In [4], a new family W(L^p(x), Lm^q) of Wiener amalgam spaces was defined and investigated some properties of these spaces, where local component is a variable exponent Lebesgue space L^p(x) (R) and the global...In [4], a new family W(L^p(x), Lm^q) of Wiener amalgam spaces was defined and investigated some properties of these spaces, where local component is a variable exponent Lebesgue space L^p(x) (R) and the global component is a weighted Lebesgue space Lm^q (R). This present paper is a sequel to our work [4]. In Section 2, we discuss necessary and sufficient conditions for the equality W (L^p(x), Lm^q) = L^q (R). Later we give some characterization of Wiener amalgam space W (L^p(x), Lm^q).In Section 3 we define the Wiener amalgam space W (FL^p(x), Lm^q) and investigate some properties of this space, where FL^p(x) is the image of L^p(x) under the Fourier transform. In Section 4, we discuss boundedness of the Hardy- Littlewood maximal operator between some Wiener amalgam spaces.展开更多
文摘In [4], a new family W(L^p(x), Lm^q) of Wiener amalgam spaces was defined and investigated some properties of these spaces, where local component is a variable exponent Lebesgue space L^p(x) (R) and the global component is a weighted Lebesgue space Lm^q (R). This present paper is a sequel to our work [4]. In Section 2, we discuss necessary and sufficient conditions for the equality W (L^p(x), Lm^q) = L^q (R). Later we give some characterization of Wiener amalgam space W (L^p(x), Lm^q).In Section 3 we define the Wiener amalgam space W (FL^p(x), Lm^q) and investigate some properties of this space, where FL^p(x) is the image of L^p(x) under the Fourier transform. In Section 4, we discuss boundedness of the Hardy- Littlewood maximal operator between some Wiener amalgam spaces.
