308 G. Villani
are two Brownian motions under the risk-neutral probability measure
∼
QandZ′isa Brownian motion under
∼
Qindependent ofZˆd. By the Brownian motions defined
in Equations (11) and (12), we can rewrite Equation (7) for the assetPunder the
risk-neutral probability
∼
Q. So it results that:
dP
P=−δdt+σvdZˆv−σddZˆd. (13)Using Equation (12), it results that:
σvdZˆv−σddZˆd=(σvρvd−σd)dZˆd+σv(√
1 −ρ^2 vd)
dZ′, (14)whereZˆv andZ′are independent under
∼
Q. Therefore, as(σvdZˆv−σddZˆd)∼
N( 0 ,σ
√
dt), we can rewrite Equation (13):
dP
P=−δdt+σdZp, (15)whereσ=
√
σv^2 +σd^2 − 2 σvσdρvdandZpis a Brownian motion under∼
Q.Usingthelog-transformation, we obtain the equation for the risk-neutral price simulationP:
Pt=P 0 exp{(
−δ−σ^2
2)
t+σZp(t)}
. (16)
So, using the assetDTas numeraire given by Equation (10), we price a SEEO as the
expectation value of discounted cash-flows under the risk-neutral probability measure:
s(V,D,T)=e−rTEQ[max( 0 ,VT−DT)]
=D 0 e−δdTE∼
Q[gs(PT)], (17)wheregs(PT)=max(PT− 1 , 0 ). Finally, it is possible to implement the Monte Carlo
simulation to approximate:
E∼
Q[gs(PT)]≈1
n∑ni= 1gsi(PˆTi), (18)wherenis the number of simulated paths effected,PˆTifori= 1 , 2 ...nare the simulated
values andgsi(PˆTi)=max( 0 ,PˆTi− 1 )are thensimulated payoffs of SEEO using a
single stochastic factor.
3 The price of a Compound European Exchange Option (CEEO)
The CEEO is a derivative in which the underlying asset is another exchange option.
Carr [5] develops a model to value the CEEO assuming that the underlying asset is