Sharp Remez type inequalities estimating the $L_q$ -norm of a function via its $L_p$ -norm
UDC 517.5 For any $q\geq p>0,$ $\alpha=(r+1/q)/(r+1/p),$ $f_p\in[0,\infty],$ $\beta\in[0,2\pi),$ we prove the sharp Remez type inequality $$\|x\|_q\leq\frac{\|\varphi_r+c\|_q}{\|\varphi_r+ c\|^{\alpha}_{L_p([0,2\pi]\setminus B_{y(\beta)})}}\|x\|^{\alpha}_{L_p([0,2\pi]\setminus B)}\|x^{(r)...
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| Дата: | 2022 |
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| Автори: | , , , , |
| Формат: | Стаття |
| Мова: | Українська |
| Опубліковано: |
Institute of Mathematics, NAS of Ukraine
2022
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| Онлайн доступ: | https://umj.imath.kiev.ua/index.php/umj/article/view/6836 |
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| Назва журналу: | Ukrains’kyi Matematychnyi Zhurnal |
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Репозитарії
Ukrains’kyi Matematychnyi Zhurnal| Резюме: | UDC 517.5
For any $q\geq p>0,$ $\alpha=(r+1/q)/(r+1/p),$ $f_p\in[0,\infty],$ $\beta\in[0,2\pi),$ we prove the sharp Remez type inequality $$\|x\|_q\leq\frac{\|\varphi_r+c\|_q}{\|\varphi_r+ c\|^{\alpha}_{L_p([0,2\pi]\setminus B_{y(\beta)})}}\|x\|^{\alpha}_{L_p([0,2\pi]\setminus B)}\|x^{(r)}\|^{1-\alpha}_\infty$$ for $2\pi$-periodic functions $x\in L_\infty^r$ that have zeros and satisfy the condition \begin{gather}\|x_+\|_p\,\|x_-\|^{-1}_p=f_p,\quad (1)\end{gather} where $\varphi_r$ is Euler's perfect spline of order $r;$ the number $c$ is chosen in such a way that the function $x=\varphi_r+c$ satisfies the condition (1); $B$ is an arbitrary measurable set such that $\mu B\leq\beta\left(\|\varphi_r+c\|_p\left\|x^{(r)}\right\|_\infty\|x\|^{-1}_p\right)^{-1/(r+1/p)},$ the set $B_{y(\beta)}$ is defined by $B_{y(\beta)}:=\{t\in[0,2\pi]\colon|\varphi_r(t)+c|>y(\beta)\},$ and moreover, $\mu B_{y(\beta)}=\beta.$
We also establish sharp Remez type inequalities of various metrics for trigonometric polynomials and for polynomial splines satisfying (1).
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| DOI: | 10.37863/umzh.v74i5.6836 |