SOCR EduMaterials Activities ApplicationsActivities BinomialOptionPricing

(Difference between revisions)
 Revision as of 16:29, 3 August 2008 (view source)Nchristo (Talk | contribs) (New page: == Binomial Option Pricing Model = * '''Description''': You can access the portfolio applet at http://www.socr.ucla.edu/htmls/app/ . Define:
$S_0$ Stock price at Where,
$[itex] - u=e^{+\sigma \sqrt{\frac{t}{n}}}, \ \ + u=e^{+\sigma \sqrt{\frac{t}{n}}}, d=e^{-\sigma \sqrt{\frac{t}{n}}}=\frac{1}{u} d=e^{-\sigma \sqrt{\frac{t}{n}}}=\frac{1}{u}$ [/itex]

= Binomial Option Pricing Model

Define:

S0 Stock price at t = 0
S1 Stock price at t = 1 < math > < br > < math > E Exercise price of the call option
u $1+ \%$ change in stock price from t = 0 to t = 1 if stock price increases (u > 1)
d $1+ \%$ change in stock price from t = 0 to t = 1 if stock price decreases (d < 1)
C The call price
α The number of shares of stocks purchased per one call (hedge ratio)
Cu Price of call at t = 1 if stock price increases: max(S1E,0) or max(uS0E,0)
Cd Price of call at t = 1 if stock price decreases: max(S1E,0) or max(dS0E,0)
r Continuous risk-free interest rate

• The value C of a European call option at time t = 0 is:

$C=S_0 \sum_{j=k}^{n} {n \choose j} p'^{j}(1-p')^{n-j} - \frac{E}{e^{rt}} \sum_{j=k}^{n} {n \choose j} p^{j}(1-p)^{n-j}$
Where,
$u=e^{+\sigma \sqrt{\frac{t}{n}}}, d=e^{-\sigma \sqrt{\frac{t}{n}}}=\frac{1}{u}$
$p=\frac{e^{rt}-d}{u-d}, \ \ p'=\frac{up}{e^{rt}}$

S0 Price of the stock at time t = 0
E Exercise price at expiration
r Risk-free interest rate per period
n Number of periods
σ Annual standard deviation of the returns of the stock
t &Time to expiration in years

• The SOCR Binomial Option Pricing applet provides the price of the stock and the price of the call at each node. Note that at expiration the nodes for which the call is in the money (S > E are colored green, while the nodes for which the call is out of the money ($S \le E)$ are colored blue. The example below uses the following data:

$S_0=\30$, $E=\29$, rf = 0.05, σ = 0.30, days to expiration = 73, number of steps = 5.

• The materials above was partially taken from

Modern Portfolio Theory by Edwin J. Elton, Martin J. Gruber, Stephen J. Brown, and William N. Goetzmann, Sixth Edition, Wiley, 2003, and
Options, Futues, and Other Derivatives by John C. Hull, Sixth Edition, Pearson Prentice Hall, 2006.