• At times, it may be desirable to determine the
compound interest rate or growth rate implied by a
series of cash flows.
• For example, you invested $1,000 in a mutual fund in
1994 which grew as shown in the table below?1994 1,000$ 1995 1,127 1996 1,158 1997 2,345 1998 3,985 1999 4,677 2000 5,525
Excel Function
=Rate(periods, pmt, PV, FV)
=Rate(6, ,1000, 5525)