108156.pdf

188 Mathematics for Finance

Above we have identified the risk-neutral probabilityP∗. Now we shall con-
sider a European call option on the stock with strike priceXto be exercised
at timeT. The general formula (8.6) for the price of an option becomes

CE(0) =E∗

(

e−rT(S(T)−X)+

)

.

Let us compute this expectation. BecauseV(T)=W(t)+

(

m−r+^12 σ^2

)t
σfor
t(≥0 is a Wiener process underP∗, the random variableV(T)=W(T)+
m−r+^12 σ^2

)T

σis normally distributed with mean 0 and varianceT,thatis,
it has density√ 21 πTe−x

2

2 T. As a result,

CE(0) =E∗

(

e−rT(S(T)−X)+

)

=E∗

((

S(0)eσV(t)−

(^12) σ (^2) T
−Xe−rT

)+)

=

∫∞

−d 2 √T

(

S(0)eσx−^12 σ

(^2) T
−Xe−rT

) 1

√

2 πT

e−x

2

2 Tdx

=S(0)

∫∞

−d 1

√^1

2 π

e−

y 22

dy−Xe−rT

∫∞

−d 2

√^1

2 π

e−

y 22

dy

=S(0)N(d 1 )−Xe−rTN(d 2 ),

where

d 1 =

lnSX(0)+

(

r+^12 σ^2

)

T

σ

√

T

,d 2 =

lnSX(0)+

(

r−^12 σ^2

)

T

σ

√

T

, (8.9)

and where

N(x)=

∫x

−∞

√^1

2 π

e−

y 22

dy=

∫∞

−x

√^1

2 π

e−

y 22

dy (8.10)

is the normal distribution function.
What we have just derived is the celebrated Black–Scholes formula for Eu-
ropean call options. The choice of time 0 to compute the price of the option
is arbitrary. In general, the option price can be computed at any timet<T,
in which case the time remaining before the option is exercised will beT−t.
Substitutingtfor 0 andT−tforTin the above formulae, we thus obtain the
following result.

Theorem 8.6 (Black–Scholes Formula)

The timetprice of a European call with strike priceXand exercise timeT,
wheret<T,isgivenby

CE(t)=S(t)N(d 1 )−Xe−r(T−t)N(d 2 )