LECTURE 2 : UTILITY AND RISK AVERSION

1. LECTURE 2 :UTILITY AND RISK AVERSION (Asset Pricing and Portfolio Theory)

2. Contents • Introduction to utility theory • Relative and absolute risk aversion • Different forms of utility functions • Empirical evidence • How useful are the general findings ? • Equity premium puzzle • Risk free rate puzzle

3. Introduction • Many different investment opportunities with different risk – return characteristics • General assumption : ‘Like returns, dislike risk’ • Preferences of investors (like more to less)

4. Risk Premium and Risk Aversion • Risk free rate of return : rate of return which can be earned with certainty (i.e s = 0). 3 months T-bill • Risk premium : expected return in excess of the risk free rate (i.e. ERp – rf) • Risk aversion : • measures the reluctance by investors to accept (more) risk • ‘High number’ : risk averse • ‘Low number’ : less risk averse • Example : ERp - rf = 0.005 A s2p A = (ERp - rf) / (0.005 s2p)

5. Indifference Curves (Investor’s Preferences) Indifference curve Asset Q ERp Asset P sp s

6. Risk and Return (US Assets : 1926 – 1998) (% p.a.) Small Company Stocks Large Company Stocks ER Long Term T-bonds Medium Term T-bonds Treasury Bills Standard deviation

7. Expected Utility • Suppose we have a random variable, end of period wealth with ‘n’ possible outcomes Wi with probabilities pi • Utility from any wealth outcome is denoted U(Wi) E[U(W)] = SpiU(Wi)

8. Example : Alternative Investments

9. Example : Alternative Investments (Cont.) • Assume following utility function : U(W) = 4W – (1/10) W2 • If outcome is 20, U(W) = 80 – (1/10) 400 = 40 • … • Expected Utility • Investment A : E(UA) = … = 36.3 • Investment B : E(UB) = … = 26.98 • Investment C : E(UC) = 39.6(1/4) + 38.4(1/4) + 33.6(1/4) + 25.6(1/4) = 34.3

10. Utility Function : U(W) = 4W – (1/10)W2

11. Example : Alternative Investments (Cont.) • Ranking of investments remains unchanged if • a constant is added to the utility function • the utility function is scaled by a constant Example : a + bU(W) gives the same ranking as U(W)

12. Fair Lottery • A fair lottery is defined as one that has expected value of zero. • Risk aversion applies that an individual would not accept a ‘fair lottery’. • Concave utility function over wealth • Example : • tossing a coin with $1 for WIN (heads) and -$1 for LOSS (tails). x = k1 with probability p x = k2 with probability 1-p E(x) = pk1 + (1-p)k2 = 0 k1/k2 = -(1-p)/p or p = -k2/(k1-k2) • Tossing a coin : p = ½ and k1 = -k2 = $ 1.-

13. Utility : The Basics

14. Utility Functions • More is preferred to less : U’(W) = ∂U(W)/∂W > 0 • Example : • Tossing a (fair) coin (i.e. p = 0.5 for head) • gamble of receiving £ 16 for a ‘head’ and £ 4 for ‘tails’ • EW = 0.5 (£ 16) + 0.5 (£ 4) = £ 10 • If costs of ‘gamble’ = £ 10.-  EW – c = 0 • How much is an individual willing to pay for playing the game ?

15. Utility Functions (Cont.) • Assume the following utility function U(W) = W1/2 • Expected return from gamble E[U(W)] = 0.5 U(WH) + 0.5 U(WT) = 0.5 (16)1/2 + 0.5(4)1/2 = 3

16. Monetary Risk Premium Utility U(16) = 4 U(W)= W1/2 U(EW) = 101/2 =3.162 p E[U(W)] = 3 =0.5(4)+0.5(2) A U(4) = 2 0 Wealth EW=10 4 16 (W–p) = 9

17. Degree of Risk Aversion • An individual’s degree of risk aversion may depend on • Initial wealth • Example : Bill Gates or You ! • Size of the bet • Risk neutral for small bets : i.e. Cost £ 10.- • Gamble : Win £ 1m or £0. Would you pay £ 499,999 (being risk averse) ?

18. Absolute and Relative Risk Aversion

19. Utility Theory • Assumptions • Investor has wealth W and security with outcome represented by the random variable Z • Let Z be a fair game E(Z) = 0 and E[Z–E(Z)]2 = sz2 • Investor is indifferent between choice A and B Choice A Choice B W + Z Wc E[(U(W + Z)] = EU(Wc) = U(Wc)

20. Utility Theory (Cont.) • Define p = W – Wc is the max. investor is willing to pay to avoid gamble. Measurement of investor’s absolute risk aversion. (1.) Expanding U(W + Z) in a Taylor series expansion around W U(W+Z)  U(W) + U’(W)[(W+Z)-W] + (½) U’’(W)[(W+Z)-W]2 + … E[U(W+Z)] = E[U(W)] + U’(W)E(Z) + (½) U’’(W)E(Z-0)2 E[U(W+Z)] = U(W) + (½) U’’(W) sz2

21. Utility Theory (Cont.) (2.) Expanding U(W - p) in a Taylor series expansion around W U(Wc) = U(W – p)  U(W) + U’(W)[(W-p)-W] + … U(Wc) = U(W) + U’(W)(-p) Rem. : E(U(W + Z)) = U(Wc)  U(W) + (½) U’’(W) sz2 = U(W) + U’(W)(-p) Rearranging p = -½ sz2 [U’’(W)] / [U’(W)] Hence : A(W) = -U’’(W) / U’(W)

22. Relative Risk Aversion • Percentage ‘insurance premium’ is p = (W-Wc)/W Or Wc = W(1-p) • Z is now outcome per Dollar invested WZ • Let E(Z) = 1 and E(Z – E(Z))2 = sz2 Choice A Choice B WZ = Wc Applying a Taylor series expansion : (1.) U(WZ) = U(W) + U’(W)(WZ–W) + (U’’(W)/2) (WZ-W)2 + … Taking expectations and using the assumptions EU(WZ) = U(W) + 0 + (U’’(W)/2) [W2sz2]

23. Relative Risk Aversion (Cont.) (2.) U(Wc) = U[W(1 – p)] = U(W) + U’(W)[W(1 – p) – W] + … U(Wc) = U(W) + U’(W) (-pW) U(W) + ½ U’’(W) sz2 W2 = U(W) – pWU’(W) p = -(sz2 /2) [WU’’(W) / U’(W)] Hence : R(W) = -WU’’(W) / U’(W)

24. Summary : Attitude Towards Risk • Risk Averse Definition : Reject a fair gamble U’’(0) < 0 • Risk Neutral Definition : Indifferent to a fair game U’’(0) = 0 • Risk Loving Definition : Selects a fair game U’’(0) > 0

25. Utility Functions : Graphs Utility U(W) Risk Neutral Risk Averter U(16) U(10) U(4) Risk Lover Wealth 4 10 16

26. Indifference Curves in Risk – Return Space Risk Averter Risk Lover Expected Return Risk Neutral Risk, s

27. Examples of Utility Functions

28. Utility Function : Power • Constant Relative Risk Aversion • U(W) = W(1-g) / (1-g) g > 0, g ≠ 1 • U’(W) = W-g • U’’(W) = -gW-g-1 • RA(W) = g/W • RR(W) = g (a constant)

29. Utility Function : Logarithmic • As g 1, logarithmic utility is a limiting case of power utility • U(W) = ln(W) • U’(W) = 1/W • U’’(W) = -1/W2 • RA(W) = 1/W • RR(W) = 1

30. Utility Function : Quadratic • U(W) = W – (b/2)W2 b > 0 • U’(W) = 1 – bW • U’’ = -b • RA(W) = b/(1-bW) • RR(W) = bW / (1-bW) • Bliss point : W < 1/b

31. Utility Function : Negative Exponential • Constant Absolute Risk Aversion • U(W) = a – be-cWc > 0 • RA(W) = c • RR(W) = cW

32. Empirical Evidence

33. How does it Work in the ‘Real World’ ? • To investigate whether (specific) utility functions represent behaviour of economic agents : • Experimental evidence from simple choice situations • Survey data on investor’s asset choices

34. Empirical Studies • Blume and Friend (1975) • Data : Federal Reserve Board survey of financial characteristics of consumers • Findings : Percentage invested in risky asset unchanged for investors with different wealth • Cohn et al (1978) • Data : Survey data from questionnaires (brokers and its customers) • Findings : Investors exhibit decreasing relative RA and decreasing absolute RA

35. Coefficient of Relative Risk Aversion (g) • From experiments on gambles coefficient of relative risk aversion (g) is expected to be in the range of 3–10. • S&P500 Average real return (since WW II) 9% p.a. with SD 16% p.a. C-CAPM suggests coefficient of relative risk aversion (g) of 50.  Equity Premium Puzzle

36. Is g = 50 Acceptable ? • Based on the C-CAPM • For g = 50, risk free rate must be 49% • Cochrane (2001) presents a nice example • Annual earnings $ 50,000 • Annual expenditure on holidays (5%) is $ 2,500 • Rft ≈ (52,500/47,500)50 – 1 = 14,800% p.a. • Interpretation : Would skip holidays this year only if the risk free rate is 14,800% !

37. How Risk Averse are You ? • Investigate the plausibility of different values of g to examine the certainty equivalent amount for various bets. • Avoiding a fair bet (i.e. win or lose $x) • Power utility • Initial consumption : $ 50,000

38. Avoiding a Fair Bet !

39. Application : Mean Variance Model

40. Mean-Variance Model and Utility Functions • Investors maximise expected utility of end-of-period wealth • Can be shown that above implies maximise a function of expected portfolio returns and portfolio variance providing • Either utility is quadratic, or • Portfolio returns are normally distributed (and utility is concave) • W = W0(1 + Rp) • U(W) = U[W0(1 + Rp)]

41. Mean-Variance Model and Utility Functions (Cont.) Expanding U(Rp) in Taylor series around mean of Rp (=mp) • U(Rp) = U(mp) + (Rp – mp) U’(mp) + (1/2)(Rp – mp)2 U’’(mp) + higher order terms • Taking expectations E[U(Rp)] = U(mp) + (1/2) s2p U’’(mp) +E(higher-terms) • E[U(Rp)] is only a function of the mean and variance • Need specific utility function to know the functional relationship between E[U(Rp)] and (mp, sp) space

42. Summary • Utility functions, expected utility • Different measures of risk aversion : absolute, relative • Attitude towards risk, indifference curves • Empirical evidence and an application of utility analysis

43. References • Cuthbertson, K. and Nitzsche, D. (2004) ‘Quantitative Financial Economics’, Chapter 1

44. References • Blume, M. and Friend, I. (1975) ‘The Asset Structure of Individual Portfolios and Some Implications for Utility Functions’, Journal of Finance, Vol. 10(2), pp. 585-603 • Cohn, R., Lewellen, W., Lease, R. and Schlarbaum, G. (1975) ‘Individual Investor Risk Aversion and Investment Portfolio Composition’, Journal of Finance, Vol. 10(2), pp. 605-620. • Cochrane, J.H. (2001) Asset Pricing, Princeton University Press

45. END OF LECTURE