Derivatives

1. Derivatives Financial products that depend on another, generally more basic, product such as a stock

2. Examples • Forward contracts • Futures • Options • Swaps

3. Forward contracts • A agrees to buy and B agrees to sell an asset • at specific price, K (forward price) • On specific date, T (delivery date) • A takes ‘long position’ • B takes ‘short position’ • Agricultural crops and commodities

4. Y(T) Y(T) Long position of buyer K K But price fluctuates in the future time! • Actual price at time T:Y(T) and K can differ • Payoff can be both positive and negative • Whatever is gained by A is lost by B • And vice versa Short position of seller

5. Options • Gives holder right to exercise a given action • Buy (or sell) underlying asset • At time T • exercise date; expiration date; date of maturity • for price K • Strike price; exercise price • European option • can only be exercised at maturity (t= T) • American option • can be exercised anytime between t=0 & t=T • Exotic options • Even more complicated boundary conditions!

6. European Calls and Puts • Call option • A has right (but not obligation) to buy underlying asset at strike price at maturity • B is obliged to sell • Secured by paying fee C(Y,t) to B (via option dealer) • Unlike future: No symmetry between buyer and seller • Buyer pays C at time t=0 and acquires right to buy at t=T • Seller receives cash but faces potential liabilities at t=T

7. Y(T) C(Y,0) K C(Y,0) Y(T) K Payoff for seller of call option Payoff for European call options Payoff for buyer of call option

8. Buyer has right to sell underlying asset at strike price, K at maturity time, T Put options Y(T) C(Y,0) K Payoff for buyer of put option C(Y,0) Y(T) K Payoff for seller of put option

9. ? • How much would one pay for the option? • How can the seller minimise the risk associated with his obligation?

10. Simple example • Suppose in 3 months time using a call option, may purchase 1 share in Acme Ltd for 2.50 • Scenario 1 • In 3 months Acme Ltd trades at 2.70 • Exercise option: buy for 2.50; sell at 2.70; profit is .20 • Scenario 2 • In 3 months Acme Ltd trades at 2.30 • Let option lapse

11. Assume 2 equal probability scenarios • Expected profit is • ½*0 +½*20 = 10 • Ignore interest rate effects reasonable to assume value of option is 10 • Scenario 1 • Profit on exercise: 20 • cost of option: (10) • Net profit: 10 • gain100% • Scenario 2 • Cost of option: (10) • Net loss (10) • Loss 100%

12. But suppose buy shares • At T = 0 share price 250 • Buy 1 share • Scenario 1 • Sell at 270; • profit 20; • Gain 20/250*100 = +8% • Scenario • Sell at 230; • loss 20; • Loss -8% • Options respond in more exaggerated way • More highly geared • Used for speculating/ gambling and insurance

13. Put options • Allows holder to sell asset at prescribed price • strike or exercise price • Holder of ‘calls’ hopes asset price will rise • Holder of ‘puts’ hopes price to fall • Can also use as insurance against fall of prices in portfolio

14. Hedging - a form of insurance • Say UK company must pay S = 10000 euro to Irish firm in 180 days • 1 can write forward contract at present exchange rate for S • 2 Buy call option for given strike price at 180 days maturity • Eliminates risk associated with exchange rate fluctuations • Risk is • exposure to losses in forward contract • Or cost of option contract

15. Equity options (Financial Times 22 November 2003)

16. Extent of trade in calls and puts (vanilla options) • ~ $10,000 billion worldwide • In late 1992 Citicorp alone had contracts totalling ~ $1426 billion • May in some markets have a value greater than the underlying asset • In some cases, options are more liquid than actual asset

17. Y(21 November)=4319

18. At expiry C = -(K-4325) K<Y(T) C = 0 K>Y(T) Y(T)=4325 Option values at expiry (FTSE = 4319 at 21 Nov 2003 - 3rd Friday in month)

19. Y; C  Y; C time t=0 t=t1 Y; C ‘Risk-less’ portfolio(Binomial model) • Y changes with time, hence h must also be changed to maximise hedging process and minimise risk

20. Holder of shares selling a derivative of stock at time, t Change must equal gain obtained by investing in riskless security (eg cash) Rational and fair price

21. Differential v stochastic calculus

22. Assumptions of Black Scholes 1973

23. Black Scholes SPDE Valid for all types of options Choice of solution determined by boundary conditions

24. Boundary conditions: Call option C(Y, K, T) = Y(T)-K if Y>K C(Y, K, T) = 0 if Y<K C = max{Y-K, 0} C(Y,K,T) K Y(T)

25. Relation to heat transfer equation

27. Solution for puts

28. Problems • Interest rates, r may vary • Volatility, σ is not constant • Fat tails, not a Gaussian • Historical volatility • Over what time period? • Implied volatility • Use Black Scholes formula in inverse sense to compute volatility given set of C values (For BS it would be constant • Gives indication of level of volatility expected by market traders