English

Exponential approximation in variable exponent Lebesgue spaces on the real line

Functional Analysis 2022-08-30 v2 Classical Analysis and ODEs

Abstract

Present work contains a method to obtain Jackson and Stechkin type inequalities of approximation by integral functions of finite degree (IFFD) in some variable exponent Lebesgue space of real functions defined on R:=(,+)\boldsymbol{R}:=\left( -\infty ,+\infty \right) . To do this we employ a transference theorem which produce norm inequalities starting from norm inequalities in C(R)\mathcal{C}(\boldsymbol{R}), the class of bounded uniformly continuous functions defined on R\boldsymbol{R}. Let BRB\subseteq \boldsymbol{R} be a measurable set, p(x):B[1,)p\left( x\right) :B\rightarrow \lbrack 1,\infty ) be a measurable function. For the class of functions ff belonging to variable exponent Lebesgue spaces Lp(x)(B)L_{p\left( x\right) }\left(B\right) we consider difference operator (ITδ)rf()\left( I-T_{\delta }\right) ^{r}f\left( \cdot \right) under the condition that p(x)p(x) satisfies the Log H\"{o}lder continuity condition and 1ess  infxBp(x)1\leq \mathop{\rm ess \; inf}\limits\nolimits_{x\in B}p(x), ess  supxBp(x)<\mathop{\rm ess \; sup}\limits\nolimits_{x\in B}p(x)<\infty where II is the identity operator, rN:={1,2,3,}r\in \mathrm{N}:=\left\{ 1,2,3,\cdots \right\} , δ0\delta \geq 0 and \begin{equation*} T_{\delta }f\left( x\right) =\frac{1}{\delta }\int\nolimits_{0}^{\delta }f\left( x+t\right) dt ) \end{equation*} is the forward Steklov operator. We obtain main properties of difference operator (ITδ)rfp()\left\Vert \left( I-T_{\delta }\right) ^{r}f\right\Vert _{p\left( \cdot \right) } in Lp(x)(B).L_{p\left( x\right) }\left( B\right) . We give proof of direct and inverse theorems of approximation by IFFD in Lp(x)(R).L_{p\left( x\right) }\left( \boldsymbol{R}\right).

Keywords

Cite

@article{arxiv.2109.02083,
  title  = {Exponential approximation in variable exponent Lebesgue spaces on the real line},
  author = {Ramazan Akgün},
  journal= {arXiv preprint arXiv:2109.02083},
  year   = {2022}
}

Comments

26 pages, submitted

R2 v1 2026-06-24T05:41:41.391Z