Separated sets and Auerbach systems in Banach spaces

Hájek, Petr; Kania, Tomasz; Russo, Tommaso

doi:10.1090/tran/8160

Cited by 12 publications

(31 citation statements)

References 59 publications

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“…Remark Theorem A implies that the unit sphere of a non‐separable WLD subspace of

ℓ_{\infty}^{c} false(normalΓ false)

contains an uncountable symmetrically (1 + )‐separated subset, that is, a set A such that

∥ x \pm y ∥ > 1

for distinct

x, y \in A

; this is because

c_{0} false(ω_{1} false)

has this property. This observation complements [, Corollary 3.6], where it was proved that WLD spaces of density greater than the continuum contain such sets. It should be noted however that not every renorming of

c_{0} false(ω_{1} false)

embeds isometrically into

ℓ_{\infty}^{c} false(normalΓ false)

; indeed any strictly convex renorming is a counterexample (such renormings do exist as proved by Day ).…”

Section: The Resultssupporting

confidence: 85%

Embedding Banach spaces into the space of bounded functions with countable support

Johnson

Kania

2019

Mathematische Nachrichten

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We prove that a WLD subspace of the space ℓ∞cfalse(normalΓfalse) consisting of all bounded, countably supported functions on a set Γ embeds isomorphically into ℓ∞ if and only if it does not contain isometric copies of c0false(ω1false). Moreover, a subspace of ℓ∞cfalse(ω1false) is constructed that has an unconditional basis, does not embed into ℓ∞, and whose every weakly compact subset is separable (in particular, it cannot contain any isomorphic copies of c0false(ω1false)).

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“…Remark Theorem A implies that the unit sphere of a non‐separable WLD subspace of

ℓ_{\infty}^{c} false(normalΓ false)

contains an uncountable symmetrically (1 + )‐separated subset, that is, a set A such that

∥ x \pm y ∥ > 1

for distinct

x, y \in A

; this is because

c_{0} false(ω_{1} false)

c_{0} false(ω_{1} false)

embeds isometrically into

ℓ_{\infty}^{c} false(normalΓ false)

; indeed any strictly convex renorming is a counterexample (such renormings do exist as proved by Day ).…”

Section: The Resultssupporting

confidence: 85%

Embedding Banach spaces into the space of bounded functions with countable support

Johnson

Kania

2019

Mathematische Nachrichten

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“…It has been clear, at least since the paper [32] of Mercourakis and Vassiliadis, that the nature of separation in uncountable subsets of the unit sphere of a nonseparable Banach space could be equally indicative of the global and diverse properties of the space like in the separable case. The question of whether the unit sphere of a nonseparable Banach space must contain an uncountable a (1+)-separated set, and if so, of what cardinality compared to the density of the space, has been studied for various classes of Banach spaces e.g., in [4,21,31,32] and recently culminated in the paper [16], where it is highlighted as a central question. Notably the existence of (1 + ε)-separated sets of the size equal to the density of the space was proved for super-reflexive Banach spaces by Kania and Kochanek in [21] and for C(K) spaces, where K is compact Hausdorff and totally disconnected by Mercourakis and Vassiliadis.…”

Section: Introductionmentioning

confidence: 99%

Banach spaces in which large subsets of spheres concentrate

Koszmider¹

2021

Preprint

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We construct a nonseparable Banach space X (actually, of density continuum) such that any uncountable subset Y of the unit sphere of X contains uncountably many points distant by less than 1 (in fact, by less then 1 − ε for some ε > 0). This solves in the negative the central problem of the search for a nonseparable version of Kottman's theorem which so far produced many deep positive results for special classes of Banach spaces and related the global properties of the spaces to the distances between pairs of points of uncountable subsets of the unit sphere. The property of our space is strong enough to imply that it contains no uncountable Auerbach system nor an uncountable equilateral set. The space is a strictly convex renorming of the Johnson-Lindenstrauss space induced by an R-embeddable almost disjoint family of subsets of N. We also show that this special property of the almost disjoint family is essential to obtain the above properties.

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“…Thus equilateral sets are related to the questions concerning separation of points in the spheres of Banach spaces (see e.g. [8] for references). Recall that a subset Y of a Banach space X is called δ-separated if y − y ′ ≥ δ for all distinct y, y ′ ∈ Y.…”

Section: Introductionmentioning

confidence: 99%

“…It is called (δ+)-separated if y − y ′ > δ for all distinct y, y ′ ∈ Y. By Remark 3.16 [8] the unit sphere of every renorming of ℓ 1 ([0, 1]) contains a subset Y of cardinality continuum such that y − y ′ ≥ 1 + ε some ε > 0 and for every two distinct y, y ′ ∈ Y.…”

Section: Introductionmentioning

confidence: 99%

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Large Banach spaces with no infinite equilateral sets

Koszmider¹,

Wark²

2021

Preprint

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A subset of a Banach space is called equilateral if the distances between any two of its distinct elements are the same. It is proved that there exist non-separable Banach spaces (in fact of density continuum) with no infinite equilateral subset. These examples are strictly convex renormings of ℓ 1 ([0, 1]). A wider class of renormings of ℓ 1 ([0, 1]) which admit no uncountable equilateral sets is also considered.

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Separated sets and Auerbach systems in Banach spaces

Cited by 12 publications

References 59 publications

Embedding Banach spaces into the space of bounded functions with countable support

Embedding Banach spaces into the space of bounded functions with countable support

Banach spaces in which large subsets of spheres concentrate

Large Banach spaces with no infinite equilateral sets

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