Corporate Finance Lectures PDF

Summary

These lecture notes cover the fundamental concepts of corporate finance, providing an overview of key financial decisions, and capital budgeting. The document explains the value of cash flows, and different approaches to project evaluation.

Full Transcript

Corporate Finance

Agenda

1. What is corporate finance?
2. The corporate business form
3. Key financial decisions

Corporate Finance

Corporate finance is the study of how firms or businesses make financial
decisions.
Firms generate cash flows (CFs) by investing in real assets, which they
pay for by issuing financial assets (eg, stocks and bonds).
Our view of the firm: a stream of (uncertain) cash flows.

Flow of Funds

1

1

Source: Brealey, Myers, and Allen

Types of Firms (US)

2
2

Source: Berk and DeMarzo

The Corporate Business Form
A corporation is a legal entity (ie, a legal “person”) owned by, but legally
distinct from its owners (“shareholders”). It is typically characterised by:
• Separation of ownership and control
• Limited liability for its owners
• Owners and the business are taxed separately (leads to the “double
taxation problem”)
Goal of the corporation: maximise shareholder wealth.

Organisational Chart of a Typical Corporation

3
3

Source: Berk and DeMarzo

The Key Financial Decisions
The role of the
financial manager
Valuation and
investment
decisions

Cash flows
correctly
computed

Return rate
should be
appropriate

Dividend
decisions

How much?

What form?

Financing
decisions

Identify costs
&
benefits
of financing
instruments

Choose
the
optimal
mix

Risk
Management
and
Hedging
Identify
which
risks
should be
hedged

Find
the
appropriate
instruments

The End

Capital Budgeting and the NPV Rule

Capital Budgeting
A key task of managers is to allocate capital between projects.
• Stand-alone: Is Project A better than doing nothing?
• Mutually exclusive: Is Project A better than Project B?
The objective of capital budgeting is to select the optimal mix of physical
(“real”) investments/projects.
Our focus will be on the financial tools for valuation. These tools attach
numerical values to projects to aid comparison and assist in the
decision-making process.

Opportunity Cost of Capital

1

Financial managers should always consider the opportunity cost of investing in a project.
1

Source: Brealey, Myers, and Allen

Net Present Value (NPV)

NPV0 =

N
X
t=0

E (CFt )
(1 + r )t

NPV converts a project’s future cash flows into comparable quantities that
can simply be summed. A project’s NPV measures its dollar contribution
to firm value in today’s money.

NPV rule (stand-alone project): Accept the project if NPV > 0.

NPV Advantages
Precise; NPV accounts for:
• Time value of money
• Compensation for bearing risk
Convenient: present values are additive
• NPV(A + B) = NPV(A) + NPV(B)
• Assuming Projects A and B are independent

The End

The Optimality of the NPV Rule

Optimality of NPV
• Two-period model: t = 0 and t = 1
• A firm has current endowment B0 , which can be used to support current and
future consumption, C0 and C1 , respectively
• Two ways to invest
1. Financial markets:
• borrow/lend at interest rate r > 0

2. Real assets:
• t = 0: I0
⇐ investment outlay
• t = 1: f (I0 ) ⇐ income from physical investment

Optimality of NPV (cont.)
• Budget constraints
• Savings (t = 0):
S0 = B0 − (C0 + I0 )

(1)

C1 = f (I0 ) + S0 (1 + r )

(2)

• Future consumption (t = 1):

• Combining (1) and (2) gives the intertemporal budget constraint line
y-intercept

z

}|

slope

{

z }| {

C1 = [(B0 − I0 ) (1 + r ) + f (I0 )] − (1 + r ) C0

(3)

Graphically
C1

(B0 − I0 ) (1 + r ) + f (I0 )

slope = −(1 + r )

C0

Investors prefer more consumption to less, so irrespective of how they feel
about consuming today vs. tomorrow, the further away from the origin the
intertemporal budget constraint line is, the better. Therefore, managers seeking to
maximise shareholder utility should adopt a physical investment policy that pushes
the line out as far out as possible.

Optimality of NPV
This goal is equivalent to maximising the x-intercept (or y-intercept) of the budget
constraint line.
• x-intercept occurs when C1 = 0. That is, when
NPV

z

}|

f (I0 )
− I0
C0 = B0 +
(1 + r )

{

• Maximise x-intercept ⇐⇒ maximise NPV of physical investments
• The x-intercept also represents investors’ current wealth; therefore,
maximising NPV is equivalent to maximising wealth

The End

Competitors to NPV

Agenda

1. Book rate of return
2. Payback period
3. Internal rate of return (IRR)

Book Rate of Return
The book/accounting rate of return is average income divided by
average book value over a project’s life.

Book rate of return =

Book income
Book assets

Decision rule: Accept if book rate of return is ‘high enough’.
It is rarely used to make decisions; many problems:
• The components reflect tax and accounting figures and are not
market values or cash flows.
• Time value of money is ignored.
• It only considers averages, and risk is ignored.

Payback Period
The payback period is the the number of years it takes before the
cumulative forecasted cash flows of a project equals the initial outlay.
Decision rule: Accept projects that “pay back” within a desired time frame.
This method is flawed:
• It ignores all cash flows after the payback period.
• It ignores time value of money and risk, although this can be
remedied by discounting cash flows before calculating the payback
period (called “discounted payback”).
• The decision rule cut-off is arbitrary.

Payback Period: Example
Examine the following three projects and note the mistake we would make
if we insisted on only taking projects with a payback period of two years or
less.
Project

C0

C1

C2

C3

Payback

NPV @ 10%

A

−2,000

500

500

5,000

2.2

+2,624

B

−2,000

500

1,800

0

1.8

−58

C

−2,000

1,800

500

0

1.4

+50

PaybackA = 2 +

2000−1000
5000

= 2 + 0.2

Internal Rate of Return (IRR)
• An equivalent way of stating the NPV criterion: accept if the expected
return on investment is higher than the opportunity cost of capital
• The opportunity cost of capital is also called the project’s hurdle rate
• When cost of capital = expected return on investment, NPV = 0
• The IRR is the discount rate that makes NPV = 0

NPV0 =

N
X
t=0

E (CFt )
=0
(1 + IRR)t

• Easily calculated in a spreadsheet or with a financial calculator

IRR: Example
• Upfront investment: $4,000
• The investment will generate $2,000 and $4,000 in cash flows in the
next two years respectively
• What is the IRR of the investment?
4000
2000
+
=0
1 + IRR (1 + IRR)2
√
−b ±
b2 − 4ac
and use quadratic formula: x =
2a

NPV = −4000 +
• Set x =

1
1 + IRR

• IRR = 28.08%

IRR and the NPV Profile
2,000

NPV ($)

1,000
IRR

Discount rate (%)

0
20 28

40

60

80

100

−1,000

−2,000

Decision rule: Accept investment opportunities offering an IRR in excess
of their opportunity cost of capital.

Pitfalls of IRR
Blindly applying the IRR rule can lead to incorrect decisions, ie, accepting
negative NPV projects.
We need to be wary of:
• Lending vs borrowing
• Multiple IRRs
• No IRR
• Mutually exclusive projects

Lending vs Borrowing
• Two streams of cash flows, both same in magnitude but opposite in
sign, will have the same IRR.
• Take the following two projects as an example. Which project do you
prefer?
Project
C0
C1
IRR
A
−1,000 +1,500 50%
B
+1,000 −1,500 50%

NPV @ 10%
+364
−364

You should be able to verify:
NPVA = −NPVB → IRRA,B = (1500/1000) − 1 = 50%

Lending vs Borrowing, (cont.)
500
400
300

NPV ($)

200
100
0
−100

10

20

30

40

50

60

70

Discount rate (%)
80

−200
−300
−400

Project A
Project B

−500

For financing projects, the IRR rule needs to be reversed: only accept if
IRR < cost of capital.

Multiple IRRs
• Certain cash flow streams can generate NPV = 0 at two (or more)
different discount rates.
• This can happen when future cash flows change sign more than
once.
• Example: The following cash flow stream has an IRR at both 3.17%
and 13.86%.
C0 C1
−50 15

...
...

...
...

C9
15

C10
−90

Multiple IRRs, (cont.)
2

IRR2 = 13.86%

NPV ($)

0
5
IRR1 = 3.17%
−2

−4

−6

10

15

Discount rate (%)
20

No IRR
• It is possible to have no IRR and a positive NPV, or no IRR and a
negative NPV.
• These are projects that should always be accepted or rejected,
respectively.
• For example:
Project
C0
C1
C2
C
+1,000 −3,000 +2,500
D
−1,500 4,000 −2,800

IRR NPV @ 10%
None
+339
None
−178

No IRR, (cont.)
500
Project C
Project D

400
300

NPV ($)

200
100
0
10
−100
−200
−300

20

30

40

50

60

70

80

90

Discount rate (%)
100

IRR and Mutually Exclusive Projects
• Decision rule: Pick the project with the highest IRR.
• Do not compare “apples to oranges”: the projects being compared
should be in the same risk-class (ie, same cost of capital).
• The IRR rule works well if the NPV profiles look like this:

NPV ($)

Project X
Project Y

10

20

30

40

Discount rate (%)
50

IRR Pitfalls: Mutually Exclusive Projects, Part I
But, the IRR rule can sometimes result in incorrect decisions when
projects differ in their scale and/or the timing of their cash flows.
Differences in scale
• The following two projects illustrate the problem. IRR picks E, but F is
better at the cost of capital.
Project
C0
E
−10,000
F
−20,000

C1
+20,000
+35,000

IRR NPV @ 10%
100%
+8,182
75%
+11,818

IRR Pitfalls: Mutually Exclusive Projects, Part II
15,000
Project E
Project F

NPV ($)

10,000

5,000
IRRE = 100%

0
10

20

30

40

50

60

70

80

Cross-over @ 50%
IRRF = 75%

90

Discount rate (%)
100 110 120

IRR Pitfalls: Mutually Exclusive Projects, Part III
Differences in the timing of CFs
• Project G, where cash flows arrive relatively earlier, is favoured by
IRR, but H is better at the cost of capital.
Project
C0
G
−10,000
H
−10,000

C1
+18,000
+5,000

C2
+500
+20,000

IRR
NPV @ 10%
82.7%
+6,777
68.6%
+11,074

IRR Pitfalls: Mutually Exclusive Projects, Part IV
15,000
Project G
Project H

NPV ($)

10,000

5,000
IRRG = 83%

0
10

20

30

40

Cross-over @ 50%

50

60

70

IRRH = 69%

80

90

Discount rate (%)
100 110 120

IRR: A Quick Question
Consider projects Alpha and Beta below.
• You can undertake only one of the two projects. The opportunity cost
of capital is 8%. Use the IRR rule to make the choice.
Project
C0
Alpha −400,000
Beta
−200,000

C1
+241,000
+131,000

C2
+293,000
+172,000

IRR
21%
31%

Hint: Calculating the IRR of the incremental cash flows that would result
from taking one project instead of the other provides a potential remedy
when comparing mutually exclusive projects.

Answer
• The incremental CFs from investing in Alpha rather than Beta are:
Project
C0
Alpha – Beta −200,000

C1
+110,000

C2
+121,000

• The IRR of the incremental CFs is 10%:
110, 000 121, 000
−200, 000 +
+
=0
1.10
1.102
• The IRR on Beta exceeds the cost of capital and so does the IRR of
the incremental investment in Alpha.
• Choose Alpha
• Note: NPV at 8% gives the same choice.

Answer
Alpha

Cross-over @ 10%

Beta

1 · 105

NPV ($)

50,000
IRRBeta = 31%

Discount rate (%)

0
8 10

20

−50,000
IRRAlpha = 21%

30

40

In Practice
Survey data on CFO use of investment evaluation tools

1

1

Source: Brealey, Myers, and Allen

The End

Free Cash Flows

Agenda

1. Free cash flow (FCF)
2. FCF components
3. Inflation

NPV: What Do You Discount?
NPV0 =

N
X
E (FCFt )
t=0

(1 + r )t

To calculate NPV, we need to forecast a project’s expected after-tax free cash flow (FCF).
FCFs are the cash flows that would be ‘left over’ to distribute to investors after all operating
and investment expenditures have been made, assuming the project is all-equity
financed.
Rules:
• Only cash flows are relevant.
• Estimate cash flows on an incremental basis.
• Include opportunity costs.
• Ignore sunk costs.
• Include all externalities.
• Treat inflation consistently.

Free Cash Flow
Approach: Start with incremental accounting earnings and then adjust to get to free cash
flows.
FCF = EBIT(1 − τc ) + Depreciation − Change in NWC − CAPEX + Salvage
where:
• EBIT: earnings before interest and taxes
• NWC (net working capital): current assets − current liabilities
• CAPEX: capital expenditures
• Salvage: after-tax recovery value of used productive capital
• τc : marginal corporate tax rate
Note: We ignore any interest expense in the FCF calculation.
• Rationale: keep investment and financing decisions separate

Free Cash Flow and Depreciation
Since EBIT = EBITDA − Depreciation,
FCF = (EBITDA − Depreciation)(1−τc ) + Depreciation − Change in NWC − CAPEX + Salvage.
Why subtract and then add back depreciation?
• Because depreciation is a non-cash expense that reduces a firm’s tax bill (a cash
expense).
Simplifying the equation above, we get an equivalent expression for FCF:

FCF = EBITDA(1 − τc ) + Depreciation×τc − Change in NWC − CAPEX + Salvage
The term Depreciation × τc in the equation above is the tax benefit provided by
depreciation, and is called the depreciation tax shield.

Example: Depreciation Tax Shield
XYZ has EBITDA = $100, τc = 30%, Change in NWC = CAPEX = Salvage = 0.
• Suppose Depreciation = 0. What is its FCF?
FCF = 100 × (1 − 30%) = $70
• What if Depreciation = 20?
FCF = (100 − 20) × (1 − 30%) + 20 = 56 + 20 = $76
• With depreciation, FCF is higher by $6. This difference is equal to the tax savings
that result from the ability to shield $20 of pre-tax income from tax by deducting
depreciation.
Depreciation tax shield = 20 × 30% = $6

Free Cash Flow: CAPEX and Salvage Values
CAPEX
Since investments in Plant, Property & Equipment (eg, machinery) generally cannot be
claimed as an expense for accounting purposes, they do not appear on the income
statement directly.
• But investments cost money!
• This expenditure will lower available FCFs, hence we subtract capital
expenditures/investments in the FCF calculation.
Salvage Value
Used equipment can sometimes be sold. If the sale price of the asset exceeds its book
value, then we need to pay tax on the gain. The after-tax proceeds of this sale (the
“salvage value”) is a cash inflow that will increase FCF.
• Salvage value = Sale price − (Gain on sale ×τc )
• Gain on sale = Sale price − Book value
• Book value = Initial investment − Accumulated depreciation

Free Cash Flows: Net Working Capital
Net working capital (NWC)
• NWC = Current assets − Current liabilities
• Main Current assets (CA): Inventory, Accounts receivable, (Cash?)
• Main Current liabilities (CL): Accounts payable
• NWC captures how much liquidity is tied up in the operation
• Accounts receivables (payables) are earnings (expenses) for which you are
yet to receive (pay) cash.
• Purchases of inventory require cash but won’t be recognised as an expense
until the goods are sold.
• A growth in NWC means a net investment in current assets, tying up more cash
and thereby decreasing free cash flow; therefore, we subtract the change in NWC
Change in NWCt = NWCt − NWCt−1 = Change in CAt − Change in CLt

Inflation
Recall the relationship between the nominal interest rate (rnom ), the real
interest rate (ireal ), and the (expected) inflation rate (π):
1 + ireal =

1 + rnom
1+π

Be consistent in how you handle inflation!
• Use nominal interest rates to discount nominal cash flows.
• Use real interest rates to discount real cash flows.

You will get the same results, whether you use nominal or real figures.

Inflation: Example

You invest in a project that will produce real cash flows of −$100 in year 0
and then $35, $50, and $30 in the following three years. If the nominal
discount rate is 15% and the forecasted inflation rate is 10%, what is the
NPV of the project?

ireal =

1 + rnom
1.15
−1=
− 1 ≈ 4.55%
1+π
1.10

Inflation: Example
Nominal figures
Year

Cash flow

PV @ 15%

0

−100

−100

1

35 × 1.10 = 38.5

38.5
1.15

= 33.48

2

50 × 1.102 = 60.5

60.5
1.152

= 45.75

3

30 × 1.103 ≈ 39.9

39.9
1.153

= 26.25

NPV = $5.48

Inflation: Example
Real figures
Year

Cash flow

PV @ 4.55%

0

−100

1

35

35
1.0455

= 33.48

2

50

50
1.04552

= 45.75

3

30

30
1.04553

= 26.25

−100

NPV = $5.48

The End

Modelling 1: NPV Calculation

VAS Project: Calculating FCFs, Part I
Depreciation:
Under straight-line depreciation, the annual depreciation expense is a constant
proportion of the difference between the initial investment and the accounting salvage
value (ie, book value):

Depreciable amount = Initial investment − Book valueT
= (250K + 50K) − 100K
= £200, 000
1
× Depreciable amount
T
1
= × 200K
4
= £50, 000

Annual depreciation =

VAS Project: Calculating FCFs, Part II
Salvage value: Since we have the required data, we can also calculate the tax due on the
market salvage value:

Taxable profit on salvage = 100K − 100K = 0
Tax due = 0 × τc = 0
After-tax market salvage value = 100K − 0 = £100, 000

VAS Project: Calculating FCFs, Part III
0
(1)
(2)
(3)
(4)
(5)
(6)
(7)

Saved rent
Heating
Move-in/out costs
Depreciation
EBIT (1 − 2 − 3 − 4)
Tax at 30%
Profit after tax (5 − 6)

(8)
(9)
(10)

Operating cash flow (7 + 4)
Change in NWC
CF from investment activities

(11)

Free cash flow (8 − 9 + 10)

1

2

3

4

150
40

150
40

150
40

(25)
(7.5)
(17.5)

50
60
18
42

50
60
18
42

50
60
18
42

150
40
25
50
35
10.5
24.5

(17.5)

92

92

92

74.5

92

92

174.5

25

(300)
(317.5)

100
92

First, calculate unlevered Net Profit = EBIT(1 − τc ) = (Revenues − Costs − Depreciation)(1 − τc ). For FCFs, we:
• Add back depreciation (Operating Cash Flow = After-tax profit + Depreciation)
• No NWC needs in this case
• Determine cash-flows from CAPEX and Salvage

VAS Project: NPV

NPV using nominal cash flows and discount rate = 10%:

NPV = −317.5K +

92K
92K
174.5K
92K
+
+
+
= 30.476K
1.10 (1.10)2 (1.10)3 (1.10)4
NPV = +£30,476

The End

NPV Applications

Agenda

1. Profitability index
2. Equivalent annual cash flow (EAC)

Profitability Index
When the total amount of funds available for investment are limited (called
“capital rationing”), the profitability index (PI) provides a tool for selecting
among various project combinations and alternatives.

Profitability index =

NPV
Investment

Decision rule: Choose the combination of projects with the highest
weighted-average PI.

Profitability Index: Example
We only have $300,000 to invest. Which do we select?
Project
A
B
C
D

NPV
230,000
141,250
194,250
162,000

Investment
200,000
125,000
175,000
150,000

PI
1.15
1.13
1.11
1.08

Select projects with the highest weighted-average PI:
• WAPI(BD) = (125/300) × 1.13 + (150/300) × 1.08 + (25/300) × 0 = 1.01
• WAPI(BC) = 1.12 (Choose this combination)
• WAPI(A) = 0.77
Note that any unused cash has a PI = 0.

Equivalent Annual Cash Flows
Sometimes it is useful to transform the present value of an investment into a stream of
equal future cash flows (eg, when choosing between projects with different lengths).
The equivalent annual cash flow (EAC) of a project is the equal cash flow per period
with the same present value as the actual cash flows of the project. When the cash flows
are costs, this quantity is called the equivalent annual cost.

EAC =

PV(cash flows)
annuity factor

where
Annuity factor =

1 − (1 + r )−n
r

!

EAC Example
Given the following costs of operating two machines and a 6% cost of capital,
select the lower cost machine using the equivalent annual cost method.
Machine
A
B

0
15
10

1
5
6

2
5
6

3
5

PV @ 6%
28.37
21.00

EAC
10.61
11.45

• EAC of machine A:

EACA ×


1 − (1.06)−3
= 28.37 → EACA ≈ 10.61
0.06

• EAC of machine B:

1 − (1.06)−2
EACB ×
= 21.00 → EACB ≈ 11.45
0.06


The End