Schreier families and F-(almost) greedy bases
Abstract
Let F be a hereditary collection of finite subsets of N. In this paper, we introduce and characterize F-(almost) greedy bases. Given such a family F, a basis (en)n for a Banach space X is called F-greedy if there is a constant C≥slant 1 such that for each x∈ X, m ∈ N, and Gm(x), we have \|x - Gm(x)\|\ ≤slant\ C ∈f\\|x-Σn∈ Aanen\|\,:\, |A|≤slant m, A∈ F, (an)⊂ K\. Here Gm(x) is a greedy sum of x of order m, and K is the scalar field. From the definition, any F-greedy basis is quasi-greedy and so, the notion of being F-greedy lies between being greedy and being quasi-greedy. We characterize F-greedy bases as being F-unconditional, F-disjoint democratic, and quasi-greedy, thus generalizing the well-known characterization of greedy bases by Konyagin and Temlyakov. We also prove a similar characterization for F-almost greedy bases. Furthermore, we provide several examples of bases that are nontrivially F-greedy. For a countable ordinal α, we consider the case F=Sα, where Sα is the Schreier family of order α. We show that for each α, there is a basis that is Sα-greedy but is not Sα+1-greedy. In other words, we prove that none of the following implications can be reversed: for two countable ordinals α < β, quasi-greedy\ \ Sα-greedy\ \ Sβ-greedy\ \ greedy.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.