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In [[mathematics]], the '''Paley–Wiener integral''' is a simple [[stochastic integral]]. When applied to [[Abstract Wiener space|classical Wiener space]], it is less general than the [[Itō integral]], but the two agree when they are both defined. | |||
The integral is named after its discoverers, [[Raymond Paley]] and [[Norbert Wiener]]. | |||
==Definition== | |||
Let ''i'' : ''H'' → ''E'' be an [[abstract Wiener space]] with abstract Wiener measure ''γ'' on ''E''. Let ''j'' : ''E''<sup>∗</sup> → ''H'' be the [[adjoint of an operator|adjoint]] of ''i''. (We have abused notation slightly: strictly speaking, ''j'' : ''E''<sup>∗</sup> → ''H''<sup>∗</sup>, but since ''H'' is a [[Hilbert space]], it is [[Isometry|isometrically isomorphic]] to its [[dual space]] ''H''<sup>∗</sup>, by the [[Riesz representation theorem]].{{Citation needed|date=September 2010}}) | |||
It can be shown that ''j'' is an [[injective function]] and has [[dense (topology)|dense]] [[image (function)|image]] in ''H''.{{Citation needed|date=September 2010}} Furthermore, it can be shown that every [[linear functional]] ''f'' ∈ ''E''<sup>∗</sup> is also [[square-integrable]]: in fact, | |||
:<math>\| f \|_{L^{2} (E, \gamma; \mathbb{R})} = \| j(f) \|_{H}</math> | |||
This defines a natural [[linear map]] from ''j''(''E''<sup>∗</sup>) to ''L''<sup>2</sup>(''E'', ''γ''; '''R'''), under which ''j''(''f'') ∈ ''j''(''E''<sup>∗</sup>) ⊆ ''H'' goes to the [[equivalence class]] [''f''] of ''f'' in ''L''<sup>2</sup>(''E'', ''γ''; '''R'''). This is well-defined since ''j'' is injective. This map is an [[isometry]], so it is [[continuous function|continuous]]. | |||
However, since a continuous linear map between [[Banach space]]s such as ''H'' and ''L''<sup>2</sup>(''E'', ''γ''; '''R''') is uniquely determined by its values on any dense subspace of its domain, there is a unique continuous linear extension ''I'' : ''H'' → ''L''<sup>2</sup>(''E'', ''γ''; '''R''') of the above natural map ''j''(''E''<sup>∗</sup>) → ''L''<sup>2</sup>(''E'', ''γ''; '''R''') to the whole of ''H''. | |||
This isometry ''I'' : ''H'' → ''L''<sup>2</sup>(''E'', ''γ''; '''R''') is known as the '''Paley–Wiener map'''. ''I''(''h''), also denoted <''h'', −><sup>∼</sup>, is a function on ''E'' and is known as the '''Paley–Wiener integral''' (with respect to ''h'' ∈ ''H''). | |||
It is important to note that the Paley–Wiener integral for a particular element ''h'' ∈ ''H'' is a [[Function (mathematics)|function]] on ''E''. The notation <''h'', ''x''><sup>∼</sup> does not really denote an inner product (since ''h'' and ''x'' belong to two different spaces), but is a convenient [[abuse of notation]] in view of the [[Cameron–Martin theorem]]. For this reason, many authors{{Citation needed|date=September 2010}} prefer to write <''h'', −><sup>∼</sup>(''x'') or ''I''(''h'')(''x'') rather than using the more compact but potentially confusing <''h'', ''x''><sup>∼</sup> notation. | |||
==See also== | |||
Other stochastic integrals: | |||
* [[Itō integral]] | |||
* [[Skorokhod integral]] | |||
* [[Stratonovich integral]] | |||
{{No footnotes|date=September 2010}} | |||
==References== | |||
*Park, C.; Skoug, D. (1988) "A Note on Paley-Wiener-Zygmund Stochastic Integrals", ''Proceedings of the American Mathematical Society', 103 (2), 591–601 {{JSTOR|2047184}} | |||
*Elworthy, D. (2008) [http://www.tjsullivan.org.uk/pdf/MA482_Stochastic_Analysis.pdf ''MA482 Stochastic Analysis''], Lecture Notes, University of Warwick (Section 6) | |||
{{DEFAULTSORT:Paley-Wiener Integral}} | |||
[[Category:Definitions of mathematical integration]] | |||
[[Category:Stochastic calculus]] | |||
Revision as of 05:02, 15 January 2014
In mathematics, the Paley–Wiener integral is a simple stochastic integral. When applied to classical Wiener space, it is less general than the Itō integral, but the two agree when they are both defined.
The integral is named after its discoverers, Raymond Paley and Norbert Wiener.
Definition
Let i : H → E be an abstract Wiener space with abstract Wiener measure γ on E. Let j : E∗ → H be the adjoint of i. (We have abused notation slightly: strictly speaking, j : E∗ → H∗, but since H is a Hilbert space, it is isometrically isomorphic to its dual space H∗, by the Riesz representation theorem.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.)
It can be shown that j is an injective function and has dense image in H.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. Furthermore, it can be shown that every linear functional f ∈ E∗ is also square-integrable: in fact,
This defines a natural linear map from j(E∗) to L2(E, γ; R), under which j(f) ∈ j(E∗) ⊆ H goes to the equivalence class [f] of f in L2(E, γ; R). This is well-defined since j is injective. This map is an isometry, so it is continuous.
However, since a continuous linear map between Banach spaces such as H and L2(E, γ; R) is uniquely determined by its values on any dense subspace of its domain, there is a unique continuous linear extension I : H → L2(E, γ; R) of the above natural map j(E∗) → L2(E, γ; R) to the whole of H.
This isometry I : H → L2(E, γ; R) is known as the Paley–Wiener map. I(h), also denoted <h, −>∼, is a function on E and is known as the Paley–Wiener integral (with respect to h ∈ H).
It is important to note that the Paley–Wiener integral for a particular element h ∈ H is a function on E. The notation <h, x>∼ does not really denote an inner product (since h and x belong to two different spaces), but is a convenient abuse of notation in view of the Cameron–Martin theorem. For this reason, many authorsPotter 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. prefer to write <h, −>∼(x) or I(h)(x) rather than using the more compact but potentially confusing <h, x>∼ notation.
See also
Other stochastic integrals:
References
- Park, C.; Skoug, D. (1988) "A Note on Paley-Wiener-Zygmund Stochastic Integrals", Proceedings of the American Mathematical Society', 103 (2), 591–601 Glazier Alfonzo from Chicoutimi, has lots of interests which include lawn darts, property developers house for sale in singapore singapore and cigar smoking. During the last year has made a journey to Cultural Landscape and Archaeological Remains of the Bamiyan Valley.
- Elworthy, D. (2008) MA482 Stochastic Analysis, Lecture Notes, University of Warwick (Section 6)