RISK AND RETURN BASICS - PowerPoint PPT Presentation

1 / 31
About This Presentation
Title:

RISK AND RETURN BASICS

Description:

RISK AND RETURN BASICS – PowerPoint PPT presentation

Number of Views:45
Avg rating:3.0/5.0
Slides: 32
Provided by: paulb211
Category:
Tags: and | basics | return | risk | basics | market | stock

less

Transcript and Presenter's Notes

Title: RISK AND RETURN BASICS


1
Chapter 2
  • RISK AND RETURN BASICS

2
Chapter 2 Questions
  • What are the sources of investment returns?
  • How can returns be measured?
  • How can we compute returns on investments outside
    of their home country?

3
Chapter 2 Questions
  • What is risk and how is it measured?
  • How is expected return and risk estimated via
    scenario analysis?
  • What are the components of an investments
    required return to investors and why might they
    change over time?

4
Sources of Investment Returns
  • Investments provide two basic types of return
  • Income returns
  • The owner of an investment has the right to any
    cash flows paid by the investment.
  • Changes in price or value
  • The owner of an investment receives the benefit
    of increases in value and bears the risk for any
    decreases in value.

5
Income Returns
  • Cash payments, usually received regularly over
    the life of the investment.
  • Examples Coupon interest payments from bonds,
    Common and preferred stock dividend payments.

6
Returns From Changes in Value
  • Investors also experience capital gains or losses
    as the value of their investment changes over
    time.
  • For example, a stock may pay a 1 dividend while
    its value falls from 30 to 25 over the same
    time period.

7
Investment Strategy
  • Generally, the income returns from an investment
    are in your pocket cash flows.
  • Over time, your portfolio will grow much faster
    if you reinvest these cash flows and put the full
    power of compound interest in your favor.
  • Dividend reinvestment plans (DRIPs) provide a
    tool for this to happen automatically similarly,
    Mutual Funds allow for automatic reinvestment of
    income.
  • See Exhibit 2.5 for an illustration of the
    benefit of reinvesting income.

8
Measuring Returns
  • Dollar Returns
  • How much money was made on an investment over
    some period of time?
  • Total Dollar Return Income Price Change
  • Holding Period Return
  • By dividing the Total Dollar Return by the
    Purchase Price (or Beginning Price), we can
    better gauge a return by incorporating the size
    of the investment made in order to get the dollar
    return.

9
Annualized Returns
  • If we have return or income/price change
    information over a time period in excess of one
    year, we usually want to annualize the rate of
    return in order to facilitate comparisons with
    other investment returns.
  • Another useful measure
  • Return Relative Income Ending Value
  • Purchase Price

10
Annualized Returns
  • Annualized HPR (1 HPR)1/n 1
  • Annualized HPR (Return Relative)1/n 1
  • With returns computed on an annualized basis,
    they are now comparable with all other annualized
    returns.

11
Returns on Overseas Investments
  • A holding period return on a foreign investment
    generally needs to be translated back into the
    home country return.
  • If the exchange rate has changed over the life of
    the investment, the home country return (HCR) can
    be very different than the foreign return (FR).

12
Returns on Foreign Investments
  • HCR Relative FR Relative (Current Exchange
    Rate/Initial Exchange Rate)
  • HCR(1 FR)Current Exchange Rate 1
  • Initial Exchange Rate

13
Measuring Historic Returns
  • Starting with annualized Holding Period Returns,
    we often want to calculate some measure of the
    average return over time on an investment.
  • Two commonly used measures of average
  • Arithmetic Mean
  • Geometric Mean

14
Arithmetic Mean Return
  • The arithmetic mean is the simple average of a
    series of returns.
  • Calculated by summing all of the returns in the
    series and dividing by the number of values.
  • RA (SHPR)/n
  • Oddly enough, earning the arithmetic mean return
    for n years is not generally equivalent to the
    actual amount of money earned by the investment
    over all n time periods.

15
Arithmetic Mean Example
  • Year Holding Period Return
  • 1 10
  • 2 30
  • 3 -20
  • 4 0
  • 5 20
  • RA (SHPR)/n 40/5 8

16
Geometric Mean Return
  • The geometric mean is the one return that, if
    earned in each of the n years of an investments
    life, gives the same total dollar result as the
    actual investment.
  • It is calculated as the nth root of the product
    of all of the n return relatives of the
    investment.
  • RG P(Return Relatives)1/n 1

17
Geometric Mean Example
  • Year Holding Period Return Return Relative
  • 1 10 1.10
  • 2 30 1.30
  • 3 -20 0.80
  • 4 0 1.00
  • 5 20 1.20
  • RG (1.10)(1.30)(.80)(1.00)(1.20)1/5 1
  • RG .0654 or 6.54

18
Arithmetic vs. Geometric
  • To ponder which is the superior measure, consider
    the same example with a 1000 initial investment.
    How much would be accumulated?
  • Year Holding Period Return Investment Value
  • 1 10 1,100
  • 2 30 1,430
  • 3 -20 1,144
  • 4 0 1,144
  • 5 20 1,373

19
Arithmetic vs. Geometric
  • How much would be accumulated if you earned the
    arithmetic mean over the same time period?
  • Value 1,000 (1.08)5 1,469
  • How much would be accumulated if you earned the
    geometric mean over the same time period?
  • Value 1,000 (1.0654)5 1,373
  • Notice that only the geometric mean gives the
    same return as the underlying series of returns.

20
Scenario Analysis
  • While historic returns, or past realized returns,
    are important, investment decisions are
    inherently forward-looking.
  • We often employ scenario or what if? analysis
    in order to make better decisions, given the
    uncertain future.
  • Scenario analysis involves looking at different
    outcomes for returns along with their associated
    probabilities of occurrence.

21
Expected Rates of Return
  • Expected rates of return are calculated by
    determining the possible returns (Ri) for some
    investment in the future, and weighting each
    possible return by its own probability (Pi).
  • E(R) S Pi Ri

22
Expected Return Example
  • Economic Conditions Probability Return
  • Strong .20 40
  • Average .50 12
  • Weak .30 -20
  • E(R) .20(40) .50 (12) .30 (-20)
  • E(R) 8

23
What is risk?
  • Risk is the uncertainty associated with the
    return on an investment.
  • Risk can impact all components of return through
  • Fluctuations in income returns
  • Fluctuations in price changes of the investment
  • Fluctuations in reinvestment rates of return.

24
Sources of Risk
  • Systematic Risk Factors
  • Affect many investment returns simultaneously
    their impact is pervasive.
  • Examples changes in interest rates and the state
    of the macro-economy.
  • Asset-specific Risk Factors
  • Affect only one or a small number of investment
    returns come from the characteristics of the
    specific investment.
  • Examples poor management, competitive pressures.

25
How can we measure risk?
  • Since risk is related to variability and
    uncertainty, we can use measures of variability
    to assess risk.
  • The variance and its positive square root, the
    standard deviation, are such measures.
  • Measure total risk of an investment, the
    combined effects of systematic and asset-specific
    risk factors.
  • Variance of Historic Returns
  • s2 S(Rt-RA)2/n-1

26
Standard Deviation of Historic Returns
  • Year Holding Period Return
  • 1 10 RA 8
  • 2 30 s2 370
  • 3 -20 s 19.2
  • 4 0
  • 5 20
  • s2 (10-8)2(30-8)2(-20-8)2(0-8)2(20-8)2/4
  • 448478464144/4
  • 1480/4

27
Coefficient of Variation
  • The coefficient of variation is the ratio of the
    standard deviation divided by the return on the
    investment it is a measure of risk per unit of
    return.
  • CV s/RA
  • The higher the coefficient of variation, the
    riskier the investment.
  • From the previous example, the coefficient of
    variation would be
  • CV 19.2/8 2.40

28
Measuring Risk Through Scenario Analysis
  • If we are considering various scenarios of return
    in the future, we can still calculate the
    variance and standard deviation of returns, now
    just from a probability distribution.
  • s2 SPi(Ri-E(R))2

29
Standard Deviation of Expected Returns
  • Economic Conditions Probability Return
  • Strong .20 40
  • Average .50 12
  • Weak .30 -20
  • E(R) 8
  • s2 .20 (40-8)2 .50 (12-8)2 .30 (-20-8)2
  • s2 448
  • s 21.2 Note CV 21.2/8 2.65

30
Components of Return
  • Recall from Chapter 1 that the required rate of
    return on an investment is the sum of the
    risk-free rate (RFR) of return available in the
    market and a risk premium (RP) to compensate the
    investor for risk.
  • Required Return RFR RP
  • The Capital Market Line (CML) is a visual
    representation of how risk is rewarded in the
    market for investments.

31
Components of Return Over Time
  • What changes the required return on an investment
    over time?
  • Anything that changes the risk-free rate or the
    investments risk premium.
  • Changes in the real risk-free rate of return and
    the expected rate of inflation (both impacting
    the nominal risk-free rate, factors that shift
    the CML).
  • Changes in the investments specific risk (a
    movement along the CML) and the premium required
    in the marketplace for bearing risk (changing the
    slope of the CML).
Write a Comment
User Comments (0)
About PowerShow.com