The Mathematics of Arbitrage

13.6 The SpaceGunder a Num ́eraire Change 275

is constructed with thed-dimensional processS,thespaceG

(S

V,

1

V

)

is the
space of workable contingent claims constructed with the (d+ 1)-dimensional
process

(S

V,

1

V

)

.

Theorem 13.6.2.Suppose thatSis a locally bounded semi-martingale that
satisfies the (NFLVR) property. Suppose thatV is a strictly positive process
of the formV=H·S+1where1+(H·S)∞is strictly positive and where
(H·S)∞is maximal admissible. Suppose that the processV^1 is locally bounded.
The mapping
φ: G(S)−→ G(SV,V^1 )
g −→ Vg∞

defines an isometry betweenG(S)=G(S,1)andG(VS,V^1 ).

Proof.SupposeV =H·S+1 where 1+(H·S)∞is strictly positive and
where (H·S)∞is maximal admissible. Take an admissible, with respect to
the processS,strategyK. The processKV·Sis the outcome of the strategy
K′=(K,(K·S)−−KS−), see also the Remark 13.2.10 above and Chap. 11.
From Theorem 13.2.5 above it follows that there is an elementQ∈Mesuch
thatEQ[(K·S)∞]=0andsuchthatEQ[V∞]=1.ThemeasureQ ̃defined
asdQ ̃=V∞dQis therefore an element ofM

(S

V,

1

V

)

such thatEQ ̃[KV∞·S]=0.

It follows that the contingent claimV^1 ∞−1 is maximal and admissible for the

process

(S

V,

1

V

)

and hence the contingent claim KV∞·Sis workable. It follows

that the mappingφmapsKmax, and hence alsoG(S), intoG

(S

V,

1

V

)

.

If we apply the num ́eraireV^1 to the system

(S

V,

1

V

)

we find the (d+1)-
dimensional process (S, V). However, becauseV is given by a stochastic in-
tegral with respect toS,wehavethatG(S, V)=G(S). It follows that the
mapping that associates with each elementk∈G

(S

V,

1

V

)

, the elementkV∞
mapsG

(S

V,

1

V

)

intoG(S). The mappingφis clearly bijective.

LetG={Q∈M(S)|EQ[V∞]=1}andG ̃={Q ̃∈M(VS,V^1 )|EQ ̃[V^1 ∞]=1}.

Since both sets are dense in, respectively,M(S)andM

(S

V,

1

V

)

,itisclear
that for every elementg∈G(S),

2 ‖g‖=sup{EQ[|g|]|Q∈M(S)}

=sup{EQ[|g|]|Q∈G}

=sup

{

EQ ̃

[

|g|

V∞

]∣∣

∣

∣

Q ̃∈G ̃

}

=sup

{

EQ ̃

[

|g|

V∞

]∣∣

∣

∣

Q ̃∈M

(

S

V

,

1

V

)}

=2

∥

∥

∥

∥

g

V∞

∥

∥

∥

∥.

This shows thatφis also an isometry.