共查询到20条相似文献,搜索用时 46 毫秒
1.
Let j{\varphi} be an analytic self-map of the unit disk
\mathbb D{\mathbb{D}},
H(\mathbb D){H(\mathbb{D})} the space of analytic functions on
\mathbb D{\mathbb{D}} and
g ? H(\mathbb D){g \in H(\mathbb{D})}. The boundedness and compactness of the operator DCj : H¥ ? Z{DC_\varphi : H^\infty \rightarrow { \mathcal Z}} are investigated in this paper. 相似文献
2.
A Toeplitz operator TfT_\phi with symbol f\phi in
L¥(\mathbb D)L^{\infty}({\mathbb{D}}) on the Bergman space
A2(\mathbb D)A^{2}({\mathbb{D}}), where
\mathbb D\mathbb{D} denotes the open unit disc, is radial if f( z) = f(| z|)\phi(z) = \phi(|z|) a.e. on
\mathbb D\mathbb{D}. In this paper, we consider the numerical ranges of such operators. It is shown that all finite line segments, convex hulls
of analytic images of
\mathbb D\mathbb{D} and closed convex polygonal regions in the plane are the numerical ranges of radial Toeplitz operators. On the other hand,
Toeplitz operators TfT_\phi with f\phi harmonic on
\mathbb D\mathbb{D} and continuous on
[`(\mathbb D)]{\overline{\mathbb{D}}} and radial Toeplitz operators are convexoid, but certain compact quasinilpotent Toeplitz operators are not. 相似文献
3.
Fourier series are considered on the one-dimensional torus for the space of periodic distributions that are the distributional
derivative of a continuous function. This space of distributions is denoted
Ac(\mathbb T){\mathcal{A}}_{c}(\mathbb{T}) and is a Banach space under the Alexiewicz norm,
|| f|| \mathbbT=sup |I| £ 2p|ò I f|\|f\|_{\mathbb{T}}=\sup_{|I|\leq2\pi}|\int_{I} f|, the supremum being taken over intervals of length not exceeding 2 π. It contains the periodic functions integrable in the sense of Lebesgue and Henstock–Kurzweil. Many of the properties of
L
1 Fourier series continue to hold for this larger space, with the L
1 norm replaced by the Alexiewicz norm. The Riemann–Lebesgue lemma takes the form [^( f)]( n)= o( n)\hat{f}(n)=o(n) as | n|→∞. The convolution is defined for
f ? Ac(\mathbb T)f\in{\mathcal{A}}_{c}(\mathbb{T}) and g a periodic function of bounded variation. The convolution commutes with translations and is commutative and associative.
There is the estimate
|| f* g|| ¥ £ || f|| \mathbbT || g|| BV\|f\ast g\|_{\infty}\leq\|f\|_{\mathbb{T}} \|g\|_{\mathcal{BV}}. For
g ? L1(\mathbb T)g\in L^{1}(\mathbb{T}),
|| f* g|| \mathbbT £ || f|| \mathbb T || g|| 1\|f\ast g\|_{\mathbb{T}}\leq\|f\|_{\mathbb {T}} \|g\|_{1}. As well, [^( f* g)]( n)=[^( f)]( n) [^( g)]( n)\widehat{f\ast g}(n)=\hat{f}(n) \hat{g}(n). There are versions of the Salem–Zygmund–Rudin–Cohen factorization theorem, Fejér’s lemma and the Parseval equality. The
trigonometric polynomials are dense in
Ac(\mathbb T){\mathcal{A}}_{c}(\mathbb{T}). The convolution of f with a sequence of summability kernels converges to f in the Alexiewicz norm. Let D
n
be the Dirichlet kernel and let
f ? L1(\mathbb T)f\in L^{1}(\mathbb{T}). Then
|| Dn* f- f|| \mathbbT?0\|D_{n}\ast f-f\|_{\mathbb{T}}\to0 as n→∞. Fourier coefficients of functions of bounded variation are characterized. The Appendix contains a type of Fubini theorem. 相似文献
4.
Let L be a divergence form elliptic operator with complex bounded measurable coefficients, ω a positive concave function on (0, ∞) of strictly critical lower type p ω ∈(0, 1] and ρ( t) = t ?1/ ω ?1( t ?1) for ${t\in (0,\infty).}Let L be a divergence form elliptic operator with complex bounded measurable coefficients, ω a positive concave function on (0, ∞) of strictly critical lower type p
ω
∈(0, 1] and ρ(t) = t
−1/ω
−1(t
−1) for t ? (0,¥).{t\in (0,\infty).} In this paper, the authors introduce the generalized VMO spaces
VMOr, L(\mathbb Rn){{\mathop{\rm VMO}_ {\rho, L}({\mathbb R}^n)}} associated with L, and characterize them via tent spaces. As applications, the authors show that
(VMOr,L (\mathbb Rn))*=Bw,L*(\mathbb Rn){({\rm VMO}_{\rho,L} ({\mathbb R}^n))^\ast=B_{\omega,L^\ast}({\mathbb R}^n)}, where L
* denotes the adjoint operator of L in
L2(\mathbb Rn){L^2({\mathbb R}^n)} and
Bw,L*(\mathbb Rn){B_{\omega,L^\ast}({\mathbb R}^n)} the Banach completion of the Orlicz–Hardy space
Hw,L*(\mathbb Rn){H_{\omega,L^\ast}({\mathbb R}^n)}. Notice that ω(t) = t
p
for all t ? (0,¥){t\in (0,\infty)} and p ? (0,1]{p\in (0,1]} is a typical example of positive concave functions satisfying the assumptions. In particular, when p = 1, then ρ(t) ≡ 1 and
(VMO1, L(\mathbb Rn))*=HL*1(\mathbb Rn){({\mathop{\rm VMO}_{1, L}({\mathbb R}^n)})^\ast=H_{L^\ast}^1({\mathbb R}^n)}, where
HL*1(\mathbb Rn){H_{L^\ast}^1({\mathbb R}^n)} was the Hardy space introduced by Hofmann and Mayboroda. 相似文献
5.
In this paper we consider the following problem $\left\{\begin{array}{l} -\Delta u=u-\left|u\right|^{-2\theta}u+f \\u \in H^1(\mathbb{R}^N)\cap L^{2(1-\theta)}(\mathbb{R}^N)\end{array}\right.$ ${f \in L^2(\mathbb{R}^N)\cap L^\frac{2(1-\theta)}{1-2\theta}(\mathbb{R}^N),\, N\geq 3,\, f\geq 0,\, f \neq 0}In this paper we consider the following problem
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{l -Du=u-|u|-2qu+f u ? H1(\mathbbRN)?L2(1-q)(\mathbbRN)\left\{\begin{array}{l} -\Delta u=u-\left|u\right|^{-2\theta}u+f \\u \in H^1(\mathbb{R}^N)\cap L^{2(1-\theta)}(\mathbb{R}^N)\end{array}\right. 相似文献
6.
Let Ω
i
and Ω
o
be two bounded open subsets of
\mathbb Rn{{\mathbb{R}}^{n}} containing 0. Let G
i
be a (nonlinear) map from
?W i×\mathbb Rn{\partial\Omega^{i}\times {\mathbb{R}}^{n}} to
\mathbb Rn{{\mathbb{R}}^{n}} . Let a
o
be a map from ∂Ω
o
to the set
Mn(\mathbb R){M_{n}({\mathbb{R}})} of n × n matrices with real entries. Let g be a function from ∂Ω
o
to
\mathbb Rn{{\mathbb{R}}^{n}} . Let γ be a positive valued function defined on a right neighborhood of 0 in the real line. Let T be a map from
]1-(2/ n),+¥[× Mn(\mathbb R){]1-(2/n),+\infty[\times M_{n}({\mathbb{R}})} to
Mn(\mathbb R){M_{n}({\mathbb{R}})} . Then we consider the problem
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$\left\{ {ll} {{\rm div}}\, (T(\omega,Du))=0 &\quad {{\rm in}} \;\Omega^{o} \setminus\epsilon{{\rm cl}} \Omega^{i},\\ -T(\omega,Du(x))\nu_{\epsilon\Omega^{i}}(x)=\frac{1}{\gamma(\epsilon)}G^{i}({x}/{\epsilon}, \gamma(\epsilon)\epsilon^{-1} ({\rm log} \, \epsilon)^{-\delta_{2,n}} u(x)) & \quad \forall x \in \epsilon\partial\Omega^{i},\\ T(\omega, Du(x)) \nu^{o}(x)=a^{o}(x)u(x)+g(x) & \quad \forall x \in \partial \Omega^{o}, \right.$\left\{ \begin{array}{ll} {{\rm div}}\, (T(\omega,Du))=0 &\quad {{\rm in}} \;\Omega^{o} \setminus\epsilon{{\rm cl}} \Omega^{i},\\ -T(\omega,Du(x))\nu_{\epsilon\Omega^{i}}(x)=\frac{1}{\gamma(\epsilon)}G^{i}({x}/{\epsilon}, \gamma(\epsilon)\epsilon^{-1} ({\rm log} \, \epsilon)^{-\delta_{2,n}} u(x)) & \quad \forall x \in \epsilon\partial\Omega^{i},\\ T(\omega, Du(x)) \nu^{o}(x)=a^{o}(x)u(x)+g(x) & \quad \forall x \in \partial \Omega^{o}, \end{array} \right. 相似文献
8.
Cauchy’s problem for a generalization of the KdV–Burgers equation is considered in Sobolev spaces
H1(\mathbb R){H^1(\mathbb{R})} and
H2(\mathbb R){H^2(\mathbb{R})}. We study its local and global solvability and the asymptotic behavior of solutions (in terms of the global attractors).
The parabolic regularization technique is used in this paper which allows us to extend the strong regularity properties and
estimates of solutions of the fourth order parabolic approximations onto their third order limit—the generalized Korteweg–de
Vries–Burgers (KdVB) equation. For initial data in
H2(\mathbb R){H^2(\mathbb{R})} we study the notion of viscosity solutions to KdVB, while for the larger
H1(\mathbb R){H^1(\mathbb{R})} phase space we introduce weak solutions to that problem. Finally, thanks to our general assumptions on the nonlinear term f guaranteeing that the global attractor is usually nontrivial (i.e., not reduced to a single stationary solution), we study
an upper semicontinuity property of the family of global attractors corresponding to parabolic regularizations when the regularization
parameter e{\epsilon} tends to 0 + (which corresponds the passage to the KdVB equation). 相似文献
9.
Let a\alpha and b\beta be bounded measurable functions on the unit circle T. The singular integral operator Sa, bS_{\alpha ,\,\beta } is defined by Sa, b f = a Pf + b Qf( f ? L2 ( T))S_{\alpha ,\,\beta } f = \alpha Pf + \beta Qf(f \in L^2 (T)) where P is an analytic projection and Q is a co-analytic projection. In the previous paper, the norm of Sa, bS_{\alpha ,\,\beta } was calculated in general, using a,b\alpha ,\beta and a[`(b)] + H¥\alpha \bar {\beta } + H^\infty where H¥H^\infty is a Hardy space in L¥ ( T).L^\infty (T). In this paper, the essential norm || Sa, b || e\Vert S_{\alpha ,\,\beta } \Vert _e of Sa, bS_{\alpha ,\,\beta } is calculated in general, using a[`(b)] + H¥ + C\alpha \bar {\beta } + H^\infty + C where C is a set of all continuous functions on T. Hence if a[`(b)]\alpha \bar {\beta } is in H¥ + CH^\infty + C then || Sa, b || e = max(||a|| ¥ , ||b|| ¥ ).\Vert S_{\alpha ,\,\beta } \Vert _e = \max (\Vert \alpha \Vert _\infty , \Vert \beta \Vert _\infty ). This gives a known result when a, b\alpha , \beta are in C. 相似文献
10.
We study the well-posedness of the fractional differential equations with infinite delay ( P
2): Da u( t)= Au( t)+ò t-¥a( t- s) Au( s) ds + f( t), (0 £ t £ 2p){D^\alpha u(t)=Au(t)+\int^{t}_{-\infty}a(t-s)Au(s)ds + f(t), (0\leq t \leq2\pi)}, where A is a closed operator in a Banach space ${X, \alpha > 0, a\in {L}^1(\mathbb{R}_+)}${X, \alpha > 0, a\in {L}^1(\mathbb{R}_+)} and f is an X-valued function. Under suitable assumptions on the parameter α and the Laplace transform of a, we completely characterize the well-posedness of ( P
2) on Lebesgue-Bochner spaces
Lp(\mathbb T, X){L^p(\mathbb{T}, X)} and periodic Besov spaces
B p,qs(\mathbb T, X){{B} _{p,q}^s(\mathbb{T}, X)} . 相似文献
11.
We show that if A is a closed analytic subset of
\mathbb Pn{\mathbb{P}^n} of pure codimension q then
Hi(\mathbb Pn\ A, F){H^i(\mathbb{P}^n{\setminus} A,{\mathcal F})} are finite dimensional for every coherent algebraic sheaf F{{\mathcal F}} and every
i 3 n-[\frac n-1 q]{i\geq n-\left[\frac{n-1}{q}\right]} . If
n-1 3 2 q we show that Hn-2(\mathbb Pn\ A, F)=0{n-1\geq 2q\,{\rm we show that}\, H^{n-2}(\mathbb{P}^n{\setminus} A,{\mathcal F})=0} . 相似文献
12.
The Cauchy problem for a nonlocal perturbation of KdV equation is considered by the Fourier restriction norm method. Local
well-posedness for initial data in $H^s({\mathbb{R}})(s > -\frac{3}{4})$H^s({\mathbb{R}})(s > -\frac{3}{4}) and global results for data in
L2(\mathbb R)L^2({\mathbb{R}}) are obtained. 相似文献
13.
Let T be a C0–contraction on a separable Hilbert space. We assume that IH − T* T is compact. For a function f holomorphic in the unit disk
\mathbb D{\mathbb{D}} and continuous on
[`(\mathbb D)]\overline{{\mathbb{D}}}, we show that f( T) is compact if and only if f vanishes on
s( T)?\mathbb T\sigma(T)\cap{\mathbb{T}}, where σ( T) is the spectrum of T and
\mathbb T{\mathbb{T}} the unit circle. If f is just a bounded holomorphic function on
\mathbb D{\mathbb{D}}, we prove that f( T) is compact if and only if lim n? ¥|| Tnf( T)|| = 0\lim\limits_{n\rightarrow \infty}\|T^{n}f(T)\| = 0. 相似文献
14.
We establish the maximal regularity for nonautonomous Ornstein–Uhlenbeck operators in L p -spaces with respect to a family of invariant measures, where ${p \in (1, +\infty)}We establish the maximal regularity for nonautonomous Ornstein–Uhlenbeck operators in
L
p
-spaces with respect to a family of invariant measures, where p ? (1, +¥){p \in (1, +\infty)} . This result follows from the maximal L
p
-regularity for a class of elliptic operators with unbounded, time-dependent drift coefficients and potentials acting on
Lp(\mathbbRN ){L^{p}(\mathbb{R}^{N} )} with Lebesgue measure. 相似文献
15.
Let ${s,\,\tau\in\mathbb{R}}Let
s, t ? \mathbbR{s,\,\tau\in\mathbb{R}} and q ? (0,¥]{q\in(0,\infty]} . We introduce Besov-type spaces
[(B)\dot]s, tp, q(\mathbbRn){{{{\dot B}^{s,\,\tau}_{p,\,q}(\mathbb{R}^{n})}}} for p ? (0, ¥]{p\in(0,\,\infty]} and Triebel–Lizorkin-type spaces
[(F)\dot]s, tp, q(\mathbbRn) for p ? (0, ¥){{{{\dot F}^{s,\,\tau}_{p,\,q}(\mathbb{R}^{n})}}\,{\rm for}\, p\in(0,\,\infty)} , which unify and generalize the Besov spaces, Triebel–Lizorkin spaces and Q spaces. We then establish the j{\varphi} -transform characterization of these new spaces in the sense of Frazier and Jawerth. Using the j{\varphi} -transform characterization of
[(B)\dot]s, tp, q(\mathbbRn) and [(F)\dot]s, tp, q(\mathbbRn){{{{\dot B}^{s,\,\tau}_{p,\,q}(\mathbb{R}^{n})}\, {\rm and}\, {{\dot F}^{s,\,\tau}_{p,\,q}(\mathbb{R}^{n})}}} , we obtain their embedding and lifting properties; moreover, for appropriate τ, we also establish the smooth atomic and
molecular decomposition characterizations of
[(B)\dot]s, tp, q(\mathbbRn) and [(F)\dot]s, tp, q(\mathbbRn){{{{\dot B}^{s,\,\tau}_{p,\,q}(\mathbb{R}^{n})}\,{\rm and}\, {{\dot F}^{s,\,\tau}_{p,\,q}(\mathbb{R}^{n})}}} . For
s ? \mathbbR{s\in\mathbb{R}} , p ? (1, ¥), q ? [1, ¥){p\in(1,\,\infty), q\in[1,\,\infty)} and
t ? [0, \frac1(max{p, q})¢]{\tau\in[0,\,\frac{1}{(\max\{p,\,q\})'}]} , via the Hausdorff capacity, we introduce certain Hardy–Hausdorff spaces
B[(H)\dot]s, tp, q(\mathbbRn){{{{B\dot{H}^{s,\,\tau}_{p,\,q}(\mathbb{R}^{n})}}}} and prove that the dual space of
B[(H)\dot]s, tp, q(\mathbbRn){{{{B\dot{H}^{s,\,\tau}_{p,\,q}(\mathbb{R}^{n})}}}} is just
[(B)\dot]-s, tp¢, q¢(\mathbbRn){\dot{B}^{-s,\,\tau}_{p',\,q'}(\mathbb{R}^{n})} , where t′ denotes the conjugate index of t ? (1,¥){t\in (1,\infty)} . 相似文献
16.
We consider the space
A(\mathbb T)A(\mathbb{T}) of all continuous functions f on the circle
\mathbb T\mathbb{T} such that the sequence of Fourier coefficients
[^( f)] = { [^( f)]( k ), k ? \mathbb Z }\hat f = \left\{ {\hat f\left( k \right), k \in \mathbb{Z}} \right\} belongs to l
1(ℤ). The norm on
A(\mathbb T)A(\mathbb{T}) is defined by
|| f || A(\mathbbT) = || [^( f)] || l1 (\mathbbZ)\left\| f \right\|_{A(\mathbb{T})} = \left\| {\hat f} \right\|_{l^1 (\mathbb{Z})}. According to the well-known Beurling-Helson theorem, if
f:\mathbb T ? \mathbb T\phi :\mathbb{T} \to \mathbb{T} is a continuous mapping such that
|| einf || A(\mathbbT) = O(1)\left\| {e^{in\phi } } \right\|_{A(\mathbb{T})} = O(1), n ∈ ℤ then φ is linear. It was conjectured by Kahane that the same conclusion about φ is true under the assumption that
|| einf || A(\mathbbT) = o( log| n | )\left\| {e^{in\phi } } \right\|_{A(\mathbb{T})} = o\left( {\log \left| n \right|} \right). We show that if $\left\| {e^{in\phi } } \right\|_{A(\mathbb{T})} = o\left( {\left( {{{\log \log \left| n \right|} \mathord{\left/
{\vphantom {{\log \log \left| n \right|} {\log \log \log \left| n \right|}}} \right.
\kern-\nulldelimiterspace} {\log \log \log \left| n \right|}}} \right)^{1/12} } \right)$\left\| {e^{in\phi } } \right\|_{A(\mathbb{T})} = o\left( {\left( {{{\log \log \left| n \right|} \mathord{\left/
{\vphantom {{\log \log \left| n \right|} {\log \log \log \left| n \right|}}} \right.
\kern-\nulldelimiterspace} {\log \log \log \left| n \right|}}} \right)^{1/12} } \right), then φ is linear. 相似文献
17.
In this work we prove that the solutions
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u ? Lq(-T, 0,H1,q(W,\mathbbRN)) ?C0,l([`(Q)],\mathbbRN)u\in L^{q}(-T, 0,H^{1,q}(\Omega,\mathbb{R}^{N})) \cap C^{0,\lambda}(\overline{Q},\mathbb{R}^{N}) 相似文献
18.
Given
W ì \mathbb Z+3\Omega \subset {\mathbb{Z}}_{+}^{3}, we discuss a necessary and sufficient condition that the triple Hilbert transform associated with any polynomial of the
form ($t_1, t_2, t_3,\sum_{m
\in \Omega} a_{m} t^m$t_1, t_2, t_3,\sum_{m
\in \Omega} a_{m} t^m) is bounded in
Lp(\mathbb R4)L^p({\mathbb{R}}^4). 相似文献
19.
Harold Widom proved in 1966 that the spectrum of a Toeplitz operator T( a) acting on the Hardy space
Hp(\mathbb T)H^p({\mathbb{T}}) over the unit circle
\mathbb T{\mathbb{T}} is a connected subset of the complex plane for every bounded measurable symbol a and 1 < p < ∞. In 1972, Ronald Douglas established the connectedness of the essential spectrum of T( a) on
H2(\mathbb T)H^2({\mathbb{T}}). We show that, as was suspected, these results remain valid in the setting of Hardy spaces Hp(Γ, w), 1 < p < ∞, with general Muckenhoupt weights w over arbitrary Carleson curves Γ. 相似文献
20.
It is shown that for any t, 0< t<∞, there is a Jordan arc Γ with endpoints 0 and 1 such that
G\{1} í \mathbb D:={ z:| z| < 1}\Gamma\setminus\{1\}\subseteq\mathbb{D}:=\{z:|z|<1\}
and with the property that the analytic polynomials are dense in the Bergman space
\mathbb At(\mathbb D\G)\mathbb{A}^{t}(\mathbb{D}\setminus\Gamma)
. It is also shown that one can go further in the Hardy space setting and find such a Γ that is in fact the graph of a continuous
real-valued function on [0,1], where the polynomials are dense in
Ht(\mathbb D\G)H^{t}(\mathbb{D}\setminus\Gamma)
; improving upon a result in an earlier paper. 相似文献
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