Mathematical and Statistical Methods for Actuarial Sciences and Finance

196 E. Luciano and P. Semeraro

It depends on three marginal parameters(μj,σj,αj)and an additional common
parametera. Its characteristic function is the following

ψX(t)(u)=

∏n

j= 1

(

1 −αj

(

iμjuj−

1

2

σ^2 ju^2 j

))−t

(

α^1

j−a

)

⎛

⎝ 1 −

∑n

j= 1

αj

(

iμjuj−

1

2

σ^2 ju^2 j

)

⎞

⎠

−ta

. (4)

The usual multivariate VG obtains forαj=α,j= 1 ,...,nanda=^1 α.
For the sake of simplicity, from now on we consider the bivariate case.
Since the marginal processes are VG, the corresponding distributions at timet,
Ft^1 andFt^2 can be obtained in a standard way, i.e., conditioning with respect to the
marginal time change:

Fti(xi)=

∫+∞

0



(

xi−μi(wi+αiz)

σi

√

wi+αiz

)

fGi(t)(z)dz, (5)

whereis a standard normal distribution function andfGi(t)is the density of a gamma

distribution with parameters

(

t

αi,

t

αi

)

. The expression for the joint distribution at time

t,Ft=FX(t),is:

Ft(x 1 ,x 2 )=

∫∞

0

∫∞

0

∫∞

0



(

x 1 −μ 1 (w 1 +αz)

σ 1

√

w 1 +α 1 z

)



(

x 2 −μ 2 (w 2 +βz)

σ 2

√

w 2 +α 2 z

)

(6)

·fY 1 (t)(w 1 )fY 2 (t)(w 2 )fZ(t)(z)dw 1 dw 2 dz, (7)

wherefY 1 (t), fY 2 (t), fZ(t)are densities of gamma distributions with parameters re-

spectively:

(

t

(

1

α 1 −a

)

,α^11

)

,

(

t

(

1

α 2 −a

)

,α^12

)

and(ta, 1 )[11].

2.1 Dependence structure

In this section, we investigate the dependence or association structure of theα-VG
process.
We know from Sklar’s Theorem that there exists a copula such that any joint
distribution can be written in terms of the marginal ones:

Ft(x 1 ,x 2 )=Ct(Ft^1 (x 1 ),Ft^2 (x 2 )). (8)

The copulaCtsatisfies:

Ct(u 1 ,u 2 )=Ft((Ft^1 )−^1 (u 1 ),(Ft^2 )−^1 (u 2 )), (9)

where(Fti)−^1 is the generalised inverse ofFti,i= 1 ,2.