A necessary and sufficient condition for Hardy's operator in the variable Lebesgue space
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Publication:1723897
DOI10.1155/2014/342910zbMath1470.42041OpenAlexW2081514441WikidataQ59036292 ScholiaQ59036292MaRDI QIDQ1723897
Yusuf Zeren, Farman I. Mamedov
Publication date: 14 February 2019
Published in: Abstract and Applied Analysis (Search for Journal in Brave)
Full work available at URL: https://doi.org/10.1155/2014/342910
Spaces of measurable functions ((L^p)-spaces, Orlicz spaces, Köthe function spaces, Lorentz spaces, rearrangement invariant spaces, ideal spaces, etc.) (46E30) (H^p)-spaces (42B30) Inequalities involving derivatives and differential and integral operators (26D10)
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Cites Work
- On a general weighted Hardy type inequality in the variable exponent Lebesgue spaces
- Variable Lebesgue spaces. Foundations and harmonic analysis
- On boundedness of weighted Hardy operator in \(L^{p(\cdot)}\) and regularity condition
- Lebesgue and Sobolev spaces with variable exponents
- On equivalent conditions for the general weighted Hardy type inequality in space \(L^{p(\cdot)}\)
- Regularity for elliptic equations with general growth conditions
- On a Hardy type general weighted inequality in spaces \(L ^{p(\cdot )}\)
- On a weighted inequality of Hardy type in spaces \(L^{p(\cdot)}\)
- On some variational problems
- Maximal and fractional operators in weighted \(L^{p(x)}\) spaces
- Hardy's inequality in power-type weighted \(L^{p(\cdot)}(0,\infty )\) spaces
- Hardy type inequality in variable Lebesgue spaces
- Convolution type operators inlp(x)
- A necessary and sufficient condition for Hardy's operator in
- Regularity results for a class of functionals with non-standard growth
- On the spaces \(L^{p(x)}(\Omega)\) and \(W^{m,p(x)}(\Omega)\)
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