Clark–Ocone theorem - Misplaced Pages

In mathematics, the Clark–Ocone theorem (also known as the Clark–Ocone–Haussmann theorem or formula) is a theorem of stochastic analysis. It expresses the value of some function F defined on the classical Wiener space of continuous paths starting at the origin as the sum of its mean value and an Itô integral with respect to that path. It is named after the contributions of mathematicians J.M.C. Clark (1970), Daniel Ocone (1984) and U.G. Haussmann (1978).

Statement of the theorem

Let C₀(; R) (or simply C₀ for short) be classical Wiener space with Wiener measure γ. Let F : C₀ → R be a BC function, i.e. F is bounded and Fréchet differentiable with bounded derivative DF : C₀ → Lin(C₀; R). Then

F(\sigma )=\int _{C_{0}}F(p)\,\mathrm {d} \gamma (p)+\int _{0}^{T}\mathbf {E} \left(\sigma )\,\mathrm {d} \sigma _{t}.

In the above

F(σ) is the value of the function F on some specific path of interest, σ;
the first integral,

\int _{C_{0}}F(p)\,\mathrm {d} \gamma (p)=\mathbf {E}

is the expected value of F over the whole of Wiener space C₀;

the second integral,

\int _{0}^{T}\cdots \,\mathrm {d} \sigma (t)

is an Itô integral;

Σ_∗ is the natural filtration of Brownian motion B : × Ω → R: Σ_t is the smallest σ-algebra containing all B_s(A) for times 0 ≤ s ≤ t and Borel sets A ⊆ R;
E denotes conditional expectation with respect to the sigma algebra Σ_t;
/_∂t denotes differentiation with respect to time t; ∇_H denotes the H-gradient; hence, /_∂t∇_H is the Malliavin derivative.

More generally, the conclusion holds for any F in L(C₀; R) that is differentiable in the sense of Malliavin.

Integration by parts on Wiener space

The Clark–Ocone theorem gives rise to an integration by parts formula on classical Wiener space, and to write Itô integrals as divergences:

Let B be a standard Brownian motion, and let L₀ be the Cameron–Martin space for C₀ (see abstract Wiener space. Let V : C₀ → L₀ be a vector field such that

{\dot {V}}={\frac {\partial V}{\partial t}}:\times C_{0}\to \mathbb {R}

is in L(B) (i.e. is Itô integrable, and hence is an adapted process). Let F : C₀ → R be BC as above. Then

\int _{C_{0}}\mathrm {D} F(\sigma )(V(\sigma ))\,\mathrm {d} \gamma (\sigma )=\int _{C_{0}}F(\sigma )\left(\int _{0}^{T}{\dot {V}}_{t}(\sigma )\,\mathrm {d} \sigma _{t}\right)\,\mathrm {d} \gamma (\sigma ),

i.e.

\int _{C_{0}}\left\langle \nabla _{H}F(\sigma ),V(\sigma )\right\rangle _{L_{0}^{2,1}}\,\mathrm {d} \gamma (\sigma )=-\int _{C_{0}}F(\sigma )\operatorname {div} (V)(\sigma )\,\mathrm {d} \gamma (\sigma )

or, writing the integrals over C₀ as expectations:

\mathbb {E} {\big }=-\mathbb {E} {\big },

where the "divergence" div(V) : C₀ → R is defined by

\operatorname {div} (V)(\sigma ):=-\int _{0}^{T}{\dot {V}}_{t}(\sigma )\,\mathrm {d} \sigma _{t}.

The interpretation of stochastic integrals as divergences leads to concepts such as the Skorokhod integral and the tools of the Malliavin calculus.

References

Nualart, David (2006). The Malliavin calculus and related topics. Probability and its Applications (New York) (Second ed.). Berlin: Springer-Verlag. ISBN 978-3-540-28328-7.

External links

Friz, Peter K. (2005-04-10). "An Introduction to Malliavin Calculus" (PDF). Archived from the original (PDF) on 2007-04-17. Retrieved 2007-07-23.

Categories:

Statement of the theorem

Integration by parts on Wiener space

See also

References

External links