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＜電子ブック＞
Fatou Type Theorems : Maximal Functions and Approach Regions / by F. Di Biase
(Progress in Mathematics. ISSN:2296505X ; 147)

版	1st ed. 1998.
出版者	(Boston, MA : Birkhäuser Boston : Imprint: Birkhäuser)
出版年	1998
本文言語	英語
大きさ	XII, 154 p : online resource
著者標目	*Di Biase, F author SpringerLink (Online service)
件　名	LCSH:Functions of complex variables LCSH:Mathematical analysis FREE:Functions of a Complex Variable FREE:Analysis FREE:Several Complex Variables and Analytic Spaces
一般注記	I Background -- 1 Prelude -- 2 Preliminary Results -- 3 The Geometric Contexts -- II Exotic Approach Regions -- 4 Approach Regions for Trees -- 5 Embedded Trees -- 6 Applications -- Notes -- List of Figures -- Guide to Notation A basic principle governing the boundary behaviour of holomorphic func­ tions (and harmonic functions) is this: Under certain growth conditions, for almost every point in the boundary of the domain, these functions ad­ mit a boundary limit, if we approach the bounda-ry point within certain approach regions. For example, for bounded harmonic functions in the open unit disc, the natural approach regions are nontangential triangles with one vertex in the boundary point, and entirely contained in the disc [Fat06]. In fact, these natural approach regions are optimal, in the sense that convergence will fail if we approach the boundary inside larger regions, having a higher order of contact with the boundary. The first theorem of this sort is due to J. E. Littlewood [Lit27], who proved that if we replace a nontangential region with the rotates of any fixed tangential curve, then convergence fails. In 1984, A. Nagel and E. M. Stein proved that in Euclidean half­ spaces (and the unit disc) there are in effect regions of convergence that are not nontangential: These larger approach regions contain tangential sequences (as opposed to tangential curves). The phenomenon discovered by Nagel and Stein indicates that the boundary behaviour of ho)omor­ phic functions (and harmonic functions), in theorems of Fatou type, is regulated by a second principle, which predicts the existence of regions of convergence that are sequentially larger than the natural ones HTTP:URL=https://doi.org/10.1007/978-1-4612-2310-8

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