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The | The '''Malliavin calculus''', named after [[Paul Malliavin]], extends the [[calculus of variations]] from functions to [[stochastic processes]]. The Malliavin calculus is also called the '''[[stochastic calculus]] of variations'''. In particular, it allows the computation of [[derivative]]s of [[random variable]]s. | ||
Malliavin ideas led to a proof that [[Hörmander's condition]] implies the existence and smoothness of a [[probability density function|density]] for the solution of a [[stochastic differential equation]]; [[Lars Hörmander|Hörmander]]'s original proof was based on the theory of [[partial differential equation]]s. The calculus has been applied to [[stochastic partial differential equation]]s as well. | |||
The calculus allows [[integration by parts]] with [[random variable]]s; this operation is used in [[mathematical finance]] to compute the sensitivities of [[derivative (finance)|financial derivative]]s. The calculus has applications for example in [[stochastic filtering]]. | |||
==Overview and history== | |||
Paul Malliavin's [[stochastic calculus]] of variations extends the [[calculus of variations]] from functions to [[stochastic processes]]. In particular, it allows the computation of [[derivative]]s of [[random variable]]s. | |||
Malliavin invented his calculus to provide a stochastic proof that [[Hörmander's condition]] implies the existence of a [[probability density function|density]] for the solution of a [[stochastic differential equation]]; [[Lars Hörmander|Hörmander]]'s original proof was based on the theory of [[partial differential equation]]s. His calculus enabled Malliavin to prove regularity bounds for the solution's density. The calculus has been applied to [[stochastic partial differential equation]]s. | |||
== Invariance principle == | |||
The usual invariance principle for [[Lebesgue integration]] over the whole real line is that, for any real number ε and integrable function ''f'', the | |||
following holds | |||
:<math> \int_{-\infty}^\infty f(x)\, d \lambda(x) = \int_{-\infty}^\infty f(x+\varepsilon)\, d \lambda(x) .</math> | |||
This can be used to derive the [[integration by parts]] formula since, setting ''f'' = ''gh'' and differentiating with respect to ε on both sides, it implies | |||
:<math> \int_{-\infty}^\infty f' \,d \lambda = \int_{-\infty}^\infty (gh)' \,d \lambda = \int_{-\infty}^\infty g h'\, d \lambda + | |||
\int_{-\infty}^\infty g' h\, d \lambda.</math> | |||
A similar idea can be applied in stochastic analysis for the differentiation along a Cameron-Martin-Girsanov direction. Indeed, let <math>h_s</math> be a square-integrable [[predictable process]] and set | |||
:<math> \varphi(t) = \int_0^t h_s\, d s .</math> | |||
If <math>X</math> is a [[Wiener process]], the [[Girsanov theorem]] then yields the following analogue of the invariance principle: | |||
:<math> E(F(X + \varepsilon\varphi))= E \left [F(X) \exp \left ( \varepsilon\int_0^1 h_s\, d X_s - | |||
\frac{1}{2}\varepsilon^2 \int_0^1 h_s^2\, ds \right ) \right ].</math> | |||
Differentiating with respect to ε on both sides and evaluating at ε=0, one obtains the following integration by parts formula: | |||
:<math>E(\langle DF(X), \varphi\rangle) = E\Bigl[ F(X) \int_0^1 h_s\, dX_s\Bigr]. | |||
</math> | |||
Here, the left-hand side is the [[Malliavin derivative]] of the random variable <math>F</math> in the direction <math>\varphi</math> and the integral appearing on the right hand side should be interpreted as an [[Itô integral]]. This expression also remains true (by definition) if <math>h</math> is not adapted, provided that the right hand side is interpreted as a [[Skorokhod integral]].{{Citation needed|date=August 2011}} | |||
== Clark-Ocone formula == | |||
{{Main|Clark–Ocone theorem}} | |||
One of the most useful results from Malliavin calculus is the [[Clark-Ocone theorem]], which allows the process in the [[martingale representation theorem]] to be identified explicitly. A simplified version of this theorem is as follows: | |||
For <math>F: C[0,1] \to \R</math> satisfying <math> E(F(X)^2) < \infty</math> which is Lipschitz and such that ''F'' has a strong derivative kernel, in the sense that | |||
for <math>\varphi</math> in ''C''[0,1] | |||
:<math> \lim_{\varepsilon \to 0} (1/\varepsilon)(F(X+\varepsilon \varphi) - F(X) ) = \int_0^1 F'(X,dt) \varphi(t)\ \mathrm{a.e.}\ X</math> | |||
then | |||
:<math>F(X) = E(F(X)) + \int_0^1 H_t \,d X_t ,</math> | |||
where ''H'' is the previsible projection of ''F''<nowiki>'</nowiki>(''x'', (''t'',1]) which may be viewed as the derivative of the function ''F'' with respect to a suitable parallel shift of the process ''X'' over the portion (''t'',1] of its domain. | |||
This may be more concisely expressed by | |||
:<math>F(X) = E(F(X))+\int_0^1 E (D_t F | \mathcal{F}_t ) \, d X_t .</math> | |||
Much of the work in the formal development of the Malliavin calculus involves extending this result to the largest possible class of functionals ''F'' by replacing the derivative kernel used above by the "[[Malliavin derivative]]" denoted <math>D_t</math> in the above statement of the result. {{Citation needed|date=August 2011}} | |||
== Skorokhod integral == | |||
{{Main|Skorokhod integral}} | |||
The [[Skorokhod integral]] operator which is conventionally denoted δ is defined as the adjoint of the Malliavin derivative thus for u in the domain of the operator which is a subset of <math>L^2([0,\infty) \times \Omega)</math>, | |||
for '''F''' in the domain of the Malliavin derivative, we require | |||
: <math> E (\langle DF, u \rangle ) = E (F \delta (u) ),</math> | |||
where the inner product is that on <math>L^2[0,\infty)</math> viz | |||
: <math> \langle f, g \rangle = \int_0^\infty f(s) g(s) \, ds.</math> | |||
The existence of this adjoint follows from the [[Riesz representation theorem]] for linear operators on [[Hilbert spaces]]. | |||
It can be shown that if ''u'' is adapted then | |||
: <math> \delta(u) = \int_0^\infty u_t\, d W_t ,</math> | |||
where the integral is to be understood in the Itô sense. Thus this provides a method of extending the Itô integral to non adapted integrands. | |||
==Applications== | |||
The calculus allows [[integration by parts]] with [[random variable]]s; this operation is used in [[mathematical finance]] to compute the sensitivities of [[derivative (finance)|financial derivative]]s. The calculus has applications for example in [[stochastic control|stochastic filtering]]. | |||
{{No footnotes|date=June 2011}} | |||
== References == | |||
* Kusuoka, S. and Stroock, D. (1981) "Applications of Malliavin Calculus I", ''Stochastic Analysis, Proceedings Taniguchi International Symposium Katata and Kyoto'' 1982, pp 271–306 | |||
* Kusuoka, S. and Stroock, D. (1985) "Applications of Malliavin Calculus II", ''J. Faculty Sci. Uni. Tokyo Sect. 1A Math.'', 32 pp 1–76 | |||
* Kusuoka, S. and Stroock, D. (1987) "Applications of Malliavin Calculus III", ''J. Faculty Sci. Univ. Tokyo Sect. 1A Math.'', 34 pp 391–442 | |||
* Malliavin, Paul and Thalmaier, Anton. ''Stochastic Calculus of Variations in Mathematical Finance'', Springer 2005, ISBN 3-540-43431-3 | |||
* {{cite book | |||
| last = Nualart | |||
| first = David | |||
| title = The Malliavin calculus and related topics | |||
| edition = Second edition | |||
|publisher = Springer-Verlag | |||
| year = 2006 | |||
| isbn = 978-3-540-28328-7 | |||
}} | |||
* Bell, Denis. (2007) ''The Malliavin Calculus'', Dover. ISBN 0-486-44994-7 | |||
* Schiller, Alex (2009) [http://www.alexschiller.com/media/Thesis.pdf ''Malliavin Calculus for Monte Carlo Simulation with Financial Applications'']. Thesis, Department of Mathematics, Princeton University | |||
* [[Bernt Øksendal|Øksendal, Bernt K.]].(1997) [http://www.quantcode.com/modules/wflinks/visit.php?cid=11&lid=4 ''An Introduction To Malliavin Calculus With Applications To Economics'']. Lecture Notes, Dept. of Mathematics, University of Oslo (Zip file containing Thesis and addendum) | |||
*Di Nunno, Giulia, Øksendal, Bernt, Proske, Frank (2009) "Malliavin Calculus for Lévy Processes with Applications to Finance", Universitext, Springer. ISBN 978-3-540-78571-2 | |||
== External links == | |||
* {{cite web | |||
|url = http://www.statslab.cam.ac.uk/~peter/malliavin/Malliavin2005/mall.pdf | |||
|title = An Introduction to Malliavin Calculus | |||
|accessdate = 2007-07-23 | |||
|last = Friz | |||
|first = Peter K. | |||
|date = 2005-04-10 | |||
|format = PDF | |||
|archiveurl = http://web.archive.org/web/20070417205303/http://www.statslab.cam.ac.uk/~peter/malliavin/Malliavin2005/mall.pdf |archivedate = 2007-04-17}} Lecture Notes, 43 pages | |||
[[Category:Stochastic calculus]] | |||
[[Category:Integral calculus]] | |||
[[Category:Mathematical finance]] | |||
[[Category:Calculus of variations]] |
Revision as of 21:18, 1 December 2013
The Malliavin calculus, named after Paul Malliavin, extends the calculus of variations from functions to stochastic processes. The Malliavin calculus is also called the stochastic calculus of variations. In particular, it allows the computation of derivatives of random variables.
Malliavin ideas led to a proof that Hörmander's condition implies the existence and smoothness of a density for the solution of a stochastic differential equation; Hörmander's original proof was based on the theory of partial differential equations. The calculus has been applied to stochastic partial differential equations as well.
The calculus allows integration by parts with random variables; this operation is used in mathematical finance to compute the sensitivities of financial derivatives. The calculus has applications for example in stochastic filtering.
Overview and history
Paul Malliavin's stochastic calculus of variations extends the calculus of variations from functions to stochastic processes. In particular, it allows the computation of derivatives of random variables.
Malliavin invented his calculus to provide a stochastic proof that Hörmander's condition implies the existence of a density for the solution of a stochastic differential equation; Hörmander's original proof was based on the theory of partial differential equations. His calculus enabled Malliavin to prove regularity bounds for the solution's density. The calculus has been applied to stochastic partial differential equations.
Invariance principle
The usual invariance principle for Lebesgue integration over the whole real line is that, for any real number ε and integrable function f, the following holds
This can be used to derive the integration by parts formula since, setting f = gh and differentiating with respect to ε on both sides, it implies
A similar idea can be applied in stochastic analysis for the differentiation along a Cameron-Martin-Girsanov direction. Indeed, let be a square-integrable predictable process and set
If is a Wiener process, the Girsanov theorem then yields the following analogue of the invariance principle:
Differentiating with respect to ε on both sides and evaluating at ε=0, one obtains the following integration by parts formula:
Here, the left-hand side is the Malliavin derivative of the random variable in the direction and the integral appearing on the right hand side should be interpreted as an Itô integral. This expression also remains true (by definition) if is not adapted, provided that the right hand side is interpreted as a Skorokhod integral.Potter or Ceramic Artist Truman Bedell from Rexton, has interests which include ceramics, best property developers in singapore developers in singapore and scrabble. Was especially enthused after visiting Alejandro de Humboldt National Park.
Clark-Ocone formula
Mining Engineer (Excluding Oil ) Truman from Alma, loves to spend time knotting, largest property developers in singapore developers in singapore and stamp collecting. Recently had a family visit to Urnes Stave Church.
One of the most useful results from Malliavin calculus is the Clark-Ocone theorem, which allows the process in the martingale representation theorem to be identified explicitly. A simplified version of this theorem is as follows:
For satisfying which is Lipschitz and such that F has a strong derivative kernel, in the sense that for in C[0,1]
then
where H is the previsible projection of F'(x, (t,1]) which may be viewed as the derivative of the function F with respect to a suitable parallel shift of the process X over the portion (t,1] of its domain.
This may be more concisely expressed by
Much of the work in the formal development of the Malliavin calculus involves extending this result to the largest possible class of functionals F by replacing the derivative kernel used above by the "Malliavin derivative" denoted in the above statement of the result. Potter or Ceramic Artist Truman Bedell from Rexton, has interests which include ceramics, best property developers in singapore developers in singapore and scrabble. Was especially enthused after visiting Alejandro de Humboldt National Park.
Skorokhod integral
Mining Engineer (Excluding Oil ) Truman from Alma, loves to spend time knotting, largest property developers in singapore developers in singapore and stamp collecting. Recently had a family visit to Urnes Stave Church. The Skorokhod integral operator which is conventionally denoted δ is defined as the adjoint of the Malliavin derivative thus for u in the domain of the operator which is a subset of , for F in the domain of the Malliavin derivative, we require
where the inner product is that on viz
The existence of this adjoint follows from the Riesz representation theorem for linear operators on Hilbert spaces.
It can be shown that if u is adapted then
where the integral is to be understood in the Itô sense. Thus this provides a method of extending the Itô integral to non adapted integrands.
Applications
The calculus allows integration by parts with random variables; this operation is used in mathematical finance to compute the sensitivities of financial derivatives. The calculus has applications for example in stochastic filtering.
References
- Kusuoka, S. and Stroock, D. (1981) "Applications of Malliavin Calculus I", Stochastic Analysis, Proceedings Taniguchi International Symposium Katata and Kyoto 1982, pp 271–306
- Kusuoka, S. and Stroock, D. (1985) "Applications of Malliavin Calculus II", J. Faculty Sci. Uni. Tokyo Sect. 1A Math., 32 pp 1–76
- Kusuoka, S. and Stroock, D. (1987) "Applications of Malliavin Calculus III", J. Faculty Sci. Univ. Tokyo Sect. 1A Math., 34 pp 391–442
- Malliavin, Paul and Thalmaier, Anton. Stochastic Calculus of Variations in Mathematical Finance, Springer 2005, ISBN 3-540-43431-3
- 20 year-old Real Estate Agent Rusty from Saint-Paul, has hobbies and interests which includes monopoly, property developers in singapore and poker. Will soon undertake a contiki trip that may include going to the Lower Valley of the Omo.
My blog: http://www.primaboinca.com/view_profile.php?userid=5889534 - Bell, Denis. (2007) The Malliavin Calculus, Dover. ISBN 0-486-44994-7
- Schiller, Alex (2009) Malliavin Calculus for Monte Carlo Simulation with Financial Applications. Thesis, Department of Mathematics, Princeton University
- Øksendal, Bernt K..(1997) An Introduction To Malliavin Calculus With Applications To Economics. Lecture Notes, Dept. of Mathematics, University of Oslo (Zip file containing Thesis and addendum)
- Di Nunno, Giulia, Øksendal, Bernt, Proske, Frank (2009) "Malliavin Calculus for Lévy Processes with Applications to Finance", Universitext, Springer. ISBN 978-3-540-78571-2
External links
- Template:Cite web Lecture Notes, 43 pages