1. CHAPTER 6 Risk and Rates of Return
Stand-alone risk
Portfolio risk
Risk & return: CAPM/SML

2. Risk & Uncertainty
Risk is seen as the phenomenon that arises from circumstances where we are able to identify the possible outcomes and even their likelihood of occurrence without being sure which will actually occur

3. Risk & Uncertainty
The outcome of throwing a true die is an example of risk.
We know that the outcome must be a number from 1 to 6 (inclusive) and we know that each
number has an equal (1 in 6) chance of occurrence, but we are not sure which one will actually occur on any particular throw.

4. Risk & Uncertainty
Uncertainty describes the position where we simply are not able to identify all, or perhaps not even any, of the possible outcomes, and we are still less able to assess their
likelihood of occurrence. Probably most business decisions are characterized by uncertainty to some extent.

5. Risk & Uncertainty
Uncertainty describes the position where we simply are not able to identify all, or perhaps not even any, of the possible outcomes, and we are still less able to assess their
likelihood of occurrence. Probably most business decisions are characterized by uncertainty to some extent.

6. Risk & Uncertainty
Uncertainty represents a particularly difficult area. Perhaps the best that decision makers can do is to try to identify as many as possible of the feasible outcomes of their
decision and attempt to assess each outcome’s likelihood of occurrence.

7. Concept of Return
The concept of return provides investors with a convenient way of expressing the financial performance
of an investment.

8. Example of Return
suppose you buy 10 shares of a stock for $1,000. The stock pays no dividends, but at the end of one year, you sell the stock for $1,100. What is the return on your $1,000 investment?

9. Expressing an Investment Return
One way of expressing an investment return is in dollar terms. The dollar return is simply the total dollars received from the investment less the amount invested:
Dollar return Amount received Amount invested
=$1,100- $1,000
$100.

10. Limitations of Dollar returns
Although expressing returns in dollars is easy, two problems arise: (1) To
make a meaningful judgment about the return, you need to know the scale
(size) of the investment; a $100 return on a $100 investment is a good return
(assumingthe investment is held for one year), but a $100 return on a $10,000
investment would be a poor return

11. Limitations of Dollar returns
(2) You also need to know the timing of the return; a $100 return on a $100 investment is a very good return if it occurs after one year, but the same dollar return after 20 years would not be very good.

12. Solution
The solution to the scale and timing problems is to express investment results as rates of return, or percentage returns. For example, the rate of return on the
1-year stock investment, when $1,100 is received after one year, is 10 percent:

13. Solution

14. Explanation of Solution
The rate of return calculation “standardizes” the return by considering the return per unit of investment. In this example, the return of 0.10, or 10 percent, indicates that each dollar invested will earn 0.10($1.00) $0.10.

15. Explanation of Solution
The rate of return calculation “standardizes” the return by considering the return per unit of investment. In this example, the return of 0.10, or 10 percent, indicates that each dollar invested will earn 0.10($1.00) $0.10.

16. Explanation of Solution
If the return had been negative, this would indicate that the original investment was not even recovered. For example, selling the stock for only $900 results in a 10 percent rate of return, which means that each dollar invested lost 10 cents.

17. Explanation of Solution
Note also that a $10 return on a $100 investment produces a 10 percent rate of
return, while a $10 return on a $1,000 investment results in a rate of return of only 1 percent.
Thus, the percentage return takes account of the size of the investment

20. What is investment risk?
Investment risk pertains to the probability of actually earning a low or negative return.
The greater the chance of low or negative returns, the riskier the investment.

21. Type of risk?
Stand-alone risk is the risk an investor would face if he or she held only this one asset.
Obviously, most assets are held in portfolios, but it is necessary to understand stand-alone risk in order to understand risk in a portfolio context.

22. PROBABILITY DISTRIBUTIONS
An event’s probability is defined as the chance that the event will occur.
For example, a weather forecaster might state, “There is a 40 percent chance of rain
today and a 60 percent chance that it will not rain.” If all possible events, or outcomes, are listed, and if a probability is assigned to each event, the listing is called a probability distribution. For our weather forecast, we could set up the ollowing probability distribution:

23. PROBABILITY DISTRIBUTIONS

25. PROBABILITY DISTRIBUTIONS
The possible outcomes are listed in Column 1, while the probabilities of these outcomes, expressed both as decimals and as percentages, are given in Column 2.
Notice that the probabilities must sum to 1.0, or 100 percent.
Probabilities can also be assigned to the possible outcomes (or returns) from an investment.

26. PROBABILITY DISTRIBUTIONS
The possible outcomes are listed in Column 1, while the probabilities of these outcomes, expressed both as decimals and as percentages, are given in Column 2.
Notice that the probabilities must sum to 1.0, or 100 percent.
Probabilities can also be assigned to the possible outcomes (or returns) from an investment.

27. EXPECTED RATE OF RETURN
If we multiply each possible outcome by its probability of occurrence and then sum these products, as in Table 6-2, we have a weighted average of outcomes.
The weights are the probabilities, and the weighted average is the expected rate of return, kˆ , called “k-hat.”
The expected rates of return for both Martin
Products and U.S. Water are shown in Table 6-2 to be 15 percent. This type of table is known as a payoff matrix.

28. PROBABILITY DISTRIBUTIONS

29. EXPECTED RATE OF RETURN
The expected rate of return calculation can also be expressed as an equation that does the same thing as the payoff matrix table.

30. Calculate the expected rate of return on each alternative:^
k = expected rate of return. ^

31. What’s the standard deviation of returns for each alternative?
 = =
 =

32. Standard deviation (si) measures total, or stand-alone, risk.
The larger the si , the lower the probability that actual returns will be close to the expected return.
The symbol for which is pronounced“sigma.”
The smaller the standard deviation, the tighter the probability distribution, and, accordingly, the lower the riskiness of the stock.

33. Martin expected return according to previous calculation is 15%

34. Standard Deviation
Thus, the standard deviation is essentially a weighted average of the deviations from the expected value, and it provides an idea of how far above or below the expected value the actual value is likely to be.

35. Standard Deviation
Martin’s standard deviation is seen in Table 6-3 to be %. Using these same procedures, we find U.S. Water’s standard deviation to be 3.87 percent. Martin Products has the larger standard deviation, which indicates a greater variation of returns and thus a greater chance that the expected return will not be realized.Therefore,Martin Products is a riskier investment than U.S. Water when held alone.

36. If a probability distribution is normal, the actual return will be within 1 standard deviation of the expected return percent of the time.
Figure 6-3
illustrates this point, and it also shows the situation for 2 and 3. For Martin Products, kˆ 15% and %, whereas kˆ 15% and % for U.S. Water. Thus, if the two distributions were normal, there would be a percent probability that Martin’s actual return would be in the range of 15 +/ percent, or from to percent. For U.S. Water, the
68.26 percent range is 15 +/ percent, or from to percent.
With such a small , there is only a small probability that U.S. Water’s return would be significantly less than expected, so the stock is not very risky

37. Probability Distribution

38. Coefficient of Variation (CV)
Standardized measure of dispersion
about the expected value:
Std dev s
CV = = ^
Mean k
Shows risk per unit of return.

39. Coefficient of Variation (CV)
Standardized measure of dispersion
about the expected value:
Std dev s
CV = = ^
Mean k
Shows risk per unit of return.

40. sA = sB , but A is riskier because larger
Prob. A B
Rate of Return (%)
sA = sB , but A is riskier because larger
probability of losses. s
= CVA > CVB. ^ k

42. Portfolio Risk and Return
Assume a two-stock portfolio with $50,000 in HT and $50,000 in Collections. ^
Calculate kp and sp.

43. kp is a weighted average:^
Portfolio Return, kp ^
kp is a weighted average: ^ n ^
kp = S wiki.
i=1 ^
kp = 0.5(17.4%) + 0.5(1.7%) = 9.6%. ^ ^ ^
kp is between kHT and kCOLL.

44. Alternative Method Estimated Return Economy Prob. HT Coll. Port.
Recession % 28.0% 3.0%
Below avg
Average
Above avg
Boom ^
kp = (3.0%) (6.4%) (10.0%)0.40
+ (12.5%) (15.0%)0.10 = 9.6%.

45. 1 / 2 é ù ê
(3.0 – 9.6)20.10
+ (6.4 – 9.6)20.20
+ (10.0 – 9.6)20.40
+ (12.5 – 9.6)20.20
+ (15.0 – 9.6)20.10 ú ê ú ê ú ê ú
p = = 3.3%. ê ú ê ú ê ú ê ú ê ú ë û
3.3%
CVp = = 0.34.
9.6%

46. sp = 3.3% is much lower than that of either stock (20% and 13.4%).
sp = 3.3% is lower than average of HT and Coll = 16.7%.
\ Portfolio provides average k but lower risk.
Reason: negative correlation. ^

47. General statements about risk
Most stocks are positively correlated. rk,m » 0.65.
s » 35% for an average stock.
Combining stocks generally lowers risk.

48. Returns Distributions for Two Perfectly Negatively Correlated Stocks (r = -1.0) and for Portfolio WM
Stock W
Stock M
Portfolio WM . . . . 25 25 25 . . . . . . . 15 15 15 . . . .
-10
-10
-10

49. Returns Distributions for Two Perfectly Positively Correlated Stocks (r = +1.0) and for Portfolio MM’
Stock M
Stock M’
Portfolio MM’ 15 25
-10 15 25
-10 25 15
-10

50. What would happen to the riskiness of an average 1-stock portfolio as more randomly selected stocks were added?
sp would decrease because the added stocks would not be perfectly correlated but kp would remain relatively constant. ^

51. Prob.
Large 2 1 15
Rate of Return (%)
Even with large N, sp » 20%

52. Company-Specific Risk35
Stand-Alone Risk, sp 20
Market Risk
,000+
# Stocks in Portfolio

53. As more stocks are added, each new stock has a smaller risk-reducing impact.
sp falls very slowly after about 10 stocks are included, and after 40 stocks, there is little, if any, effect. The lower limit for sp is about 20% = sM .

54. Stand-alone Market Firm-specific=
risk risk risk
Market risk is that part of a security’s stand-alone risk that cannot be eliminated by diversification, and it is measured by beta.
Firm-specific risk is that part of a security’s stand-alone risk that can be eliminated by proper diversification.

55. By forming portfolios, we can eliminate about half the riskiness of individual stocks (35% vs. 20%).

56. If you chose to hold a one-stock portfolio and thus are exposed to more risk than diversified investors, would you be compensated for all
the risk you bear?

57. NO!
Stand-alone risk as measured by a stock’s s or CV is not important to a well-diversified investor.
Rational, risk-averse investors are concerned with sp , which is based on market risk.

58. There can only be one price, hence market return, for a given security
There can only be one price, hence market return, for a given security. Therefore, no compensation can be earned for the additional risk of a one-stock portfolio.

59. Beta measures a stock’s market risk
Beta measures a stock’s market risk. It shows a stock’s volatility relative to the market.
Beta shows how risky a stock is if the stock is held in a well-diversified portfolio.

60. How are betas calculated?
Run a regression of past returns on Stock i versus returns on the market. Returns = D/P + g.
The slope of the regression line is defined as the beta coefficient.

61. . . . Illustration of Beta Calculation: _ ki _ kM Regression line:20 15 10 5 . ^ ^ .
Year kM ki
1 15% 18% _ kM -5
-10 .

62. If beta = 1.0, average stock.
If beta > 1.0, stock riskier than average.
If beta < 1.0, stock less risky than average.
Most stocks have betas in the range of 0.5 to 1.5.

63. List of Beta Coefficients
Stock Beta
Merrill Lynch
America Online
General Electric
Microsoft Corp
Coca-Cola
IBM
Procter & Gamble
Energen Corp
Heinz
Empire District Electric

64. Can a beta be negative?
Yes, if ri, m is negative. Then in a “beta graph” the regression line will slope downward. Though, a negative beta is highly unlikely.

65. _ ki HT T-Bills _ kM Coll. b = 1.30 b = 0 -20 0 20 40 b = -0.87 40 20 kM
-20
Coll.
b = -0.87

66. Expected Risk
Security Return (Beta)
HT 17.4% 1.30
Market
USR
T-bills
Coll
Riskier securities have higher returns, so the rank order is OK.

67. Use the SML to calculate the required returns.
SML: ki = kRF + (kM – kRF)bi .
Assume kRF = 8%.
Note that kM = kM is 15%. (Equil.)
RPM = kM – kRF = 15% – 8% = 7%. ^

68. Required Rates of Return
kHT = 8.0% + (15.0% – 8.0%)(1.30)
= 8.0% + (7%)(1.30)
= 8.0% + 9.1% = %.
kM = 8.0% + (7%)(1.00) = %.
kUSR = 8.0% + (7%)(0.89) = %.
kT-bill = 8.0% + (7%)(0.00) = %.
kColl = 8.0% + (7%)(-0.87) = %.

69. Expected vs. Required Returns^ k k
HT 17.4% 17.1% Undervalued:
k > k
Market Fairly valued
USR Overvalued:
k < k
T-bills Fairly valued
Coll Overvalued: ^ ^ ^

70. . . . . . SML: ki = 8% + (15% – 8%) bi . ki (%) SML Risk, bi HT
kM = 15
kRF = 8 .
USR
T-bills .
Coll.
Risk, bi

71. Calculate beta for a portfolio with 50% HT and 50% Collections
bp= Weighted average
= 0.5(bHT) + 0.5(bColl)
= 0.5(1.30) + 0.5(-0.87) =

72. The required return on the HT/Coll. portfolio is:
kp = Weighted average k
= 0.5(17.1%) + 0.5(1.9%) = 9.5%.
Or use SML:
kp = kRF + (kM – kRF) bp
= 8.0% + (15.0% – 8.0%)(0.215)
= 8.0% + 7%(0.215) = 9.5%.

73. If investors raise inflation expectations by 3%, what would happen to the SML?

74. Required Rate of Return ki (%) SML2 SML1 Original situation
D I = 3%
New SML
SML2
SML1 18 15 11 8
Original situation
Risk, bi

75. If inflation did not change but risk aversion increased enough to cause the market risk premium to increase by 3 percentage points, what would happen to the SML?

76. Required Rate of Return (%)
After increase
in risk aversion
Required Rate of Return (%)
SML2
kM = 18%
kM = 15% 2 1 18 15
SML1
D RPM = 3% 8
Original situation
Risk, bi
1.0

77. Has the CAPM been verified through empirical tests?
Not completely. Those statistical tests have problems that make verification almost impossible.

78. Investors seem to be concerned with both market risk and total risk
Investors seem to be concerned with both market risk and total risk. Therefore, the SML may not produce a correct estimate of ki:
ki = kRF + (kM – kRF)bi + ?

79. Also, CAPM/SML concepts are based on expectations, yet betas are calculated using historical data. A company’s historical data may not reflect investors’ expectations about future riskiness.