In this paper,on homogeneous groups,we study the Littlewood–Paley operators in variable exponent spaces.First,we prove that the weighted Littlewood–Paley operators are controlled by the weighted Hardy–Littlewood ma...In this paper,on homogeneous groups,we study the Littlewood–Paley operators in variable exponent spaces.First,we prove that the weighted Littlewood–Paley operators are controlled by the weighted Hardy–Littlewood maximal function,and obtain the vector-valued inequalities of the Littlewood–Paley operators,including the Lusin function,Littlewood–Paley g function and gλ* function.Second,we prove the boundedness of multilinear Littlewood–Paley gψ,λ* function.展开更多
Let (x, d,u) be a metric measure the upper doubling conditions. Under the weak space satisfying both the geometrically doubling and reverse doubling condition, the authors prove that the generalized homogeneous Litt...Let (x, d,u) be a metric measure the upper doubling conditions. Under the weak space satisfying both the geometrically doubling and reverse doubling condition, the authors prove that the generalized homogeneous Littlewood-Paley g-function gr (r ∈ [2, ∞)) is bounded from Hardy space H1(u) into L1(u). Moreover, the authors show that, if f ∈ RBMO(u), then [gr(f)]r is either infinite everywhere or finite almost everywhere, and in the latter case, [gr(f)]r belongs to RBLO(u) with the norm no more than ||f|| RBMO(u) multiplied by a positive constant which is independent of f. As a corollary, the authors obtain the boundedness of gr from RBMO(u) into RBLO(u). The vector valued Calderon-Zygmund theory over (X, d, u) is also established with details in this paper.展开更多
We study the windowed Fourier transform in the framework of Clifford analysis, which we call the Clifford windowed Fourier transform (CWFT). Based on the spectral representation of the Clifford Fourier transform (...We study the windowed Fourier transform in the framework of Clifford analysis, which we call the Clifford windowed Fourier transform (CWFT). Based on the spectral representation of the Clifford Fourier transform (CFT), we derive several important properties such as shift, modulation, reconstruction formula, orthogonality relation, isometry, and reproducing kernel. We also present an example to show the differences between the classical windowed Fourier transform (WFT) and the CWFT. Finally, as an application we establish a Heisenberg type uncertainty principle for the CWFT.展开更多
基金Supported by National Natural Science Foundation of China(Grant Nos.11471040 and 11761131002)。
文摘In this paper,on homogeneous groups,we study the Littlewood–Paley operators in variable exponent spaces.First,we prove that the weighted Littlewood–Paley operators are controlled by the weighted Hardy–Littlewood maximal function,and obtain the vector-valued inequalities of the Littlewood–Paley operators,including the Lusin function,Littlewood–Paley g function and gλ* function.Second,we prove the boundedness of multilinear Littlewood–Paley gψ,λ* function.
基金Supported by National Natural Science Foundation of China(Grant No.11471040)the Fundamental Research Funds for the Central Universities(Grant No.2014KJJCA10)
文摘Let (x, d,u) be a metric measure the upper doubling conditions. Under the weak space satisfying both the geometrically doubling and reverse doubling condition, the authors prove that the generalized homogeneous Littlewood-Paley g-function gr (r ∈ [2, ∞)) is bounded from Hardy space H1(u) into L1(u). Moreover, the authors show that, if f ∈ RBMO(u), then [gr(f)]r is either infinite everywhere or finite almost everywhere, and in the latter case, [gr(f)]r belongs to RBLO(u) with the norm no more than ||f|| RBMO(u) multiplied by a positive constant which is independent of f. As a corollary, the authors obtain the boundedness of gr from RBMO(u) into RBLO(u). The vector valued Calderon-Zygmund theory over (X, d, u) is also established with details in this paper.
文摘We study the windowed Fourier transform in the framework of Clifford analysis, which we call the Clifford windowed Fourier transform (CWFT). Based on the spectral representation of the Clifford Fourier transform (CFT), we derive several important properties such as shift, modulation, reconstruction formula, orthogonality relation, isometry, and reproducing kernel. We also present an example to show the differences between the classical windowed Fourier transform (WFT) and the CWFT. Finally, as an application we establish a Heisenberg type uncertainty principle for the CWFT.
