The domain of generalized difference matrix B(r, s) in the classical spaces L∞, e, and co was recently studied by Kirisci and Basar in [16]. The main goal of this article is to introduce the paranormed sequence spa...The domain of generalized difference matrix B(r, s) in the classical spaces L∞, e, and co was recently studied by Kirisci and Basar in [16]. The main goal of this article is to introduce the paranormed sequence spaces L∞(B,p), c(B,p), and co(B,p), which are more general and comprehensive than the corresponding consequences of the matrix domain of B(r, s), as well as other studies in literature. Besides this, the alpha-, beta-, and gamma-duals of the spaces L∞ (B, p), c(B, p), and co (B, p) are computed and the bases of the spaces c(B, p) and co (B, p) are constructed. The final section of this article is devoted to the characterization of the classes (λ(B, p): μ) and (μ:λ(B, p)), where λ ∈ {c, co, L∞ } and μ is any given sequence space. Additionally, the characterization of some other classes which are related to the space of Mmost convergent sequences is obtained by means of a given lemma.展开更多
文摘The domain of generalized difference matrix B(r, s) in the classical spaces L∞, e, and co was recently studied by Kirisci and Basar in [16]. The main goal of this article is to introduce the paranormed sequence spaces L∞(B,p), c(B,p), and co(B,p), which are more general and comprehensive than the corresponding consequences of the matrix domain of B(r, s), as well as other studies in literature. Besides this, the alpha-, beta-, and gamma-duals of the spaces L∞ (B, p), c(B, p), and co (B, p) are computed and the bases of the spaces c(B, p) and co (B, p) are constructed. The final section of this article is devoted to the characterization of the classes (λ(B, p): μ) and (μ:λ(B, p)), where λ ∈ {c, co, L∞ } and μ is any given sequence space. Additionally, the characterization of some other classes which are related to the space of Mmost convergent sequences is obtained by means of a given lemma.
