In mathematics, the Bochner integral, named for Salomon Bochner, extends the definition of Lebesgue integral to functions that take values in a Banach space, as the limit of integrals of simple functions.

Definition

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Let   be a measure space, and   be a Banach space. The Bochner integral of a function   is defined in much the same way as the Lebesgue integral. First, define a simple function to be any finite sum of the form   where the   are disjoint members of the  -algebra   the   are distinct elements of   and χE is the characteristic function of   If   is finite whenever   then the simple function is integrable, and the integral is then defined by   exactly as it is for the ordinary Lebesgue integral.

A measurable function   is Bochner integrable if there exists a sequence of integrable simple functions   such that   where the integral on the left-hand side is an ordinary Lebesgue integral.

In this case, the Bochner integral is defined by  

It can be shown that the sequence   is a Cauchy sequence in the Banach space   hence the limit on the right exists; furthermore, the limit is independent of the approximating sequence of simple functions   These remarks show that the integral is well-defined (i.e independent of any choices). It can be shown that a function is Bochner integrable if and only if it lies in the Bochner space  

Properties

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Elementary properties

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Many of the familiar properties of the Lebesgue integral continue to hold for the Bochner integral. Particularly useful is Bochner's criterion for integrability, which states that if   is a measure space, then a Bochner-measurable function   is Bochner integrable if and only if  

Here, a function   is called Bochner measurable if it is equal  -almost everywhere to a function   taking values in a separable subspace   of  , and such that the inverse image   of every open set   in   belongs to  . Equivalently,   is the limit  -almost everywhere of a sequence of countably-valued simple functions.

Linear operators

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If   is a continuous linear operator between Banach spaces   and  , and   is Bochner integrable, then it is relatively straightforward to show that   is Bochner integrable and integration and the application of   may be interchanged:   for all measurable subsets  .

A non-trivially stronger form of this result, known as Hille's theorem, also holds for closed operators.[1] If   is a closed linear operator between Banach spaces   and   and both   and   are Bochner integrable, then   for all measurable subsets  .

Dominated convergence theorem

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A version of the dominated convergence theorem also holds for the Bochner integral. Specifically, if   is a sequence of measurable functions on a complete measure space tending almost everywhere to a limit function  , and if   for almost every  , and  , then   as   and   for all  .

If   is Bochner integrable, then the inequality   holds for all   In particular, the set function   defines a countably-additive  -valued vector measure on   which is absolutely continuous with respect to  .

Radon–Nikodym property

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An important fact about the Bochner integral is that the Radon–Nikodym theorem fails to hold in general, and instead is a property (the Radon–Nikodym property) defining an important class of ″nice″ Banach spaces.

Specifically, if   is a measure on   then   has the Radon–Nikodym property with respect to   if, for every countably-additive vector measure   on   with values in   which has bounded variation and is absolutely continuous with respect to   there is a  -integrable function   such that   for every measurable set  [2]

The Banach space   has the Radon–Nikodym property if   has the Radon–Nikodym property with respect to every finite measure.[2] Equivalent formulations include:

  • Bounded discrete-time martingales in   converge a.s.[3]
  • Functions of bounded-variation into   are differentiable a.e.[4]
  • For every bounded  , there exists   and   such that   has arbitrarily small diameter.[3]

It is known that the space   has the Radon–Nikodym property, but   and the spaces     for   an open bounded subset of   and   for   an infinite compact space, do not.[5] Spaces with Radon–Nikodym property include separable dual spaces (this is the Dunford–Pettis theorem)[citation needed] and reflexive spaces, which include, in particular, Hilbert spaces.[2]

See also

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References

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  1. ^ Diestel, Joseph; Uhl, Jr., John Jerry (1977). Vector Measures. Mathematical Surveys. American Mathematical Society. doi:10.1090/surv/015. (See Theorem II.2.6)
  2. ^ a b c Bárcenas, Diómedes (2003). "The Radon–Nikodym Theorem for Reflexive Banach Spaces" (PDF). Divulgaciones Matemáticas. 11 (1): 55–59 [pp. 55–56].
  3. ^ a b Bourgin 1983, pp. 31, 33. Thm. 2.3.6-7, conditions (1,4,10).
  4. ^ Bourgin 1983, p. 16. "Early workers in this field were concerned with the Banach space property that each X-valued function of bounded variation on [0,1] be differentiable almost surely. It turns out that this property (known as the Gelfand-Fréchet property) is also equivalent to the RNP [Radon-Nikodym Property]."
  5. ^ Bourgin 1983, p. 14.