TARAS BELETSKI AND RALF KORN 175withXφ(t)=φ 0 (t)P 0 (t)+φ 1 (t)f(1)(t,P 1 (t),I(t))+φ 2 (t)f(2)(t,P 1 (t),I(t)) (9.13)(and B(x) the set of all admissible trading strategies in the bond and the
two derivatives for an initial wealth of x) admits the following solution:(a) The optimal final wealth B* coincides with the optimal final wealth
in the corresponding basic portfolio problem (P) where the investor is
assumed to be able to trade the stock and the inflation index.(b) Letξ(t)=(ξ 0 (t),ξ 1 (t),ξ 2 (t)) denote the optimal trading strategy of the
corresponding basic portfolio problem (P). Then the optimal trading
strategy for the option portfolio problemφ(t)=(φ 0 (t),φ 1 (t),φ 2 (t)) is
given by:
φ ̄(t)=(
(t)′)−^1 ·ξ ̄(t),φ 0 (t)=(
X(t)−∑d
i= 1φi(t)f(i)(t,P 1 (t),...,Pd(t)))P 0 (t)(9.14)withφ ̄(t)=(φ 1 (t),φ 2 (t))′and ̄ξ(t)=(ξ 1 (t),ξ 2 (t)).Equipped with this result we are now able to solve various particular port-
folio problems related to inflation explicitly. But first we recall examples of
explicit solutions of the basic portfolio problem (P):
Step 1: Solving the basic portfolio problem (P). In this step we will treat the
inflation index as a tradable good and solve the portfolio problem (P) for
the choices ofU(x)∈{ln (x), 1/γxγ} withγ< 1 (9.15)With the notation ofσ=(
σ 1 σ 2
0 σI)
(9.16)the solutions of the basic portfolio problem (P) for these choices of the utility
functions are well-known and are given by:π∗(t)=1
1 −γ(σσ′)−^1(
b−rN
λσI−rR)
(9.17)