The fixed point property and unbounded sets in CAT(0) spaces

Espínola, Rafa; Piątek, Bożena

doi:10.1016/j.jmaa.2013.06.038

Cited by 14 publications

(11 citation statements)

References 28 publications

(39 reference statements)

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“…The proof in any other model space M n k follows similar patterns by using the corresponding law of cosines of each space. The above result also holds in the equivalent infinite dimensional spherical and hyperbolic spaces defined using points in ℓ 2 (see, for instance, H ∞ in [14] and [13,Example 3.4]).…”

Section: Reflecting In Geodesic Spacesmentioning

confidence: 63%

Averaged alternating reflections in geodesic spaces

Fernández-León

Nicolae

2013

Journal of Mathematical Analysis and Applications

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We study the nonexpansivity of reflection mappings in geodesic spaces and apply our findings to the averaged alternating reflection algorithm employed in solving the convex feasibility problem for two sets in a nonlinear context. We show that weak convergence results from Hilbert spaces find natural counterparts in spaces of constant curvature. Moreover, in this particular setting, one obtains strong convergence.

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Section: Reflecting In Geodesic Spacesmentioning

confidence: 63%

Averaged alternating reflections in geodesic spaces

Fernández-León

Nicolae

2013

Journal of Mathematical Analysis and Applications

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“…In fact, this characterization of the FPP in terms of geodesic boundedness holds in the setting of complete CAT(0) spaces that are additionally δ-hyperbolic (see [29,Corollary 3.2]). Other results related to the FPP of unbounded sets in geodesic spaces can be found in [12,28,27].…”

Section: Preliminariesmentioning

confidence: 98%

“…Such properties include the presence of upper or lower curvature bounds in the sense of Alexandrov [5,12,24], the Gromov hyperbolicity condition [5], the betwenness property [23], or, for normed spaces, the reflexivity [34]. On the other hand, the existence of different types of curves can be used in the analysis of several problems among which we mention the characterization of the fixed point property either for continuous [20,19,24] or nonexpansive mappings [34,12,27], and some pursuit-evasion games [2,23].Geometric properties of a set stand behind the existence of fixed points for continuous or nonexpansive mappings defined on the set in question. This fact has prompted a very fruitful research direction because, among other reasons, it leads to challenging questions regarding the geometry of Banach spaces (see, e.g., the monographs [3,13]).…”

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confidence: 99%

Geodesic rays, the “Lion-Man” game, and the fixed point property

López-Acedo

Nicolae

Piątek

2020

Journal of Mathematical Analysis and Applications

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This paper focuses on the relation among the existence of different types of curves (such as directional ones, quasi-geodesic or geodesic rays), the (approximate) fixed point property for nonexpansive mappings, and a discrete lion and man game. Our main result holds in the setting of CAT(0) spaces that are additionally Gromov hyperbolic. IntroductionGiven a metric space X, the existence of either a geodesic ray in X or, more generally, of a curve that approximates a geodesic ray (e.g., a directional curve or a quasi-geodesic ray, see Section 3 for precise definitions), is connected to some intrinsic topological and geometric properties of the space. Such properties include the presence of upper or lower curvature bounds in the sense of Alexandrov [5,12,24], the Gromov hyperbolicity condition [5], the betwenness property [23], or, for normed spaces, the reflexivity [34]. On the other hand, the existence of different types of curves can be used in the analysis of several problems among which we mention the characterization of the fixed point property either for continuous [20,19,24] or nonexpansive mappings [34,12,27], and some pursuit-evasion games [2,23].Geometric properties of a set stand behind the existence of fixed points for continuous or nonexpansive mappings defined on the set in question. This fact has prompted a very fruitful research direction because, among other reasons, it leads to challenging questions regarding the geometry of Banach spaces (see, e.g., the monographs [3,13]). Klee [20] was a pioneer in the use of topological rays as a tool to characterize compactness of convex subsets of a locally convex metrizable linear topological space by means of the fixed point property for continuous mappings (see also [10]). Counterparts of this result for geodesic metric spaces were proved in [24,25]. The notion of directional curves was introduced in [34] to characterize the approximate fixed point property for nonexpansive mappings in convex subsets of a class of metric spaces which includes, in particular, Banach spaces or complete Busemann convex geodesic spaces. Further results in this direction were proved in [19,27]. Namely, the absence of geodesic rays from a closed and convex set is equivalent to its fixed point property for continuous mappings in complete R-trees, while for the more general setting of complete CAT(κ) spaces with κ < 0, it is equivalent to its fixed point property for nonexpansive mappings.Persuit-evasion problems are not only interesting because their analysis requires the use of tools from different areas of mathematics, but also because of their application in other disciplines such as robotics or the modeling of animal behavior. In a recent survey, Chung et al.[8] classify persuit-evasion games based on the environment where the game is played, the information available to the players, the restrictions imposed on the players' motion, and the way of defining capture.The game that we consider in this work was proposed in [1, 2] (see also [4]) and is a discrete variant of the cla...

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“…Thus, Ray's result fails in complete CAT(0) spaces in general. However, it is known that Ray's result does hold in such spaces if their unbounded convex sets satisfy a quasi-boundedness condition which holds for all reflexive Banach spaces (see the recent paper of Espínola [29,Theorem 3.6]). It is also known that a closed convex subset of a complete CAT(κ) space with κ < 0 has the fixed point property for non-expansive mappings if and only if it is geodesically bounded (Piatek [82]).…”

Section: Theorem 94 a Complete Geodesically Bounded R-tree Has The mentioning

confidence: 99%

Hyperbolic spaces and directional contractions

Kirk

Shahzad

2019

Bull. Math. Sci.

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The axiomatic approach to metric convexity goes back to the pioneering work of Karl Menger in 1928. This is an overview of this concept and the role it plays in metric fixed point theory especially in conjunction with spaces possessing a “hyperbolic” type structures. These include the CAT(0) spaces, hyperconvex metric spaces, and [Formula: see text]-trees. Much of the discussion involves the existence of “approximate” fixed point sequences for mappings satisfying weak contractive conditions. Applications of a well-known fixed point theorem due to Caristi are also included. These involve fixed and approximate fixed points for mappings satisfying local “directional” contractive and non-expansive conditions. Convexity plays a role in this part of the discussion as well. While the paper is semi-expository in nature, some detailed proofs appear here for the first time. Also the concept of a weak [Formula: see text]-directional contraction introduced in Sec. 8 appears to be new. Several suggestions for further research are also discussed.

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The fixed point property and unbounded sets in CAT(0) spaces

Cited by 14 publications

References 28 publications

Averaged alternating reflections in geodesic spaces

Averaged alternating reflections in geodesic spaces

Geodesic rays, the “Lion-Man” game, and the fixed point property

Hyperbolic spaces and directional contractions

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