ACTS 4302 Instructor: Natalia A. Humphreys SOLUTION TO HOMEWORK 4
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ACTS 4302 Instructor: Natalia A. Humphreys SOLUTION TO HOMEWORK 4
ACTS 4302 Instructor: Natalia A. Humphreys SOLUTION TO HOMEWORK 4 Lesson 6: Binomial trees: miscellaneous topics. Lesson 7: Modeling stock prices with the lognormal distribution. Problem 1 For a 1-year American put option on a stock with 6 months left to expiry, you are given: (i) The strike price is 42. (ii) The continuous dividend rate for the stock is 0.03. (iii) 6 months before expiry, the stock price is 33. (iv) The value of a 6-month call option on the stock with a strike price of 42 is 0.155. Calculate the lowest possible continuously compounded risk-free rate so that exercising the option at 6 months before expiry is optimal. Solution. Since early exercise is optimal, the present value of interest on the strike price must exceed the present value of dividends plus the value of the implicit call option: K(1 − e−rt ) ≥ S(1 − e−δt ) + C The present value of dividends is: 33 1 − e−0.5·0.03 = 0.4913 The value of the call option is given as 0.155. The present value of interest on the strike price is 42 1 − e−0.5r Hence, 42 1 − e−0.5r ≥ 0.4913 + 0.155 = 0.6463 e−0.5r = 0.9846 r = 0.031 Problem 2 The Jarrow-Rudd binomial tree is used to price an option on a non-dividend paying stock. You are given: (i) The risk-free rate is 0.045. (ii) The annual volatility is 29%. (iii) The period of the binomial tree is 7 months. Determine the risk-neutral probability of an up move. Solution. Recall that for a Lognormal (Jarrow-Rudd) tree: u = e(r−δ−0.5σ 2 )h+σ √ h , d = e(r−δ−0.5σ 2 )h−σ √ h and p∗ = e(r−δ)h − d u−d Hence, 2 √ u = e0.5833[0.045−0.5(0.29 )]+0.29√ 0.5833 = e0.2232 = 1.2501 2 d = e0.5833[0.045−0.5(0.29 )]−0.29 0.5833 = e−0.2198 = 0.8027 e0.045·0.5833 − 0.8027 1.0266 − 0.8027 p∗ = = = 0.5005 1.2501 − 0.8027 0.4474 Copyright ©Natalia A. Humphreys, 2014 ACTS 4302. AU 2014. SOLUTION TO HOMEWORK 4. Problem 3 A Cox-Ross-Rubinstein binomial tree is used to model an option. You are given: (i) The continuously compounded risk-free rate is 5%. (ii) σ = 0.06. (iii) δ = 0. Determine the largest period for which this tree can be used without violating arbitrage conditions on the nodes. Solution. To avoid arbitrage, u and d must satisfy: d < e(r−δ)h < u For a Cox-Ross-Rubinstein tree: u = eσ √ h , d = e−σ √ h Thus, to avoid arbitrage, we need e(r−δ)h < u ⇔ e(r−δ)h < eσ eσ √ √ h. Since δ = 0, √ 0.06 h h > erh ⇔ e > e0.05h ⇔ √ √ 6 0.06 h > 0.05h ⇔ h < ⇔ h < 1.44 5 Problem 4 An American company expects to receive £450,000 from sales in England at the end of 9 months. The current exchange rate is $1.5/£. The company would like to guarantee that it will get at least this rate when it receives the pounds, so that it will receive at least $675,000. You are given: (i) (ii) (iii) (iv) The continuously compounded risk-free rate in dollars is 4.3%. The continuously compounded risk-free rate in pounds is 3.5%. Relative volatility of the currencies is 0.2. A two-period Cox-Ross-Rubinstein binomial tree is used to determine the price of options. Determine the cost of an option, in dollars, which will guarantee the current exchange rate at the end of 9 months. Solution. The company should purchase a European put on pounds with strike price 1.50. For this option, the domestic currency is dollars and the foreign currency is pounds. Thus, r = rd = r$ = 0.043 δ = rf = r£ = 0.035 Also, note that h = 0.75/2 = 0.375. In a Cox-Ross-Rubinstein binomial tree the up and down movements, and the risk-neutral probability of an up move, are √ √ h = e0.2 0.375 = 1.1303 u = eσ √ √ −σ h −0.2 0.375 d=e =e = 0.8847 u − d = 0.2456 e(r−δ)h − d e(0.043−0.035)0.375 − 0.8847 p∗ = = = 0.4817 u−d 0.2456 1 − p∗ = 0.5183 The spot exchange rate tree: Page 2 of 7 Copyright ©Natalia A. Humphreys, 2014 ACTS 4302. AU 2014. SOLUTION TO HOMEWORK 4. u2 x0 = 1.9163 ux0 = 1.6954 x0 = 1.5 udx0 = 1.5 dx0 = 1.3271 ddx0 = 1.1741 The put tree: Puu = 0 Pu Pud = 0 P Pd Pdd = 0.3259 Pd = e−rh (p∗ Pud + (1 − p∗ )Pdd ) = e−0.043·0.375 · 0.5183 · 0.3259 = 0.1662 Since the put is the European put, we continue with this value of Pd : P = e−0.043·0.375 · 0.5183 · 0.1662 = 0.0848$/£ This is the cost of a put to buy £1. The total price of a put on £450,000 is: 450,000 · 0.0848 = 38,143.61 Note that if the put were an American put, the answer would be slightly different: If exercised, 1.5 − 1.3271 = 0.1729. Since 0.1729 > 0.1662, we use 0.1729 in further calculations: P = e−0.043·0.375 · 0.5183 · 0.1729 = 0.0882$/£ This is the cost of a put to buy £1. The total price of a put on £450,000 is: 450,000 · 0.0882 = 39,684.74 Problem 5 You are given the following information on the price of a stock: Page 3 of 7 Copyright ©Natalia A. Humphreys, 2014 ACTS 4302. AU 2014. SOLUTION TO HOMEWORK 4. Date Stock price Jul. 1, 2007 35.30 Aug. 1, 2007 33.90 Sep. 1, 2007 41.20 Oct. 1, 2007 31.95 Nov. 1, 2007 38.25 Dec. 1, 2007 46.18 Estimate the annual volatility of continuously compounded return on the stock. (A) 0.20 (B) 0.62 (C) 0.68 (D) 0.69 (E) 0.75 Key: D Solution. To estimate volatility from historical data: s P P 2 √ xt n St xt 2 −x ¯ , where xt = ln , x ¯= σ ˆ= N n−1 n St−1 n N is the number of periods per year, n is the number one less than the number of observations of stock price. In our problem N=12 and n=5. We calculate xt = ln(St /St−1 ) and x2t : St xt x2t 35.30 33.90 -0.0405 0.0016 41.20 0.1950 0.0380 31.95 -0.2543 0.0647 38.25 0.1800 0.0324 46.18 0.1884 0.0355 Summing up the third column and its squares, 5 X 5 X 0.2687 = 0.05373, x2t = 0.1722 5 t=1 t=1 √ 5 0.1722 s2 = − 0.053732 = 0.03944, s = 0.03944 = 0.1986 4 5 That is the monthly volatility. The annual volatility is √ 0.1986 12 = 0.688 ≈ 0.69 xt = 0.2687, x ¯= Problem 6 A stock’s price follows a lognormal model. You are given: (i) The current price of the stock is 105. (ii) The probability that the stock’s price will be less than 98 at the end of 6 months is 0.3483. Page 4 of 7 Copyright ©Natalia A. Humphreys, 2014 ACTS 4302. AU 2014. SOLUTION TO HOMEWORK 4. (iii) The probability that the stock’s price will be less than 115 at the end of 9 months is 0.7123. Calculate the expected price of the stock at the end of one year. Solution. Recall from Lesson 7 that probabilities of payoffs of stock prices are: P r(St < K) = N (−dˆ2 ), and P r(St > K) = N (dˆ2 ), where ln SK0 + (α − δ + 0.5σ 2 )t ln SK0 + (µ + σ 2 )t ˆ √ √ d1 = = σ t σ t ln SK0 + µt ln SK0 + (α − δ − 0.5σ 2 )t ˆ √ √ = d2 = σ t σ t √ dˆ2 = dˆ1 − σ t Hence, our statements could be written as: P r (S0.5 < 98) = N (−dˆ2 (0.5)) = 0.3483 P r (S0.75 < 115) = N (−dˆ2 (0.75)) = 0.7123 Calculating dˆ2 (0.5) and dˆ2 (0.75), we obtain: 105 98 √+ ln dˆ2 (0.5) = ln dˆ2 (0.75) = µ · 0.5 σ 0.5 105 115 √+ = µ · 0.75 0.069 + 0.5µ 0.7071σ = −0.091 + 0.75µ 0.866σ σ 0.75 On the other hand, using the standard normal probability table for N (z) = 0.3483 and N (z) = 0.7123, we obtain: −dˆ2 (0.5) = −0.39 −dˆ2 (0.75) = 0.56 Thus, we solve the system: 0.069+0.5µ 0.7071σ = 0.39 ⇔ 0.069 + 0.5µ = 0.2758σ −0.091+0.75µ −0.091 + 0.75µ = −0.485σ = −0.56 0.866σ 0.5µ − 0.2758σ = −0.069 µ − 0.5517σ = −0.138 ⇔ 0.75µ + 0.485σ = 0.091 µ + 0.6467σ = 0.1213 to obtain: σ = 0.2164, µ = −0.01864. Therefore, m = µ · t = −0.01864t, v 2 = σ 2 t = 0.0468t and the expected value of the stock after one year is 2 E[S1 ] = S0 em+0.5v = 105e−0.01864+0.5·0.0468 = 105.5025 This problem could be solved slightly differently, using the theory of percentiles. The probability statements result in these two equations expressing the percentiles in terms of standard normal coefficients of the 100pth percentile, or zp : √ 105e0.5µ+ √0.5σz0.3483 = 98 105e0.75µ+ 0.75σz0.7123 = 115 The normal percentiles are: z0.3483 = −0.39 and z0.7123 = 0.56. Hence, 0.5µ − 0.2758σ = −0.069 0.75µ + 0.485σ = 0.091 This is the same system as in the first approach above. Page 5 of 7 Copyright ©Natalia A. Humphreys, 2014 ACTS 4302. AU 2014. SOLUTION TO HOMEWORK 4. Problem 7 A stock’s price follows a lognormal model. You are given: (i) The initial price is 95. (ii) α = 0.14. (iii) δ = 0.07. (iv) σ = 0.4. Construct a 95% confidence interval for the price of the stock at the end of five years. Solution. The lognormal parameter m for the distribution of the stock price after five years is (α − δ − 0.5σ 2 )t = (0.14 − 0.07 − 0.5 · 0.42 )5 = −0.05 √ The lognormal parameter v is 0.4 5 = 0.8944. The confidence interval is −0.05 ± 1.96(0.8944) = (−1.8031, 1.7031) Exponentiating, we get e−1.8031 , e1.7031 = (0.1648, 5.4909) Multiplying by the initial stock price of 95, the answer is (15.66, 521.64). Problem 8 A stock’s price follows a lognormal model. The current price of the stock is 50. A 95% confidence interval for the price of the stock at the end of one year is (41.20, 73.05). Construct a 90% confidence interval for the price of the stock at the end of two years. Solution. We know that 41.20 = 50eµ−1.96σ and 73.05 = 50eµ+1.96σ so the quotient is: 73.05 = 1.7731 41.20 ln 1.7731 σ= = 0.1461 3.92 e3.92σ = and the product is e2µ = We need 41.20 · 73.05 = 1.2039 502 √ 2σ 50e2µ−1.645 √ and 50e2µ+1.645 2σ Calculating: √ √ e1.645 2σ =√e1.645 2·0.1461 = 1.4049 50e2µ−1.645 2σ = 50(1.2039)/1.4049 = 42.85 √ 50e2µ+1.645 2σ = 50(1.2039)(1.4049) = 84.56 Thus the 90% confidence interval for the price of the stock at the end of two years is (42.85, 84.56). Problem 9 A stock’s price follows a lognormal model. You are given: (i) The stock’s initial price is 60. (ii) The stock’s continuously compounded rate of return is 0.06. (iii) The stock’s continuously compounded dividend rate is 0.03. Page 6 of 7 ACTS 4302. AU 2014. SOLUTION TO HOMEWORK 4. Copyright ©Natalia A. Humphreys, 2014 (iv) Volatility is 0.25. Calculate the conditional expected value of the stock after 1 year given that it is greater than 70. Solution. We use the formula E[St |St > K] = S0 e(α−δ)t N (dˆ1 ) N (dˆ2 ) Calculating dˆ1 and dˆ2 : ln SK0 + (α − δ + 0.5σ 2 )t ln (60/70) + 0.06 − 0.03 + 0.5(0.252 ) ˆ √ d1 = = = −0.3716 0.25 σ t √ dˆ2 = dˆ1 − σ t = −0.3716 − 0.25 = −0.6216 Then N (−0.3716) = N (−0.6216) 1 − N (0.3716) 1 − N (0.3716) = 61.8273 = 61.8273 ≈ 1 − N (0.6216) 1 − N (0.6216) 1 − N (0.37) 1 − 0.6443 ≈ 61.8273 = 61.8273 = 82.1822 1 − N (0.62) 1 − 0.7324 E[St |St > 70] = 60e0.03 Problem 10 A stock’s price follows a lognormal model. You are given: (i) The stock’s initial price is 42. (ii) The stock’s continuously compounded rate of return is 0.156. (iii) The stock’s continuously compounded dividend rate is 0.03. (iv) Volatility is 0.36. A European call option on the stock expires in 6 months and has strike price 47. Calculate the expected payoff for the call option. Solution. We use the formula E[max(0, St − K)] = S0 e(α−δ)t N (dˆ1 ) − KN (dˆ2 ) Calculating dˆ1 and dˆ2 : S0 ln + (α − δ + 0.5σ 2 )t ln (42/47) + (0.156 − 0.03 + 0.5(0.362 ))0.5 K √ √ dˆ1 = = = −0.0671 ≈ −0.07 σ t 0.36 0.5 √ √ dˆ2 = dˆ1 − σ t = −0.0671 − 0.36 0.5 = −0.3217 ≈ −0.32 N (dˆ1 ) = N (−0.07) = 1 − N (0.07) = 1 − 0.5279 = 0.4721 N (dˆ2 ) = N (0.32) = 1 − N (0.32) = 1 − 0.6255 = 0.3745 The expected payoff for the call option is E[max(0, St − K)] = 42e0.063 (0.4721) − 47(0.3745) = 3.5161 Page 7 of 7