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Risk and Return Analysis in Investment: Understanding, Measuring, and Analyzing

Learn the principles of risk and return in investments, measuring asset and portfolio risk, the CAPM model, and risk preferences. Understand calculating returns, defining risk, and risk assessment for single assets. Explore probability distributions, expected returns, and standard deviation for risk measurement.

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Risk and Return Analysis in Investment: Understanding, Measuring, and Analyzing

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  1. Chapter 5 Risk and Return

  2. After studying Chapter 5, you should be able to: • Understand the meaning of risk, return and risk preferences. • Measure the risk and return of a single asset. • Measure the risk and return of a portfolio of assets. • Explain beta and the CAPM model. • Analyse shifts in the securities market line.

  3. Defining Return Return is defined as “the total gain or loss experienced on an investment over a given period of time”. Income received on an investment plus any change in market price, usually expressed as a percent of the beginning market price of the investment. (see eqn 5.1 p.98) • It is measured as follows: Dt+ (Pt – Pt - 1) R = Pt - 1

  4. Defining Return • Where: • R = Actual, expected or required rate of return during the period t • Dt = Cash flow received from the investment in the time period [t – 1 to t] • Pt = Price of the asset at time t • Pt-1 = Price of the asset at time t – 1

  5. Return Example The stock price for Stock A was $10 per share 1 year ago. The stock is currently trading at $9.50 per share and shareholders just received a $1 dividend. What return was earned over the past year? $1.00 + ($9.50 – $10.00) = 5% R = $10.00

  6. Another Example

  7. Defining Risk Risk is defined as “the chance of financial loss”. It is the variability (difference) of returns from those that are expected. What rate of return do you expect on your investment (savings) this year? What rate will you actually earn? Does it matter if it is a bank deposit or a share of stock?

  8. The Risk-Return Trade-off • Investments must be analysed in terms of both their return potential and their riskiness or variability. • Historically, its been shown that higher returns are accompanied by higher risks.

  9. Risk Preferences • Three Preferences: • Risk Averse: Require a higher rate of return to compensate for taking higher risk. • Risk Seeking: Will accept a lower return for a greater risk. • Risk Indifferent: Required return does not change in response to a change in risk.

  10. Risk Preferences

  11. Risk Assessment Of A Single Asset – Probability Distribution • Provides a more quantitative, yet behavioural, insight into an asset’s risk. • Probability is the chance of a particular outcome occurring. • Can be graphed as a model relating probabilities and their associated outcomes. • The expected value of a return R [the most likely return on an asset] can be calculated by:

  12. Determining Expected Return (Discrete Dist.) n R = S ( Ri )( Pi ) R is the expected return for the asset, Ri is the return for the ith possibility, Pi is the probability of that return occurring, n is the total number of possibilities. I = 1

  13. Probability Distribution • A probability distribution is a model that relates probabilities to the associated outcomes. • The simplest type of probability distribution is the bar chart, which shows only a limited number of outcome-probability coordinates.

  14. How to Determine the Expected Return Stock BW RiPi (Ri)(Pi) -0.15 0.10 –0.015 -0.03 0.20 –0.006 0.09 0.40 0.036 0.21 0.20 0.042 0.33 0.10 0.033 Sum1.000.090 The expected return, R, for Stock BW is .09 or 9%

  15. Probability Distribution • The bar charts for Shuia Na Ltd’s assets A and B are shown in Slide 15. • Although both assets have the same most likely return, the range of return is much more dispersed for asset B than for asset A—16% versus 4%.

  16. Probability Distribution

  17. Probability Distribution • If we knew all the possible outcomes and associated probabilities, a continuous probability distribution could be developed. This type of distribution can be thought of as a bar chart for a very large number of outcomes. • Slide 17 shows continuous probability distributions for assets A and B. Note that although assets A and B have the same most likely return (15%), the distribution of returns for asset B has much greater dispersion than the distribution for asset A. • Clearly, asset B is more risky than asset A.

  18. Probability Distribution

  19. Discrete versus Continuous Distributions DiscreteContinuous

  20. Risk Measurement – Standard Deviation • A normal probability distribution will always resemble a bell shaped curve.

  21. Risk Measurement – Standard Deviation • Measures the dispersion around the expected value. • The higher the standard deviation the higher the risk.

  22. Determining Standard Deviation (Risk Measure) n s = S ( Ri – R )2( Pi ) Standard Deviation, s, is a statistical measure of the variability of a distribution around its mean. It is the square root of variance. Note, this is for a discrete distribution. i = 1

  23. How to Determine the Expected Return and Standard Deviation Stock BW RiPi (Ri)(Pi) (Ri- R )2(Pi) –0.15 0.10 –0.015 0.00576 –0.03 0.20 –0.006 0.00288 0.09 0.40 0.036 0.00000 0.21 0.20 0.042 0.00288 0.33 0.10 0.033 0.00576 Sum1.000.090 0.01728

  24. Determining Standard Deviation (Risk Measure) n s = S ( Ri – R )2( Pi ) s = .01728 s = 0.1315 or 13.15% i=1

  25. Another example • Shuia Na Ltd, a tennis-equipment manufacturer, is attempting to choose the better of two alternative investments, A and B. Each requires an initial outlay of $10,000 and each has a most likely annual rate of return of 15%. To evaluate the riskiness of these assets, management has made pessimistic (worse case) and optimistic (best case) estimates of the returns associated with each. • The expected values for these assets are presented in the Table on slide 26. Column 1 gives the Pri’s and column 2 gives the ri’s, n equals 3 in each case. The expected value for each asset’s return is 15%. • Slide 27 shows the standard deviations for these assets

  26. Another example – cont. • Before looking at the standard deviations, can you identify which asset is most risky?

  27. Another example – cont.

  28. Which Asset Is Riskier?

  29. Risk Measurement – Coefficient Of Variation • A measure of relative dispersion, useful in comparing the risk of assets that have different expected returns. • The higher the coefficient of variation, the greater the risk. • Allows comparison of assets that have different expected returns.

  30. Coefficient of Variation The ratio of the standard deviation of a distribution to the mean (average) of that distribution. It is a measure of RELATIVE risk. CV = s/R CV of BW = 0.1315 / 0.09 = 1.46

  31. Risk Attitudes Certainty Equivalent(CE) is the amount of cash someone would require with certainty at a point in time to make that person indifferent between that certain amount and an amount expected to be received with risk at the same point in time.

  32. Risk Attitudes Certainty equivalent > Expected value Risk Preference Certainty equivalent = Expected value Risk Indifference Certainty equivalent < Expected value Risk Aversion Most individuals are Risk Averse.

  33. Risk Attitude Example You have the choice between (1) a guaranteed dollar reward or (2) a coin-flip gamble of $100,000 (50% chance) or $0 (50% chance). The expected value of the gamble is $50,000. • Mary requires a guaranteed $25,000, or more, to call off the gamble. • Raleigh is just as happy to take $50,000 or take the risky gamble. • Shannon requires at least $52,000 to call off the gamble.

  34. Risk Attitude Example What are the Risk Attitude tendencies of each? Mary shows “risk aversion” because her “certainty equivalent” < the expected value of the gamble. Raleigh exhibits “risk indifference”because her “certainty equivalent” equals the expected value of the gamble. Shannon reveals a “risk preference” because her “certainty equivalent” > the expected value of the gamble.

  35. Portfolios • A portfolio is a collection of assets. • An efficient portfolio is: • One that maximises the return for a given level of risk. • OR • One that minimises risk for a given level of return.

  36. Portfolio Return • Is calculated as a weighted average of returns on the individual assets from which it is formed. • Is calculated by (Eqn 5.6):

  37. Determining Portfolio Expected Return m RP = S ( Wj )( Rj ) RPis the expected return for the portfolio, Wj is the weight (investment proportion) for the jth asset in the portfolio, Rj is the expected return of the jth asset, m is the total number of assets in the portfolio. J = 1

  38. Correlation • A statistical measure of the relationship, if any, between a series of numbers representing data of any kind. • Three types: • Positive Correlation: Two series move in the same direction. • Uncorrelated: No relationship between the two series. • Negative Correlation: Two series move in opposite directions.

  39. Correlation Coefficient A standardised statistical measure of the linear relationship between two variables. Its range is from –1.0 (perfect negative correlation), through 0 (no correlation), to +1.0 (perfect positive correlation).

  40. Correlation • The degree of correlation is measured by the correlation coefficient.

  41. Diversification • Combining assets with low or negative correlation can reduce the overall risk of the portfolio. • Combining uncorrelated risks can reduce overall portfolio risk. • Combining two perfectly positively correlated assets cannot reduce the risk below the risk of the least risky asset. • Combining two assets with less than perfectly positive correlations can reduce the total risk to a level below that of either asset.

  42. Diversification

  43. Correlation, Diversification, Risk & Return • The lower the correlation between asset returns, the greater the potential diversification of risk.

  44. Portfolio Risk and Expected Return Example You are creating a portfolio of Stock D and Stock BW (from earlier). You are investing $2,000 in Stock BW and $3,000 in Stock D. Remember that Stock BW’s the expected return is 9% and its standard deviation is13.15%. Stock D’s expected returnis 8% and its standard deviation is 10.65%. The correlation coefficient between BW and D is 0.75. What is the expected return and standard deviation of the portfolio?

  45. Determining Portfolio Expected Return WBW = $2,000/$5,000 = 0.4 WD= $3,000/$5,000 = 0.6 RP= (WBW)(RBW) + (WD)(RD) RP = (0.4)(9%) + (0.6)(8%) RP = (3.6%) + (4.8%) = 8.4%

  46. Determining Portfolio Standard Deviation sP = 0.0028 + (2)(0.0025) + 0.0041 sP = SQRT(0.0119) sP = 0.1091 or 10.91% You will not be asked to do this calculation.

  47. Determining Portfolio Standard Deviation The WRONG way to calculate is a weighted average like: sP = 0.4(13.15%)+0.6(10.65%) sP = 5.26 + 6.39 = 11.65% 10.91% = 11.65% This is INCORRECT.

  48. Summary of the Portfolio Return and Risk Calculation Stock CStock DPortfolio Return 9.00% 8.00% 8.4% Stand. Dev. 13.15% 10.65% 10.91% CV 1.46 1.33 1.30 The portfolio has the LOWEST coefficient of variation due to diversification.

  49. Diversification and the Correlation Coefficient Combining securities that are not perfectly, positively correlated reduces risk. Combination E and F SECURITY E SECURITY F INVESTMENT RETURN TIME TIME TIME

  50. Systematic Risk is the variability of return on stocks or portfolios associated with changes in return on the market as a whole. It cannot be avoided Unsystematic Risk is the variability of return on stocks or portfolios not explained by general market movements. It is avoidable through diversification. Total Risk = SystematicRisk + UnsystematicRisk Total Risk = Systematic Risk + Unsystematic Risk

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