Generalized Ordinary Differential Equations in Abstract Spaces and Applications. Группа авторов

Generalized Ordinary Differential Equations in Abstract Spaces and Applications

(1.18) and by the Riemann integrability of beta left-parenthesis dot right-parenthesis f prime left-parenthesis dot right-parenthesis

. Finally, (1.13) follows from (1.16) and (1.17) and the proof is complete.

1.3.5 A Convergence Theorem

As the last result of this introductory chapter, we mention a convergence theorem for Perron–Stieltjes integrals. Such result is used in Chapter 3. A proof of it can be found in [180, Theorem 2.2].

Theorem 1.88: Consider functions and , for . Suppose

limit Underscript n right-arrow infinity Endscripts parallel-to f Subscript n Baseline minus f parallel-to equals 0 comma limit Underscript n right-arrow infinity Endscripts parallel-to alpha Subscript n Baseline minus alpha parallel-to equals 0 and sup Underscript n element-of double-struck upper N Endscripts v a r Subscript a Superscript b Baseline left-parenthesis alpha Subscript n Baseline right-parenthesis less-than infinity period

Then

limit Underscript n right-arrow infinity Endscripts left-parenthesis sup Underscript t element-of left-bracket a comma b right-bracket Endscripts vertical-bar vertical-bar vertical-bar vertical-bar integral integral at minus minus times times times d of alpha alpha n left-parenthesis right-parenthesis s of ffn left-parenthesis right-parenthesis s integral integral at times times times d of alpha alpha left-parenthesis right-parenthesis s of ff left-parenthesis right-parenthesis s right-parenthesis equals 0 period

Appendix 1.A: The McShane Integral

The integrals introduced by J. Kurzweil [152] and independently by R. Henstock [118] in the late 1950s are equivalent to the restricted Denjoy integral and the Perron integral for integrands taking values in double-struck upper R (see [108], for instance). In particular, the definitions of the so-called ”Kurzweil–Henstock” integrals are based on Riemannian sums, and are therefore easy to deal with even by undergraduate students. Not only that, but the Kurzweil–Henstock–Denjoy–Perron integral encompasses the integrals of Newton, Riemann, and Lebesgue.

In 1969, E. J. McShane (see [173, 174]) showed that a small change in the subdivision process of the domain of integration within the Kurzweil–Henstock (or Perron) integral leads to the Lebesgue integral. This is a very nice finding, since now the Lebesgue integral can be taught by presenting its Riemannian definition straightforwardly and, then, obtaining immediately some very interesting properties such as the linearity of the Lebesgue integral which comes directly from the fact that the Riemann sum can be split into two sums. The monotone convergence theorem for the Lebesgue integral is another example of a result which is naturally obtained from its equivalent definition due to McShane.

The Kurzweil integral and the variational Henstock integral can be extended to Banach space-valued functions as well as to the evaluation of integrands over unbounded intervals. The extension of the McShane integral, proposed by R. A. Gordon (see [107]) to Banach space-valued functions, gives a more general integral than that of Bochner–Lebesgue. As a matter of fact, the idea of McShane into the definition due to Kurzweil enlarges the class of Bochner–Lebesgue integrals.

On the other hand, when the idea of McShane is employed in the variational Henstock integral, one gets precisely the Bochner–Lebesgue integral. This interesting fact was proved by W. Congxin and Y. Xiabo in [47] and, independently, by C. S. Hönig in [131]. Later, L. Di Piazza and K. Musal generalized this result (see [55]). We clarify here that unlike the proof by Congxin and Xiabo, based on the Fréchet differentiability of the Bochner–Lebesgue integral, Hönig's idea to prove the equivalence between the Bochner–Lebesgue integral and the integral we refer to as Henstock–McShane integral uses the fact that the indefinite integral of a Henstock–McShane integrable function is itself a function of bounded variation and the fact that absolute Henstock integrable functions are also functions of bounded variation. In this way, the proof provided in [131] becomes simpler. We reproduce it in the next lines, since reference [131] is not easily available. We also refer to [73] for some details.

Definition 1.89: We say that a function f colon left-bracket a comma b right-bracket right-arrow upper X is Bochner–Lebesgue integrable (we write f element-of script upper L 1 left-parenthesis left-bracket a comma b right-bracket comma upper X right-parenthesis ), if there exists a sequence left-brace f Subscript n Baseline right-brace Subscript n element-of double-struck upper N of simple functions, f Subscript n Baseline colon left-bracket a comma b right-bracket right-arrow upper X , , such that

1 almost everywhere (i.e. for almost every ), and

2 .

With the notation of Definition 1.89, we define

integral Subscript a Superscript b Baseline f left-parenthesis t right-parenthesis d t equals limit Underscript n right-arrow infinity Endscripts integral Subscript a Superscript b Baseline f Subscript n Baseline left-parenthesis t right-parenthesis d t and vertical-bar vertical-bar vertical-bar vertical-bar f Subscript 1 Baseline equals integral Subscript a Superscript b Baseline vertical-bar vertical-bar vertical-bar vertical-bar of ff left-parenthesis right-parenthesis t d t period

Then, the space of all equivalence classes of Bochner–Lebesgue integrable functions, equipped with the norm vertical-bar vertical-bar vertical-bar vertical-bar f Subscript 1 , is complete.

The next definition can be found in [239], for instance.

Definition 1.90: We say that a function f colon left-bracket a comma b right-bracket right-arrow upper X is measurable, whenever there is a sequence of simple functions f Subscript n Baseline colon left-bracket a comma b right-bracket right-arrow upper X such that f Subscript n Baseline right-arrow f almost everywhere. When this is the case,

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