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Chapter 6 Financial Options

Chapter 6 Financial Options. Financial Options Terminology Option Price Relationships Black- Scholes Option Pricing Model Put-Call Parity. Importance. Why do financial managers need to know options? Option pricing theory provides insights into the optimal debt/equity choice.

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Chapter 6 Financial Options

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  1. Chapter 6 Financial Options • Financial Options Terminology • Option Price Relationships • Black-Scholes Option Pricing Model • Put-Call Parity

  2. Importance Why do financial managers need to know options? • Option pricing theory provides insights into the optimal debt/equity choice. • Many projects allow managers to make strategic or tactical changes in plans as market conditions change. • Many companies use derivatives to manage risk • understanding financial options will help firms design their optimal managerial incentive to improve management efficiency and mitigate agency cost.

  3. What is a financial option? • An option is a contract which gives its holder the right, but not the obligation, to buy (or sell) an asset at some predetermined price within a specified period of time. • What is the single most important characteristic of an option? It does not obligate its owner to take any action. It merely gives the owner the right to buy or sell an asset!!

  4. Option Terminology • Call option [ c ] : An option to buy a specified number of shares of a security within some future period. • Put option [ p ]: An option to sell a specified number of shares of a security within some future period. • Strike (or exercise) price [ X ]: The price stated in the option contract at which the security can be bought or sold. • Expiration date [ t ]: The last date the option can be exercised. • Option price [ V ]: The market price of the option contract. • Exercise value: The value of a call option if it were exercised today = Current stock price - Strike price. [Note: The exercise value is zero if the stock price is less than the strike price.]

  5. Option Terminology (Continued) • Time value: Option price minus the exercise value. It is the additional value because the option has remaining time until it expires. • Covered option: A call option written against stock held in an investor’s portfolio. • Naked (uncovered) option: An option sold without the stock to back it up. • In-the-money call: A call whose strike price is less than the current price of the underlying stock. • Out-of-the-money call: A call option whose strike price exceeds the current stock price.

  6. Example Consider the following data:

  7. Example Exercise Value of Option

  8. Example Market Price of Option

  9. Example Time Value of Option

  10. Call Time Value Diagram Option value 30 25 20 15 10 5 Market price Exercise value 5 10 15 20 25 30 35 40 Stock Price

  11. Option Time Value Versus Exercise Value • The time value, which is the option price less its exercise value, declines as the stock price increases. • This is due to the declining degree of leverage provided by options as the underlying stock price increases, and the greater loss potential of options at higher option prices.

  12. The Binomial Model • Stock assumptions: • Current price: P = $27 • In next 6 months, stock can either • Go up by factor of 1.41 • Go down by factor of 0.71 • Call option assumptions • Expires in t = 6 months = 0.5 years • Exercise price: X = $25 • Risk-free rate: rRF = 6%

  13. Ending "up" stock price = P(u) = $38.07 Option payoff: Cu = MAX[0,P(u)−X] = $13.07 Currentstock priceP = $27 Ending “down" stock price = P(d) = $19.17 Option payoff: Cd = MAX[0,P(d)−X] = $0.00 u = 1.41d = 0.71X = $25 Binomial Payoffs at Call’s Expiration

  14. Create Portfolio Create portfolio by writing 1 option and buying Ns shares of stock. • Portfolio payoffs: • Stock is up: Ns(P)(u) − Cu • Stock is down: Ns(P)(d) − Cd

  15. The Hedge Portfolio with a Riskless Payoff • Set payoffs for up and down equal, solve for number of shares: Ns= (Cu − Cd) / P(u− d) • In our example: Ns= ($13.07− $0) / $27(1.41− 0.71) Ns=0.6915

  16. Ending "up" stock price = P(u) = $38.07 Ending "up" stock value = NsP(u) = $26.33Option payoff: Cu = MAX[0,P(u)−X] = $13.07Portfolio's net payoff = P(u)Ns - Cu = $13.26 Currentstock priceP = $27 Ending “down" stock price = P(d) = $19.17 Ending “down" stock value = NsP(d) = $13.26Option payoff: Cd = MAX[0,P(d)−X] = $0.00Portfolio's net payoff = P(d)Ns - Cd = $13.26 u = 1.41d = 0.71X = $25Ns = 0.6915 Riskless Portfolio’s Payoffs at Call’s Expiration: $13.26

  17. Riskless payoffs earn the risk-free rate of return. • Discount at risk-free rate compounded daily. • VPortfolio = PV of riskless payoff • VPortfolio = Payoff / (1 + rRF/365)365*t • VPortfolio = $13.26 / (1 + 0.06/365)365*0.5 • VPortfolio = $12.87

  18. The Value of the Call Option • Because the portfolio is riskless: VPortfolio= PV of riskless payoff • By definition, the value of the portfolio is: VPortfolio= Ns*(P) − VC • Equating these two and rearranging, we get the value of the call: PV of riskless payoff= Ns*(P) − VC or VC =Ns*(P) − PV of riskless payoff

  19. Value of Call • VC =Ns(P) − Payoff / (1 + rRF/365)365*t • VC =0.6915($27) − $13.26 / (1 + 0.06/365)365*0.5 = $18.67 − $12.87 = $5.80 (VC = $5.81 if no rounding in any intermediate steps.)

  20. Multi-Period Binomial Pricing • If you divided time into smaller periods and allowed the stock price to go up or down each period, you would have a more reasonable outcome of possible stock prices when the option expires. • This type of problem can be solved with a binomial lattice. • As time periods get smaller, the binomial option price converges to the Black-Scholes price, which we discuss in later slides.

  21. Replicating Portfolio • From the previous slide we have: • VC =Ns(P) − Payoff / (1 + rRF/365)365*t • The right side of the equation is the same as creating a portfolio by buying Ns shares of stock and borrowing an amount equal to the present value of the hedge portfolio’s riskless payoff (which must be repaid). • The payoffs of the replicating portfolio are the same as the option’s payoffs.

  22. Replicating Portfolio Payoffs: Amount Borrowed and Repaid • Amount borrowed: • PV of payoff = $12.87 • Repayment due to borrowing this amount: • Repayment = $12.87 (1 + rRF/365)365*tRepayment = $13.26 • Notice that this is the same as the payoff of the hedge portfolio.

  23. Replicating Portfolio Net Payoffs • Stock up: • Value of stock = 0.6915($38.07) =$26.33 • Repayment of borrowing = $13.26 • Net portfolio payoff = $13.07 • Stock down: • Value of stock = 0.6915($19.17) =$13.26 • Repayment of borrowing = $13.26 • Net portfolio payoff = $0 • Notice that the replicating portfolio’s payoffs exactly equal those of the option.

  24. Replicating Portfolios and Arbitrage • The payoff’s of the replicating portfolio exactly equal those of the call option. • Cost of replicating portfolio =Ns(P) − Amount borrowed =0.6915($27) − $12.87= $18.67 − $12.87= $5.80 • If the call option’s price is not the same as the cost of the replicating portfolio, then there will be an opportunity for arbitrage.

  25. Arbitrage Example • Suppose the option sells for $6. • You can write option, receiving $6. • Create replicating portfolio for $5.80, netting $6.00 −$5.80 = $0.20. • Arbitrage: • You invested none of your own money. • You have no risk (the replicating portfolio’s payoffs exactly equal the payoffs you will owe because you wrote the option. • You have cash ($0.20) in your pocket.

  26. Arbitrage and Equilibrium Prices • If you could make a sure arbitrage profit, you would want to repeat it (and so would other investors). • With so many trying to write (sell) options, the extra “supply” would drive the option’s price down until it reached $5.80 and there were no more arbitrage profits available. • The opposite would occur if the option sold for less than $5.80.

  27. Black-Scholes Option Pricing Model Assumptions of the Black-Scholes Option Pricing Model • The stock underlying the call option provides no dividends during the call option’s life. • There are no transactions costs for the sale/purchase of either the stock or the option. • RRF is known and constant during the option’s life. (More...)

  28. Assumptions (Continued) • Security buyers may borrow any fraction of the purchase price at the short-term risk-free rate. • No penalty for short selling and sellers receive immediately full cash proceeds at today’s price. • Call option can be exercised only on its expiration date. • Security trading takes place in continuous time, and stock prices move randomly in continuous time.

  29. V= P[N(d1)] - Xe -rRFt[N(d2)] d1 = * t 0.5 d2 = d1 - *t 0.5 ln(P/X) + [rRF + (2/2)]t Black-Scholes Option Pricing Model What is the value of the call option according to the OPM?

  30. First, find d1 and d2. Example: P = $27 ; X = $25 ; rRF = 6%; t = 0.5 years; σ2 = 0.11 d1= {ln($27/$25) + [(0.06 + 0.11/2)](0.5)} ÷ {(0.3317)(0.7071)} d1= 0.5736. d2 = d1 - (0.3317)(0.7071) d2= 0.5736 - 0.2345 = 0.3391.

  31. Second, find N(d1) and N(d2) • N(d1) = N(0.5736) = 0.7168. • N(d2) = N(0.3391) = 0.6327. • Note: Values obtained from Excel using NORMSDIST function. For example: • N(d1) = NORMSDIST(0.5736)

  32. Third, find value of option. V = $27(0.7168) - $25e-(0.06)(0.5)(0.6327) = $19.3536 - $25(0.97045)(0.6327) = $4.0036.

  33. Bonus question If you find an option has negative value from your calculation, what should you do next?

  34. The Impact of Parameters What impact do the following parameters have on a call option’s value? • Current stock price: Call option value increases as the current stock price increases. • Strike price: As the exercise price increases, a call option’s value decreases. • Option period: As the expiration date is lengthened, a call option’s value increases (more chance of becoming in the money.) • Risk-free rate: Call option’s value tends to increase as rRF increases (reduces the PV of the exercise price). • Stock return variance: Option value increases with variance of the underlying stock (more chance of becoming in the money).

  35. Put Options • A put option gives its holder the right to sell a share of stock at a specified stock on or before a particular date. • Value of put option= Max{ Strike price – Stock price, 0}

  36. Put-Call Parity • Portfolio 1: • Put option, V_p • Share of stock, P • Portfolio 2: • Call option, V_c • PV of exercise price (Cash), Xe Put and Call is based on same stock and has same strike price -rRFt

  37. Put-Call Parity Portfolio Payoffs at Expiration Date T for PT<X and PT≥X

  38. -rRFt V_p+ P = V_c+ Xe -rRFt V_p= V_c– P + Xe Put-Call Parity Relationship • Portfolio payoffs are equal, so portfolio values also must be equal. • Put + Stock = Call + PV of Exercise Price

  39. Extensions Some questions you may get sense after you finish this chapter: • Should options given as part of compensation packages be reported on the income statement as an expense? what are some pros and cons relating to this issue? • The rationale behind granting stock options is to induce employees to work harder and be more productive. as the stock price increases (presumably due to their hard work), the employees share in this added wealth. another way to share this wealth would be to grant shares of stock, rather than options. what are the advantages and disadvantages of using stock options rather than shares of stock as employee incentives?

  40. Extensions Some questions you may get sense after you finish this chapter: • The stockholders' claim in a levered firm can be viewed as a call option; stockholders have the option to purchase the firm's assets by paying off its debt. what incentives does this provide to stockholders and managers in choosing investment projects?

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