Perpetual integral functionals as hitting and occupation times
Abstract
Let X be a linear diffusion and f a non-negative, Borel measurable function. We are interested in finding conditions on X and f which imply that the perpetual integral functional IX∞(f):=∫0∞ f(Xt) dt is identical in law with the first hitting time of a point for some other diffusion. This phenomenon may often be explained using random time change. Because of some potential applications in mathematical finance, we are considering mainly the case when X is a Brownian motion with drift μ>0, denoted \B(μ)t: t≥ 0\, but it is obvious that the method presented is more general. We also review the known examples and give new ones. In particular, results concerning one-sided functionals ∫0∞ f(B(μ)t) 1\B(μ)t<0\ dt and ∫0∞ f(B(μ)t) 1\B(μ)t>0\ dt are presented. This approach generalizes the proof, based on the random time change techniques, of the fact that the Dufresne functional (this corresponds to f(x)=(-2x)), playing quite an important r\ole in the study of geometric Brownian motion, is identical in law with the first hitting time for a Bessel process. Another functional arising naturally in this context is %associated to the function ∫0∞ (a+(B(μ)t))-2 dt, which is seen, in the case μ=1/2, to be identical in law with the first hitting time for a Brownian motion with drift μ=a/2. The paper is concluded by discussing how the Feynman-Kac formula can be used to find the distribution of a perpetual integral functional.
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