Geometric Invariants of Surjective Isometries between Unit Spheres

Campos-Jiménez, Almudena; García-Pacheco, Francisco Javier

doi:10.3390/math9182346

Open AccessArticle

Geometric Invariants of Surjective Isometries between Unit Spheres

by

Almudena Campos-Jiménez

^†

and

Francisco Javier García-Pacheco

^*,†

Department of Mathematics, College of Engineering, University of Cadiz, 11519 Puerto Real, Cádiz, Spain

^*

Author to whom correspondence should be addressed.

^†

These authors contributed equally to this work.

Mathematics 2021, 9(18), 2346; https://doi.org/10.3390/math9182346

Submission received: 4 August 2021 / Revised: 13 September 2021 / Accepted: 18 September 2021 / Published: 21 September 2021

(This article belongs to the Special Issue Ordered Topological Vector Spaces, Operators Acting on Them and Related Applications)

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Abstract

:

In this paper we provide new geometric invariants of surjective isometries between unit spheres of Banach spaces. Let

X, Y

be Banach spaces and let

T : S_{X} \to S_{Y}

be a surjective isometry. The most relevant geometric invariants under surjective isometries such as T are known to be the starlike sets, the maximal faces of the unit ball, and the antipodal points (in the finite-dimensional case). Here, new geometric invariants are found, such as almost flat sets, flat sets, starlike compatible sets, and starlike generated sets. Also, in this work, it is proved that if F is a maximal face of the unit ball containing inner points, then

T (- F) = - T (F)

. We also show that if

[x, y]

is a non-trivial segment contained in the unit sphere such that

T ([x, y])

is convex, then T is affine on

[x, y]

. As a consequence, T is affine on every segment that is a maximal face. On the other hand, we introduce a new geometric property called property P, which states that every face of the unit ball is the intersection of all maximal faces containing it. This property has turned out to be, in a implicit way, a very useful tool to show that many Banach spaces enjoy the Mazur-Ulam property. Following this line, in this manuscript it is proved that every reflexive or separable Banach space with dimension greater than or equal to 2 can be equivalently renormed to fail property P.

Keywords:

tingley problem; Mazur-Ulam property; surjective isometry; extension isometries; geometric invariants; extreme point; exposed point; face; facet; strictly convex

MSC:

46B20

1. Introduction

The isometric extension problem is a prolific topic in the area of Functional Analysis inspired by the so-called Mazur-Ulam Theorem [1], which affirms that an isometry defined between two real Banach spaces is affine, understanding an isometry as a mapping

T : X \to Y

preserving distances (where X and Y are two normed spaces), that means

‖ T (x) - T (y) ‖ = ‖ x - y ‖

for all

x, y \in X

. The interest hiding on this result is the identification between the algebraic structure of the underline vector space and the metric one, whose distance is defined by its norm. A subtle generalization of this result is due to Mankiewicz [2], which states that it is sufficient to define the isometry between two convex bodies (convex sets with non-empty interior) of the real normed spaces to uniquely extend to an affine isometry between the whole spaces. A notable convex body in Banach spaces is the unit ball, which motivates the next step in the isometric extension problem: reducing the domain and co-domain to the unit spheres of both spaces. This question is known as Tingley’s Problem, due to Tingley [3].

Problem 1

(Tingley’s Problem). Is it always possible to extend a surjective isometry defined between the unit spheres of two real Banach spaces to a surjective linear isometry between the whole spaces?

In the last thirty years, quite a few researchers have given several positive answers to the above problem for particular Banach spaces, as well as many geometric and algebraic tools to tackle it [4,5,6,7,8,9,10,11,12,13,14,15]. Despite this wide list, nowadays Problem 1 is still open, even for the 2-dimensional case.

A variation of Tingley’s Problem was introduced in [6] by considering an arbitrary Banach space Y. This is a more general question in the isometric extension topic known as the Mazur-Ulam property.

Definition 1

(Mazur-Ulam property). A Banach space X satisfies the Mazur-Ulam property (MUp) if for an arbitrary Banach space Y, any surjective isometry between the unit spheres of X and Y is the restriction of a surjective linear isometry between the whole spaces.

The natural question that arises is what conditions allow X to satisfy the MUp. Some concrete examples of Banach spaces satisfying the MUp are polyhedral spaces,

c_{0} (Γ), ℓ^{p} (Γ) (1 \leq p < \infty), ℓ^{\infty} (Γ), C (Ω)

, (see [5,8,16,17,18]). This issue is currently a hot topic at the same level as Tingley’s Problem (recent articles about the MUp are [19,20,21,22]). Finally, in [21,23] the authors prove that non-strictly convex 2-dimensional Banach spaces and non-smooth 2-dimensional Banach spaces satisfy MUp.

In this work, the authors give some new geometric invariants under surjective isometries and simpler proofs about well-known results. Section 2 is devoted to make a review about the more relevant concepts, useful tools and results in the geometrical study of Banach spaces, in particular, the extremal structure, the starlike structure, smoothness, inner points and the Minkowski functional. These notions will play a fundamental role along the article. Moreover, property P is newly introduced in this section: we shall say that a normed space has property P if every proper face is the intersection of all maximal faces containing it. This property will be utilised as an implement in the study of the MUp (see Problem 2). Section 3 is a compilation of geometric results concerning the terms presented above. In the first place, we present several examples of Banach spaces failing property P under particular hypotheses. Later, we make a comprehension about the behaviour of facets and frames of the unit ball. In particular, we point out Theorem 7 as a straightforward characterisation of the frame of the unit ball. The next subsection is a deep study of the flatness properties of the unit sphere, where we present new definitions in search for more geometric invariants under surjective isometries. In particular, Theorems 9 and 10 show an identification between starlike sets and maximal faces when they are convex or centred in a smooth point. To end this section, we prove the invariance of the frame (Theorem 11), starlike envelopes (Theorem 12) and faces, when the large space satisfies property P (Theorem 13). Even more, surjective isometries preserve antipodal rotund points (Theorem 14), antipodal maximal faces with inner points (Theorem 15) and segments of the unit ball, when its image is convex (Theorem 17). Section 4 and Section 5 close the article with a proposal of a new approach to show that 2-dimensional real Banach spaces enjoy MUp by strongly relying on [23].

2. Materials and Methods

All vector spaces considered throughout this manuscript will be over the reals. If X is a normed space, then

B_{X}, U_{X}, S_{X}

will stand for its (closed) unit ball, its open unit ball, and its unit sphere, respectively. If

x \in X

and

r > 0

, then

B_{X} (x, r), U_{X} (x, r), S_{X} (x, r)

will denote, as expected, the (closed) ball of center x and radius

r > 0

, the open ball of center x and radius

r > 0

, and the sphere of center x and radius

r > 0

. For metric spaces, we will keep using the same notation for the closed balls, the open balls and the spheres.

If X is now a topological space and

A \subseteq X

, then

int (A), cl (A), bd (A)

stand for the interior of A, the closure of A, and the boundary of A, respectively. If

B \subseteq A

, then

{int}_{A} (B), {cl}_{A} (B), {bd}_{A} (B)

stand, as expected, for the relative interior of B with respect to A, the relative closure of B with respect to A, and the relative boundary of B with respect to A, respectively.

2.1. Extremal Structure

The following definitions are well known among the Banach Space Geometers and belong to the folklore of classic literature of Banach Space Theory. For further reading on these topics, we refer the reader to the classical texts [24,25,26].

Definition 2

(Extremal subset, Extremal point). Let X be a vector space. Let

E \subseteq F \subseteq X

. We say that E satisfies the extremal condition with respect to F provided that the following property is satisfied:

\forall x, y \in F, \forall t \in (0, 1) : t x + (1 - t) y \in E \Rightarrow x, y \in E .

(1)

Under this situation, we say that E is extremal in F. When an extremal subset

E = {e}

is a singleton, then

{e}

is called a extremal point of F. The set of extremal points of F is denoted by

ext (F)

.

Notice that the non-empty intersection of any arbitrary family of extremal subsets is extremal as well. Also, if E is extremal in F and D is extremal in E, then D is extremal in F. Observe that if E is extremal in F, then

ext (E) \subseteq ext (F)

.

Example 1

(Supporting hyperplane). Let A be a non-empty subset of a vector space X and consider

f \in X^{*}

. The supporting hyperplane relative to f in A

F (f, A) : = {x \in A : f (x) = max f (A)}

is a extremal subset of A, provided that

F (f, A) \neq ⌀

. If X is normed and

A = B_{X}

, then we will simply write

F (f)

.

The extremal condition allows to define the geometrical concepts of face and facet. We would like to make the reader beware that the notions of face and facet in [3] is what we call later on in this manuscript an exposed face and a maximal face, respectively.

Definition 3

(Face, Extreme point). Let X be a normed space. Let

A \subseteq B_{X}

be a subset of

B_{X}

. We shall say that A is a face of

B_{X}

if A is convex and extremal in

B_{X}

. The extremal points of a convex subset

A \subseteq B_{X}

are called extreme points.

It is easy to check that every extremal subset E of

B_{X}

satisfies that either

E = B_{X}

or

E \subseteq S_{X}

. As a consequence, proper faces of the unit ball are always contained in the unit sphere. Also, a point x is an extreme point of a convex set A if and only if

A ∖ {x}

is also convex.

Definition 4

(Exposed face, Exposed point, Edge). Let X be a normed space. An exposed face of

B_{X}

is a set of the form

F (f)

for some

f \in S_{X^{*}}

. When an exposed face

F (f) = {x}

is a singleton, then

{x}

is called an exposed point of

B_{X}

. The set of exposed points of

B_{X}

is denoted by

exp (B_{X})

. Besides, we define an edge

E (f)

of the unit ball with respect to

f \in S_{X^{*}}

as

E (f) = {bd}_{f^{- 1} ({1})} (F (f))

.

Observe that exposed faces are trivial examples of proper faces. On the other hand, it is trivial that

exp (B_{X}) \subseteq ext (B_{X})

. We want to make the reader notice that the definition of edge right above agrees with the one given in ([9], Theorem 1.1) and ([10], Section 3), and it differs from the one provided in ([27], Definition 1.2(2)).

Remark 1.

Let X be a normed space. If

{(C_{n})}_{n \in N}

is a family of exposed faces of

B_{X}

such that

⋂_{n \in N} C_{n} \neq ⌀

, then

⋂_{n \in N} C_{n}

is an exposed face of

B_{X}

. Indeed, take

f_{n} \in S_{X^{*}}

with

C_{n} = F (f_{n})

for all

n \in N

. Then

⋂_{n \in N} C_{n} = F (f)

where

f : = \sum_{n = 1}^{\infty} \frac{1}{2^{n}} f_{n}

.

Definition 5

(Maximal face, Rotund point). Let X be a normed space. A maximal face of

B_{X}

is a proper face that is a maximal element of the set of proper faces of

B_{X}

endowed with the inclusion. When a maximal face

C = {x}

of

B_{X}

is a singleton, we call x a rotund point of

B_{X}

. The set of rotund points of

B_{X}

is denoted by

rot (B_{X})

.

In view of the Hahn-Banach Separation Theorem, one can see that every maximal face of the unit ball is an exposed face. In fact, maximal faces can be characterized as follows. Recall that a convex component is, by definition, a maximal convex subset. We refer the reader to [28] for a wider perspective on convex components. By relaying on the Hahn-Banach Separation Theorem, it is not hard to check (see also ([3], Lemma 1) or ([27], Lemma 2.7)) that the following are equivalent for a subset

C \subseteq S_{X}

:

C is a convex component of $S_{X}$ .
C is a maximal face of $B_{X}$ .
C is a maximal exposed face of $B_{X}$ .

Therefore, we will indistinctly talk about maximal faces of the unit ball and maximal convex subsets of the unit sphere. Also, note that

rot (B_{X}) \subseteq exp (B_{X}) \subseteq ext (B_{X})

. The following examples show the above contentions are strict for some kind of Banach spaces.

Example 2.

In

ℓ_{\infty}^{2}

, each corner of the unit sphere is an example of an exposed point which is not rotund. If we smoothen the corners of

B_{ℓ_{\infty}^{2}}

, then each extreme of any of the four edges is an extreme point which is not an exposed point.

The following result can be found in ([6], Lemma 5.1), ([10], Lemma 3.5), and ([11], Lemma 6.3).

Theorem 1

([6,10,11]). Let

X, Y

be Banach spaces. Let

T : S_{X} \to S_{Y}

be a surjective isometry and

C \subseteq S_{X}

a maximal convex subset of

S_{X}

. Then

T (C)

is a maximal face of

B_{Y}

.

The above theorem was originally proved in ([3], Lemma 13) in the finite dimensional case. In Corollary 7(1), we provide a new and simpler proof of Theorem 1 for a wide class of Banach spaces including the finite-dimensional spaces.

Definition 6

(Pre-maximal face, Proper exposed point). Let X be a normed space. A proper face A of

B_{X}

is said to be a pre-maximal face of

B_{X}

if A is the intersection of all maximal faces containing A. When a pre-maximal face is a singleton

A = {x}

, it is called a proper exposed point, and the set of all proper exposed points of

B_{X}

is denoted by

pexp (B_{X})

.

The term of proper exposed point defined right above was already coined by Tanaka in ([11], Definition 3.2). The following chain of inclusions is verified:

rot (B_{X}) \subseteq pexp (B_{X}) \subseteq ext (B_{X}) .

If X is separable, one can see by relying on Remark 1 or on ([11], Proposition 3.4) that:

rot (B_{X}) \subseteq pexp (B_{X}) \subseteq exp (B_{X}) \subseteq ext (B_{X}) .

The following interesting property, original from this work, is strongly motivated by ([11], Definition 3.2). It constitutes a very helpful tool to prove that certain spaces enjoy the MUp.

Definition 7

(Property P). Let X be a normed space. We say that X has property P or the P-property (Pp) if every proper face of

B_{X}

is a pre-maximal face.

It is an interesting question whether every Banach space satisfying Pp also enjoys the MUp.

Problem 2.

If X is a Banach space enjoying Pp, does X have the MUp?

If the answer to the above problem was positive, then the next step would be to determine or characterize which Banach spaces verify Pp. This motivates the following question:

Problem 3.

Can every Banach space be equivalently renormed to satisfy Pp?

In Corollary 3, we approach the above question negatively by proving that reflexive Banach spaces and separable Banach spaces with dimension greater than or equal to 2 can be equivalently renormed to fail Pp.

As we mentioned before, in [3], Tingley calls facets to the maximal faces of the unit ball. Here, following ([27], Definition 1.2), we will give a different meaning to the notion of facet.

Definition 8

(Facet). Let X be a normed space. A proper face A of

B_{X}

is called a facet of

B_{X}

provided that

{int}_{S_{X}} (A) \neq ⌀

. We will denote

C_{X} : = {C \subset S_{X} : C is a facet}

.

Remark 2.

Let

X, Y

be Banach spaces. Let

T : S_{X} \to S_{Y}

be a surjective isometry and

C \subseteq S_{X}

a facet. Then

{int}_{S_{X}} (C) \neq ⌀

, so

{int}_{S_{Y}} (T (C)) \neq ⌀

because T is a homeomorphism.

In ([27], Theorem 2.8), it was proved that facets of the unit ball are convex components of the unit sphere, hence they are maximal faces of the unit ball. A direct consequence of this fact together with Theorem 1 and Remark 2 is that surjective isometries between unit sphere preserve facets of the unit ball.

Corollary 1.

Let

X, Y

be Banach spaces. Let

T : S_{X} \to S_{Y}

be a surjective isometry. If

C \subseteq S_{X}

a facet, then

T (C)

is a facet of

B_{Y}

. In other words,

T (C_{X}) = C_{Y}

.

2.2. Starlike Structure

Starlike sets were originally introduced in [3] and characterized in ([3], Lemma 4 and Corollary 5).

Definition 9

(Starlike set). Let X be a normed space. The starlike set of a point

x \in S_{X}

is defined as

s t (x, B_{X}) : = {y \in B_{X} : ‖ x + y ‖ = 2}

.

Observe that

s t (x, B_{X}) \subseteq S_{X}

and

s t (- x, B_{X}) = - s t (x, B_{X})

. Using metric spaces notation, the starlike set of x is precisely the sphere of center

- x

and radius 2 in the metric space given by the unit sphere, that is,

s t (x, B_{X}) = S_{S_{X}} (- x, 2)

. Another trivial way of characterizing the starlike set is the following:

s t (x, B_{X}) = \{y \in S_{X} : [y, x] \subseteq S_{X}\} = ⋃ \{C \subseteq S_{X} : C is a maximal face containing x\} .

(2)

Remark 3.

Let

X, Y

be metric spaces. Every isometry

T : X \to Y

clearly satisfies, for all

x \in X

and all

r > 0

, that

T (B_{X} (x, r)) \subseteq B_{Y} (T (x), r)

,

T (U_{X} (x, r)) \subseteq U_{Y} (T (x), r)

,

T (S_{X} (x, r)) \subseteq S_{Y} (T (x), r)

. Furthermore, if T is surjective, then

T (B_{X} (x, r)) = B_{Y} (T (x), r)

,

T (U_{X} (x, r)) = U_{Y} (T (x), r)

,

T (S_{X} (x, r)) = S_{Y} (T (x), r)

.

In view of the previous remark, the following is immediate (see also ([3], Lemma 10 and Corollary 11)).

Remark 4.

Let

X, Y

be Banach spaces. Let

T : S_{X} \to S_{Y}

be a surjective isometry. For every

x \in S_{X}

,

T s t ((x, B_{X})) = T (S_{S_{X}} (- x, 2)) = S_{S_{Y}} (T (- x), 2) = S_{S_{Y}} (- (- T (- x)), 2) = s t (- T (- x), B_{Y}) .

The main theorem of [3], which is stated right below, shows that surjective isometries between unit spheres of finite dimensional Banach spaces preserve antipodal points.

Theorem 2

([3]). Let

X, Y

be finite dimensional Banach spaces. Let

T : S_{X} \to S_{Y}

be a surjective isometry. Then

T (- x) = - T (x)

for every

x \in S_{X}

.

In ([5], Corollary 2.2), the following result was stated and proved. In ([6], Corollary 5.2), the same result was stated but its proof was omitted. Here, simply for the sake of completeness, we will include a different (and more direct) proof than the one given in ([5], Corollary 2.2). This proof strongly relies on Theorem 1.

Theorem 3

([5,6]). Let

X, Y

be Banach spaces. Let

T : S_{X} \to S_{Y}

be a surjective isometry. Then

T (s t (x, B_{X})) = s t (T (x), B_{Y})

for every

x \in S_{X}

.

Proof.

In virtue of (2) together with Theorem 1, we have that

\begin{matrix} T (s t (x, B_{X})) & = & T (⋃ \{C \subseteq S_{X} : C is a maximal face containing x\}) \\ = & ⋃ \{T (C) : C is a maximal face of B_{X} containing x\} \\ = & ⋃ \{D \subseteq S_{Y} : D is a maximal face of B_{Y} containing T (x)\} \\ = & s t (T (x), B_{Y}) . \end{matrix}

□

In Corollary 7(2), we provide a different and more direct proof of Theorem 3 for a wide class of Banach spaces containing the finite-dimensional Banach spaces. On the other hand, a direct consequence of Theorem 3 together with Remark 4 is the following corollary, original from this work.

Corollary 2.

Let

X, Y

be Banach spaces and let

T : S_{X} \to S_{Y}

be a surjective isometry. Then

T (- s t (x, B_{X})) = - T (s t (x, B_{X}))

for all

x \in S_{X}

.

Proof.

It only suffices to rely on Theorem 3 and Remark 4:

T (- s t (x, B_{X})) = T (s t (- x, B_{X})) = (T s t (- x), B_{Y}) = - s t (- T (- x), B_{Y})) = - T (s t (x, B_{X})) .

□

2.3. Smoothness

The following concepts are related to the smoothness properties of the unit ball. We refer the reader to [25,26,29] for a wider perspective on smoothness. First of all, we recall the definition of smoothness.

Definition 10

(Smooth space, smooth point). Let X be a normed space. A point

x \in S_{X}

is called a smooth point of

B_{X}

if there exists a unique functional

f \in S_{X^{*}}

attaining its norm at x, in other words,

f (x) = 1

. The set of smooth points of

B_{X}

is denoted as

smo (B_{X})

. The normed space X is said to be smooth provided that

smo (B_{X}) = S_{X}

.

Geometrically speaking, x is smooth if the unit ball

B_{X}

has a unique supporting hyperplane at x. Notice that all the exposed faces of the unit ball are pairwise disjoint in smooth spaces.

Definition 11

(Dualilty mapping). Let X be a normed space. The duality mapping of X is defined as

\begin{matrix} J : & X & \to & P (X^{*}) \\ x & \mapsto & J (x) : = \{x^{*} \in X^{*} : x^{*} (x) = ∥x^{*}∥ ‖ x ‖\} . \end{matrix}

(3)

The duality mapping induces the spherical image map.

Definition 12

(Spherical image map). Let X be a normed space. The spherical image map of X is defined as

\begin{matrix} ν : & S_{X} & \to & P (S_{X^{*}}) \\ x & \mapsto & ν (x) : = \{x^{*} \in S_{X^{*}} : x^{*} (x) = 1\} . \end{matrix}

(4)

Notice that, for each

x \in S_{X}

,

ν (x) = J (x) \cap S_{X^{*}}

, that is,

ν (x)

is the subset of

S_{X^{*}}

whose members are the supporting functionals for

B_{X}

at x. On the other hand, it is easy to understand that

ν (x) = F (x)

, where x is seen as an element of

X^{* *}

. Note that if

x \in smo (B_{X})

, then

ν (x)

is a singleton, so we will identify

ν (x)

with its only element. In this situation,

F (ν (x))

is the only exposed face of

B_{X}

containing x, thus

F (ν (x))

is the only maximal face of

B_{X}

containing x.

With the help of the spherical image map, we can provide an easy reformulation of the frame of a Banach space (see ([9], Theorem 1.1) and ([10], Section 3)).

Definition 13

(Frame). Let X be a normed space. The frame of

B_{X}

is defined as

frm (B_{X}) : = ⋃ \{E (f) : f \in ⋃_{x \in S_{X}} ν (x)\} .

In ([10], Theorem 3.7), it was proved that the frame of a Banach space is preserved under surjective isomeries between unit spheres.

Theorem 4

([10]). If

T : S_{X} \to S_{Y}

is a surjective isometry between the unit spheres of Banach spaces

X, Y

, then

T (frm (B_{X})) = frm (B_{Y})

.

In Theorem 7, we provide a topological reformulation of the frame in terms of the relative topology of the unit sphere, which allows to provide a very simple proof ([10], Theorem 3.7) (see Theorem 11).

2.4. Inner Structure

We refer the reader to [30,31,32,33] for a wider perspective on these concepts. Inner structure was introduced for the first time in ([30], Definition 1.2) for non-convex sets, although it appears implicitly in [34,35] for convex sets. In this manuscript, we will only make use of inner structure of convex sets.

Definition 14

(Inner points). Let X be a vector space. Let M be a convex subset of X with at least two points. We define the set of inner points of M as

inn (M) : = \{x \in X : \forall m \in M ∖ {x} \exists n \in M ∖ {m, x} such that x \in (m, n)\} .

The set of inner points of a convex set is the infinite dimensional version of what Tingley calls “relative interior” of convex subsets of

R^{n}

in [3]. In fact, in ([30], Theorem 5.1) it is proved that every non-singleton convex subset of any finite dimensional vector space has inner points. However, in ([30], Corollary 5.3) it was shown that every infinite dimensional vector space possesses a non-singleton convex subset free of inner points.

Remark 5.

Under the settings of the previous definition, we convey that if M is a singleton, then

inn (M) = ⌀

. It is trivial that

inn (M) \subseteq M

. In view of ([32], Remark 1.1), if

x \in inn (M)

, then

[x, m) \subseteq inn (M)

for all

m \in M

. As a consequence,

inn (M)

is convex and

cl (inn (M)) = cl (M)

. On the other hand, in ([32], Lemma 2.1), it was proved that if F is a extremal subset of M, then

F \cap inn (M) = ⌀

.

The following trivial remark we will be made use of later on and it will turn out to be crucial.

Remark 6.

Let X be a vector space. If

x, y, z \in X

are three different points not aligned, then

\begin{matrix} inn (co ({x, y, z})) & = & co ({x, y, z}) ∖ ([x, y] \cup [y, z] \cup [x, z]) \\ = & {r x + s y + t z : r, s, t \in (0, 1), r + s + t = 1} . \end{matrix}

In ([6], Definition 2.1), the notion of non-supporting point was introduced.

Definition 15

(Non-support point). Let X be a vector space. Let A be a non-empty subset of X. Let

h (A) : = {f \in X^{*} : f attains its \sup at A and it is not constant on A}

. The set of non-support points of A is defined as

nsupp (A) : = A ∖ ⋃_{f \in h (A)} F (f, A)

.

Notice that in the above definition it might occur that

h (A)

be empty. For instance, if A is the open unit ball of a normed space, then

h (A) = ⌀

. The following result, which is original from this work, unveils the relation between inner points and non-support points.

Theorem 5.

Let X be a vector space. Let C be a convex subset of X. If

h (C) \neq ⌀

, then

inn (C) \subseteq nsupp (C)

.

Proof.

Fix an arbitrary

f \in h (C)

. By bearing in mind Example 1, we have that

F (f, C)

is extremal in C. Next, we call on ([32], Lemma 2.1) (see also Remark 5) to conclude that

inn (C) \cap F (f, C) = ⌀

. This means that

inn (C) \subseteq C ∖ F (f, C)

. The arbitrariness of

f \in h (C)

implies that

inn (C) \subseteq ⋂_{f \in h (C)} C ∖ F (f, C) = C ∖ ⋃_{f \in h (C)} F (f, C) = nsupp (C) .

□

The following remark is crucial towards finding geometric invariants under surjective isometries between unit spheres.

Remark 7.

Let X be a normed space. For every

x, y \in X ∖ {0}

,

‖ x + y ‖ = ‖ x ‖ + ‖ y ‖

if and only if

[\frac{x}{‖ x ‖}, \frac{y}{‖ y ‖}] \subseteq S_{X}

. Indeed, if

‖ x + y ‖ = ‖ x ‖ + ‖ y ‖

, then

\frac{‖ x ‖}{‖ x + y ‖} \frac{x}{‖ x ‖} + \frac{‖ y ‖}{‖ x + y ‖} \frac{y}{‖ y ‖} = \frac{x + y}{‖ x + y ‖}

is a strict convex combination contained in

S_{X}

, so then the whole segment

[\frac{x}{‖ x ‖}, \frac{y}{‖ y ‖}]

is contained in

S_{X}

. Conversely, if

[\frac{x}{‖ x ‖}, \frac{y}{‖ y ‖}] \subseteq S_{X}

, then

\frac{x + y}{‖ x ‖ + ‖ y ‖} = \frac{‖ x ‖}{‖ x ‖ + ‖ y ‖} \frac{x}{‖ x ‖} + \frac{‖ y ‖}{‖ x ‖ + ‖ y ‖} \frac{y}{‖ y ‖} \in [\frac{x}{‖ x ‖}, \frac{y}{‖ y ‖}] \subseteq S_{X},

therefore,

‖ x + y ‖ = ‖ x ‖ + ‖ y ‖

.

Recall that a normed space X is said to be rotund or strictly convex provided that its unit sphere is free of non-trivial segments. This is equivalent to

ext (B_{X}) = S_{X}

.

Remark 8.

Let X be a normed space. If

C \subseteq X

is a convex subset containing at least three points not aligned, then

C ∖ {c}

is connected for every

c \in C

.

2.5. Minkowski Functional

The following definition forms part of the folklore of the literature of Geometry of Topological Vector Spaces. We refer the reader to [36,37,38] for a deep perspective on the following concepts and on the Minkowski functional.

Definition 16.

Let X denote a vector space. A subset

A \subseteq X

is said to be:

Balanced provided that $[- 1, 1] A \subseteq A$ .
Absorbing provided that for all $x \in X$ there exists $δ > 0$ satisfying that $[- δ, δ] x \subseteq A$ .
Absolutely convex if A is balanced and convex.
Linearly bounded if A does not contain straight lines or rays.

The Minkowski functional assures that every absorbing absolutely convex subset

A \subseteq X

defines a seminorm on X:

{‖ x ‖}_{A} : = inf {λ \geq 0 : x \in λ A} .

If we let

U_{X}, B_{X}

denote the open, closed unit balls of

(X, ‖ \cdot ‖_{A})

, respectively, then it is easy to check that

U_{X} = int (A)

and

B_{X} = cl (A)

. Another trivial fact is that

{‖ \cdot ‖}_{A}

is a norm on X if and only if A is linearly bounded.

Suppose now that X is a Banach space and A is a bounded, closed, absolutely convex subset of X with non-empty interior. Then the Minkowski functional on A defines an equivalent norm in X (keep in mind that every absolutely convex subset with non-empty interior in a topological vector space is a neighbourhood of 0).

We will rely on the following remark to construct a new unit ball in

R^{3}

that will serve as counterexample for several intuitive conjectures.

Remark 9.

Let X be a finite dimensional Banach space. Let K be a convex compact subset of X with non-empty interior. Suppose that there exists

x^{*} \in S_{X^{*}}

such that

x^{*} (x) > 0

for all

x \in K

. Take

A : = co (K \cup - K)

. Then A is compact, absolutely convex and a neighbourhood of 0. As a consequence, A defines an equivalent norm on X.

Lemma 1.

Under the settings of Remark 9,

ext (A) \subseteq ext (K) \cup ext (- K)

.

Proof.

Fix any

a \in ext (A)

. There are

t \in [0, 1]

and

k_{1}, k_{2} \in K

with

a = t k_{1} + (1 - t) (- k_{2})

. Since a is an extreme point of A, either

a = k_{1}

or

a = - k_{2}

. Suppose without any loss of generality that

a = k_{1}

. Then

a \in ext (A) \cap K \subseteq ext (K)

. □

Recall that the Krein-Milman Theorem [39] assures that if X is a Hausdorff locally convex topological vector space and

K \subseteq X

compact, then

ext (K) \neq ⌀

. If, in addition, K is compact and convex, then

K = \bar{co} (ext (K))

. As a consequence, if X is a reflexive Banach space and

C \subseteq X

is closed, convex and bounded, then C is weakly closed and bounded, and thus weakly compact. Therefore,

ext (C) \neq ⌀

.

3. Results

In this section, we will present the main results derived from this work on Tingley’s Problem.

3.1. Banach Spaces Lacking Pp

Our first result provides a sufficient condition for a Banach space to fail Pp.

Lemma 2.

Let X be a Banach space. If X is smooth and

ext (B_{X}) ∖ rot (B_{X}) \neq ⌀

, then X fails Pp.

Proof.

Take any

e \in ext (B_{X}) ∖ rot (B_{X})

. We will show X fails P by proving that

{e}

is a face of

B_{X}

that is not the intersection of all maximal faces containing it. Indeed, there exists a maximal face

C \subseteq S_{X}

containing e. If D is another maximal face containing

{e}

, then there exists

x^{*} \in S_{X^{*}}

such that

D = {x \in S_{X} : x^{*} (x) = 1}

. Now, C is another maximal face, so there exists

y^{*} \in S_{X^{*}}

such that

C = {x \in S_{X} : y^{*} (x) = 1}

. Then

x^{*} (e) = 1 = y^{*} (e)

, which implies that

x^{*} = y^{*}

because of the smoothness of X. As a consequence,

C = D

is the only maximal face containing

{e}

. Finally, since

e \notin rot (B_{X})

,

C \neq {e}

. □

Lemma 3.

If Y is a 2-dimensional Banach space, then Y is isomorphic to a smooth space

Y^{'}

such that

ext (B_{Y^{'}}) ∖ rot (B_{Y^{'}}) \neq ⌀

. If, in addition, Z is another Banach space, then

ext (B_{Y^{'}}) ∖ rot (B_{Y^{'}}) \subseteq (B_{X^{'}}) ∖ rot (B_{X^{'}})

, where

X^{'} : = Y^{'} \oplus_{2} Z

.

Proof.

It suffices to smoothen the corners of

B_{ℓ_{\infty}^{2}}

and take

Y^{'}

equal to

R^{2}

endowed with the norm given by this new unit ball. Since

Y^{'}

is not strictly convex and its unit ball is compact, any non-singleton maximal face of

B_{Y^{'}}

contains extreme points in view of the Krein-Milman Theorem. These extreme points are clearly not rotund points. □

We are now in the right position to state and prove the main theorem in this subsection.

Theorem 6.

If a Banach space X with dimension greater than or equal to 2 admits a smooth equivalent norm, then it can be equivalently renormed to be smooth and to verify that

ext (B_{X}) ∖ rot (B_{X}) \neq ⌀

. Thus, X fails Pp with this equivalent norm by Lemma 2.

Proof.

First off, let us assume that X is already endowed with an equivalent smooth norm. Fix a 2-dimensional subspace Y of X. According to Lemma 3, Y is isomorphic to a smooth, but not strictly convex, 2-dimensional Banach space

Y^{'}

. Let Z be a closed subspace of X such that

X = Y \oplus Z

. Observe that X is isomorphic to

X^{'} : = Y^{'} \oplus_{2} Z

. Also, notice that

Y^{'} \oplus_{2} Z

is smooth. In view of Lemma 3, we can find

e \in ext (B_{Y^{'}}) ∖ rot (B_{Y^{'}})

. Finally,

e \in (B_{X^{'}}) ∖ rot (B_{X^{'}})

in virtue of Lemma 3. □

Corollary 3.

Every reflexive or separable Banach space with dimension greater than or equal to 2 can be equivalently renormed to fail Pp.

Proof.

It only suffices to take into consideration that reflexive Banach spaces ([40], Corollary 4) and separable Banach spaces ([29], Corollary 4.3(i)) admit an equivalent smooth renorming. □

We also refer the reader to [41] for other interesting renormings of reflexive spaces.

3.2. Geometric Structure of Facets and Frames

Some of the results in this subsection appear in a light version and in a scattered manner throughout the literature of the Geometry of Banach spaces. Those results are generalized here and all the proofs are provided for the sake of completeness. We refer the reader to [25,26,27,28,32] for more details about facets and frames.

Remark 10.

Let X be a normed space,

x \in X

,

r > 0

and

y \in B_{X} (x, r) ∖ {x}

. The extremes of the maximal segment of

B_{X} (x, r)

containing

[x, y]

are given by

(1 + \frac{r}{‖ x - y ‖}) x - \frac{r}{‖ x - y ‖} y and (1 - \frac{r}{‖ x - y ‖}) x + \frac{r}{‖ x - y ‖} y .

(5)

Notice that these two points are in

S_{X} (x, r)

and they are the only points of the segment

[(1 + \frac{r}{‖ x - y ‖}) x - \frac{r}{‖ x - y ‖} y, (1 - \frac{r}{‖ x - y ‖}) x + \frac{r}{‖ x - y ‖} y]

lying on

S_{X} (x, r)

.

Lemma 4.

Let X be a normed space with

dim (X) \geq 2

. Let

x \in S_{X}

,

f \in S_{X^{*}}

with

f (x) = 1

, and

r > 0

. Then:

If $B_{X} (x, r) \cap S_{X} \subseteq f^{- 1} ({1})$ , then $B_{X} (x, \frac{r}{2}) \cap f^{- 1} ({1}) \subseteq S_{X}$ .
If $y \in S_{X} ∖ {x}$ is so that $[x, y] \subseteq S_{X} \cap f^{- 1} ({1})$ , and $[u, v]$ is the maximal segment of $S_{X}$ containing $[x, y]$ , then $u, v \in cl (S_{X} ∖ f^{- 1} ({1}))$ .
If $B_{X} (x, r) \cap S_{X} \subseteq f^{- 1} ({1})$ , then $B_{X} (x, r) \cap S_{X}$ is convex and $r \leq 1$ . Even more, if $y \in (B_{X} (x, r) \cap S_{X}) ∖ {x}$ , then $[(1 + \frac{r}{‖ x - y ‖}) x - \frac{r}{‖ x - y ‖} y, (1 - \frac{r}{‖ x - y ‖}) x + \frac{r}{‖ x - y ‖} y] \subseteq S_{X}$ .
If $B_{X} (x, r) \cap f^{- 1} ({1}) \subseteq S_{X}$ , then $r \leq 1$ and there exists $0 < s < r$ such that $B_{X} (x, s) \cap S_{X} \subseteq f^{- 1} ({1})$ .

Proof.

Take any $y \in B_{X} (x, \frac{r}{2}) \cap f^{- 1} ({1})$ . Observe that $1 = f (y) \leq ‖ y ‖$ . Next,

$\begin{matrix} ∥x - \frac{y}{‖ y ‖}∥ & \leq & ‖ x - y ‖ + ∥y - \frac{y}{‖ y ‖}∥ \\ = & ‖ x - y ‖ + \frac{∥‖ y ‖ y - y∥}{‖ y ‖} \\ = & ‖ x - y ‖ + \frac{|‖ y ‖ - 1| ‖ y ‖}{‖ y ‖} \\ = & ‖ x - y ‖ + |‖ y ‖ - 1| \\ = & ‖ x - y ‖ + |‖ y ‖ - ‖ x ‖| \\ \leq & 2 ‖ y - x ‖ \\ \leq & r . \end{matrix}$

Therefore, $\frac{y}{‖ y ‖} \in B_{X} (x, r) \cap S_{X} \subseteq f^{- 1} ({1})$ . As a consequence, $f (\frac{y}{‖ y ‖}) = 1$ , which implies that $‖ y ‖ = 1$ .
It suffices to show that $u, v \notin {int}_{S_{X}} (S_{X} \cap f^{- 1} ({1}))$ . Suppose to the contrary that, for instance, $u \in {int}_{S_{X}} (S_{X} \cap f^{- 1} ({1}))$ . There exists $α > 0$ such that $B_{X} (u, α) \cap S_{X} \subseteq S_{X} \cap f^{- 1} ({1})$ . In virtue of Lemma 4(1), $B_{X} (u, \frac{α}{2}) \cap f^{- 1} ({1}) \subseteq S_{X}$ . Then we can find $s < 0$ sufficiently small such that $(1 - s) u + s v \in B_{X} (u, \frac{α}{2})$ . Clearly, $(1 - s) u + s v \in f^{- 1} ({1})$ because $[x, y] \subseteq [u, v]$ and $[x, y] \subseteq f^{- 1} ({1})$ , so $[u, v] \subseteq f^{- 1} ({1})$ . As a consequence, $(1 - s) u + s v \in B_{X} (u, \frac{α}{2}) \cap f^{- 1} ({1}) \subseteq S_{X}$ . In particular, $[(1 - s) u + s v, v] \subseteq B_{X} \cap f^{- 1} ({1}) \subseteq S_{X}$ . Finally, notice that $[u, v] ⊊ [(1 - s) u + s v, v] \subseteq S_{X}$ , contradicting the maximality of $[u, v]$ .
We will show first that $B_{X} (x, r) \cap S_{X}$ is convex. Take $y, z \in B_{X} (x, r) \cap S_{X}$ and $t \in [0, 1]$ . Notice that $t y + (1 - t) z \in B_{X} (x, r) \cap B_{X}$ . By hypothesis, $t y + (1 - t) z \in f^{- 1} ({1})$ , which implies that $‖ t y + (1 - t) z ‖ \geq | f (t y + (1 - t) z) | = 1$ . As a consequence, $t y + (1 - t) z \in S_{X}$ . This shows that $B_{X} (x, r) \cap S_{X}$ is convex. Next, let us prove that $r \leq 1$ . Assume on the contrary that $r > 1$ . Observe that $x \in S_{X} = cl (S_{X} ∖ {x})$ because $dim (X) \geq 2$ . Therefore, we can take $y \in (B_{X} (x, r) \cap S_{X}) ∖ {x}$ . Since $B_{X} (x, r) \cap S_{X}$ is convex, we have that $[x, y] \subseteq B_{X} (x, r) \cap S_{X}$ . According to Remark 10, the maximal segment of $B_{X} (x, r)$ containing $[x, y]$ is given by

$[(1 + \frac{r}{‖ x - y ‖}) x - \frac{r}{‖ x - y ‖} y, (1 - \frac{r}{‖ x - y ‖}) x + \frac{r}{‖ x - y ‖} y] .$

Denote by $[u, v]$ to the maximal segment of $S_{X}$ containing $[x, y]$ . Let us distinguish between several cases:
- $[(1 + \frac{r}{‖ x - y ‖}) x - \frac{r}{‖ x - y ‖} y, (1 - \frac{r}{‖ x - y ‖}) x + \frac{r}{‖ x - y ‖} y] \subseteq [u, v]$ . In this case, since $[u, v] \subseteq S_{X}$ , we obtain that
  
  $(1 + \frac{r}{‖ x - y ‖}) x - \frac{r}{‖ x - y ‖} y, (1 - \frac{r}{‖ x - y ‖}) x + \frac{r}{‖ x - y ‖} y \in S_{X},$
  
  reaching the contradiction that
  
  $\begin{matrix} 2 & = & diam (B_{X}) \\ \geq & ∥[(1 - \frac{r}{‖ x - y ‖}) x + \frac{r}{‖ x - y ‖} y] - [(1 + \frac{r}{‖ x - y ‖}) x - \frac{r}{‖ x - y ‖} y]∥ \\ = & ∥2 \frac{r}{‖ x - y ‖} (y - x)∥ = 2 r > 2 . \end{matrix}$
- $[(1 + \frac{r}{‖ x - y ‖}) x - \frac{r}{‖ x - y ‖} y, (1 - \frac{r}{‖ x - y ‖}) x + \frac{r}{‖ x - y ‖} y] ⊊ [u, v]$ . In this case, either u or v is in in the interior of the segment
  
  $((1 + \frac{r}{‖ x - y ‖}) x - \frac{r}{‖ x - y ‖} y, (1 - \frac{r}{‖ x - y ‖}) x + \frac{r}{‖ x - y ‖} y) .$
  
  By Remark 10,
  
  $((1 + \frac{r}{‖ x - y ‖}) x - \frac{r}{‖ x - y ‖} y, (1 - \frac{r}{‖ x - y ‖}) x + \frac{r}{‖ x - y ‖} y) \subseteq U_{X} (x, r) .$
  
  We can assume without any loss of generality that $u \in U_{X} (x, r)$ . Let $δ > 0$ such that $B_{X} (u, δ) \subseteq U_{X} (x, r)$ . Notice that $[u, v] \subseteq f^{- 1} ({1})$ since $[x, y] \subseteq [u, v]$ and $[x, y] \subseteq B_{X} (x, r) \cap S_{X} \subseteq f^{- 1} ({1})$ . In accordance with Lemma 4(2), $u \in cl (S_{X} ∖ f^{- 1} ({1}))$ , so we can find $u^{'} \in (S_{X} ∖ f^{- 1} ({1})) \cap B_{X} (u, δ) \subseteq U_{X} (x, r) \subseteq B_{X} (x, r)$ . Finally, $u^{'} \in (B_{X} (x, r) \cap S_{X}) ∖ f^{- 1} ({1})$ , which contradicts our hypothesis that $B_{X} (x, r) \cap S_{X} \subseteq f^{- 1} ({1})$ .
As a consequence, $r \leq 1$ . Notice that, with $r \leq 1$ , for every $y \in (B_{X} (x, r) \cap S_{X}) ∖ {x}$ the first one of the above two bullets is possible, but not the second one, which implies that

$[(1 + \frac{r}{‖ x - y ‖}) x - \frac{r}{‖ x - y ‖} y, (1 - \frac{r}{‖ x - y ‖}) x + \frac{r}{‖ x - y ‖} y] \subseteq S_{X} .$
Suppose to the contrary that $r > 1$ . Since $dim (X) \geq 2$ , we can find

$y \in (B_{X} (x, r) \cap f^{- 1} ({1})) ∖ {x} .$

Suppose that $‖ y - x ‖ > 1$ . Then $2 x - y \in B_{X} (x, r) \cap f^{- 1} ({1}) \subseteq S_{X}$ . Therefore, we reach the contradiction that

$2 = diam (B_{X}) \geq ‖ (2 x - y) - y ‖ = 2 ‖ x - y ‖ > 2 .$

If $‖ y - x ‖ \leq 1$ , then

$z : = \frac{r}{‖ y - x ‖} y + (1 - \frac{r}{‖ y - x ‖}) x \in B_{X} (x, r) \cap f^{- 1} ({1})$

and $‖ z - x ‖ = r > 1$ . By using the same reasoning as before, we reach the contradiction that $diam (B_{X}) > 2$ . As a consequence, $r \leq 1$ . Finally, let us show the existence of $0 < s < r$ such that $B_{X} (x, s) \cap S_{X} \subseteq f^{- 1} ({1})$ . Take $0 < s < r$ such that $s + \frac{s}{1 - s} \leq r$ . Take any $y \in B_{X} (x, s) \cap S_{X}$ . Observe that $f (y) = f (x) - f (x - y) = 1 - f (x - y) \geq 1 - ‖ x - y ‖ \geq 1 - s$ . Next,

$\begin{matrix} ∥x - \frac{y}{f (y)}∥ & \leq & ‖ x - y ‖ + ∥y - \frac{y}{f (y)}∥ \\ = & ‖ x - y ‖ + \frac{∥f (y) y - y∥}{| f (y) |} \\ = & ‖ x - y ‖ + \frac{|f (y) - 1| ‖ y ‖}{| f (y) |} \\ = & ‖ x - y ‖ + \frac{|f (y) - f (x)|}{| f (y) |} \\ \leq & ‖ x - y ‖ + \frac{∥y - x∥}{| f (y) |} \\ \leq & s + \frac{s}{1 - s} \\ \leq & r . \end{matrix}$

Therefore, $\frac{y}{f (y)} \in B_{X} (x, r) \cap f^{- 1} ({1}) \subseteq S_{X}$ . As a consequence, $∥\frac{y}{f (y)}∥ = 1$ , which implies that $f (y) = 1$ .

□

The following proposition is an extension of ([27], Lemma 2.1).

Proposition 1.

Let X be a normed space. Let

C \subset S_{X}

be a convex subset, and let

f \in S_{X^{*}}

such that

C \subseteq F (f)

. Then

{int}_{S_{X}} (C) = {int}_{f^{- 1} ({1})} (C)

and

{bd}_{S_{X}} (C) = {bd}_{f^{- 1} ({1})} (C)

. In particular,

E (f) = {bd}_{S_{X}} (F (f))

.

Proof.

Fix an arbitrary

x \in {int}_{S_{X}} (C) \neq ⌀

. There exists

r > 0

such that

B_{X} (x, r) \cap S_{X} \subseteq C

. We will show that

B_{X} (x, \frac{r}{2}) \cap f^{- 1} ({1}) \subseteq C

, which implies that

x \in {int}_{f^{- 1} ({1})} (C)

. For this, by taking into consideration that

B_{X} (x, r) \cap S_{X} \subseteq C

, it only suffices to show that

B_{X} (x, \frac{r}{2}) \cap f^{- 1} ({1}) \subseteq S_{X}

, which is already given by Lemma 4(1). Conversely, fix an arbitrary

x \in {int}_{f^{- 1} ({1})} (C) \neq ⌀

. There exists

r > 0

such that

B_{X} (x, r) \cap f^{- 1} ({1}) \subseteq C

. In view of Lemma 4(4), we know that

r \leq 1

and there exists

0 < s < r

such that

B_{X} (x, s) \cap S_{X} \subseteq f^{- 1} ({1})

. We will prove that

B_{X} (x, s) \cap S_{X} \subseteq C

, which implies that

x \in {int}_{S_{X}} (C)

. However, by taking into consideration that

B_{X} (x, r) \cap f^{- 1} ({1}) \subseteq C

, it only suffices with

B_{X} (x, s) \cap S_{X} \subseteq f^{- 1} ({1})

. Finally, since both

S_{X}

and

f^{- 1} ({1})

are closed in X, we have that

cl (C) = {cl}_{S_{X}} (C) = {cl}_{f^{- 1} ({1})} (C)

, therefore

{bd}_{S_{X}} (C) = {cl}_{S_{X}} (C) ∖ {int}_{S_{X}} (C) = {cl}_{f^{- 1} ({1})} (C) ∖ {int}_{f^{- 1} ({1})} (C) = {bd}_{f^{- 1} ({1})} (C) .

□

Lemma 5.

Let X be a normed space. If

C \subset S_{X}

is a facet, then:

C is a convex component of $S_{X}$ , that is, a maximal convex subset of $S_{X}$ .
There exists a unique $f \in S_{X^{*}}$ such that $C \subseteq F (f)$ , which verifies that $C = F (f)$ .
If $c \in {int}_{S_{X}} (C)$ and $f \in ν (c)$ , then $C = F (f)$ .
${int}_{S_{X}} (C) \subseteq smo (B_{X})$ .
If $c \in i n t_{S_{X}} (C)$ and $f \in ν (c)$ , then $C - c$ is a closed convex neighbourhood of 0 in $ker (f)$ . In particular, ${int}_{S_{X}} (C)$ is dense in C and $inn (C) = {int}_{S_{X}} (C)$ .

Proof.

Let D be a convex subset of $S_{X}$ strictly containing C. Fix an arbitrary $d \in D ∖ C$ . Take any $c \in {int}_{S_{X}} (C)$ . By relying on the Hahn-Banach Separation Theorem, there exists $f \in S_{X^{*}}$ such that $C \subseteq D \subseteq F (f)$ . In view of Proposition 1, $c \in {int}_{S_{X}} (C) = {int}_{f^{- 1} ({1})} (C)$ , so there exists a ball $B_{X} (c, r)$ such that $B_{X} (c, r) \cap f^{- 1} ({1}) \subseteq C$ . There exists $t > 1$ sufficiently closed to 1 such that $t c + (1 - t) d \in B_{X} (c, r)$ . Notice that $t c + (1 - t) d \in f^{- 1} ({1})$ , thus $t c + (1 - t) d \in B_{X} (c, r) \cap f^{- 1} ({1}) \subseteq C$ . Since C is a face of $B_{X}$ , we conclude that $d \in C$ .
The maximality of C already implies the existence of $f \in S_{X^{*}}$ such that $C = F (f)$ . Suppose that there exists other $g \in S_{X^{*}}$ such that $C = F (g)$ . In view of Proposition 1, we have that ${int}_{S_{X}} (C) = {int}_{f^{- 1} ({1})} (C) = {int}_{g^{- 1} ({1})} (C)$ . Fix any arbitrary $c \in i n t_{S_{X}} (C)$ . Observe that ${int}_{ker (f)} (C - c) = {int}_{ker (g)} (C - c) .$ Next, observe that $C \subseteq f^{- 1} ({1}) \cap g^{- 1} ({1})$ , thus $C - c \subseteq ker (f) \cap ker (g)$ . This implies that $ker (f) = ker (g)$ and so $f = g$ .
Suppose that there exists $y \in C ∖ F (f)$ . Then $f (y) < 1$ . Take $g \in S_{X^{*}}$ such that $C = F (g)$ . According to Proposition 1, we can fix $r > 0$ such that $B_{X} (c, r) \cap g^{- 1} ({1}) \subseteq C$ . We can find $t < 0$ sufficiently closed to 0 such that $t y + (1 - t) c \in B_{X} (c, r)$ .Note that $y, c \in C = F (g)$ , thus $t y + (1 - t) c \in F (g) = C$ . As a consequence, $t y + (1 - t) c \in B_{X} (c, r) \cap g^{- 1} ({1}) \subseteq C \subseteq S_{X}$ . However, we obtain the contradiction $1 \geq f (t y + (1 - t) c) = t f (y) + 1 - t = 1 - t (1 - f (y)) > 1$ .
If $c \in {int}_{S_{X}} (C)$ and $f, g \in ν (c)$ , then by the previous item $C = F (f) = F (g)$ . Finally, by (2) we have that $f = g$ . This shows that $x \in smo (B_{X})$ .
It only suffices to take into consideration that ${int}_{S_{X}} (C) = {int}_{f^{- 1} ({1})} (C)$ and that the translation

$\begin{matrix} X & \to & X \\ x & \mapsto & x - c \end{matrix}$

is a homeomorphism mapping $f^{- 1} ({1})$ to $ker (f)$ , C to $C - c$ , ${int}_{f^{- 1} ({1})} (C)$ to ${int}_{ker (f)} (C - c)$ , and c to 0. In order to show that ${int}_{S_{X}} (C)$ is dense in C, note that $C - c$ is a convex set with non-empty interior in $ker (f)$ , so it is well known that ${cl}_{ker (f)} ({int}_{ker (f)} (C - c)) = {cl}_{ker (f)} (C - c) .$ Thus, by undoing the translation, we obtain $cl ({int}_{S_{X}} (C)) = cl ({int}_{f^{- 1} ({1})} (C)) = {cl}_{f^{- 1} ({1})} ({int}_{f^{- 1} ({1})} (C)) = {cl}_{f^{- 1} ({1})} (C) = cl (C) .$ Finally, let us see that $inn (C) = {int}_{S_{X}} (C)$ . Indeed, we use again the fact that $C - c$ is a convex set with non-empty interior in $ker (f)$ , so we call on ([33], Lemma 5(6)) to conclude that $inn (C - c) = {int}_{ker (f)} (C - c)$ . Since translations preserve inner points ([30], Proposition 1.3), we conclude that $inn (C) = {int}_{f^{- 1} ({1})} (C) = {int}_{S_{X}} (C)$ .

□

The final result in this section is a characterization of frames. This characterization serves to provide an immediate proof of ([10], Theorem 3.7) (see also Theorem 4).

Theorem 7.

Let X be a normed space. Then

frm (B_{X}) = S_{X} ∖ ⋃_{C \in C_{X}} {int}_{S_{X}} (C) .

Proof.

We will strongly rely on Proposition 1. Let

x \in S_{X} ∖ ⋃_{C \in C_{X}} {int}_{S_{X}} (C)

. By Hahn-Banach, there exists

x^{*} \in S_{X^{*}}

such that

x \in F (x^{*})

. If

{int}_{S_{X}} (F (x^{*})) = ⌀

, then

F (x^{*}) = E (x^{*})

, so

x \in E (x^{*}) \subseteq frm (B_{X})

. If

{int}_{S_{X}} (F (x^{*})) \neq ⌀

, then

F (x^{*}) \in C_{X}

, therefore

x \notin {int}_{S_{X}} (F (x^{*}))

therefore

x \in F (x^{*}) ∖ {int}_{S_{X}} (F (x^{*})) = {bd}_{S_{X}} (F (x^{*})) = E (x^{*})

. Conversely, let

x \in frm (B_{X})

. Suppose on the contrary that there exists

C \in C_{X}

such that

x \in {int}_{S_{X}} (C)

. Since

{int}_{S_{X}} (C) \subseteq smo (B_{X})

, there exists a unique

f \in S_{X^{*}}

such that

C = F (f)

. By hypothesis, there exists

g \in S_{X^{*}}

such that

x \in E (g) \subseteq F (g)

. Since x is a smooth point,

f = g

, which produces the following contradiction:

x \in {int}_{S_{X}} (C) = {int}_{S_{X}} (F (g))

and

x \in {bd}_{S_{X}} (F (g))

. □

As a direct consequence of Theorem 7, we obtain the following corollary, the details of whose proof we spare to the reader as a simple topology exercise.

Corollary 4.

Let X be a normed space. The following conditions are equivalent:

${int}_{S_{X}} (frm (B_{X})) = ⌀$ .
$⋃_{C \in C_{X}} {int}_{S_{X}} (C)$ is dense in $S_{X}$ .

3.3. Flatness

In ([42], Definition 11), the notion of starlike hull was introduced and studied for general starlike sets. Here, we propose the term of starlike envelope for subsets of the unit sphere of a normed space, which fits our purposes much better.

Definition 17.

Let X be a normed space. Let

E \subseteq S_{X}

. The starlike envelope of E is defined as

s t (E) : = ⋂_{e \in E} s t (e, B_{X}) .

Furthermore, we will say that:

E is almost flat if $[e, f] \subseteq S_{X}$ for all $e, f \in E$ .
E is flat if $co (E) \subseteq S_{X}$ .
E is starlike compatible if $E \subseteq s t (E)$ .
E is starlike generated if $E = s t (E)$ .

It is clear that every flat set is almost flat. It is also trivial to check that a subset of the unit sphere is almost flat if and only if E is starlike compatible. We will explore next the relations between the previous concepts and will provide an example of a unit ball in

R^{3}

containing an almost flat set which is not flat.

Notice that convex subsets of the unit sphere are trivially flat. In general, any subset of the unit sphere who is contained in a convex subset of the unit sphere is flat. As a consequence, in view of the Hahn-Banach Separation Theorem, a subset of the unit sphere is flat if and only if it is contained in a exposed face of the unit ball.

Lemma 6.

Let X be a normed space. Let

E \subseteq S_{X}

. Then:

If E is convex, then E is flat and starlike compatible.
E is almost flat if and only if E is starlike compatible.
If E is flat, then E is almost flat.
E is flat if and only if $co (E) \subseteq s t (E)$ .
If E is flat and D is a convex component of $S_{X}$ containing E, then $D \subseteq s t (E)$ .
If E is a convex component of $S_{X}$ , then E is starlike generated.
If E is convex and starlike generated, then E is a convex component.

Proof.

It is trivial that E is flat. In order to check that E is starlike compatible, it only suffices to notice that if $e, f \in E$ , then $[e, f] \subseteq S_{X}$ , therefore $f \in s t (e, B_{X})$ , that is, $E \subseteq s t (e, B_{X})$ for all $e \in E$ .
Immediate by bearing in mind (2).
Trivial by definition.
Suppose first that E is flat, then $co (E) \subseteq S_{X}$ , so $[x, e] \subseteq co (E) \subseteq S_{X}$ for all $x \in co (E)$ , meaning that $x \in s t (e, B_{X})$ for all $x \in co (E)$ and all $e \in E$ , that is, $co (E) \subseteq s t (E)$ . Conversely, assume that $co (E) \subseteq s t (E)$ , then $co (E) \subseteq s t (E) \subseteq S_{X}$ , so E is flat.
Fix an arbitrary $d \in D$ . For every $e \in E$ , $[e, d] \subseteq D \subseteq S_{X}$ , thus $d \in s t (E)$ . The arbitrariness of $d \in D$ means that $D \subseteq s t (E)$ .
We know by (1) that $E \subseteq s t (E)$ . Fix an arbitrary $x \in s t (E)$ . Notice that

$co (E \cup {x}) = ⋃_{e \in E} [e, x] \subseteq S_{X}$

because $[x, e] \subseteq S_{X}$ for all $e \in E$ . The maximality of E implies that $E = co ({x} \cup E)$ , so $x \in E$ . This shows that $E = s t (E)$ , hence E is starlike generated.
By (1) we know that E is flat. Let us show now that E is a convex component of $S_{X}$ . Indeed, let D be any convex subset of $S_{X}$ containing E. Fix an arbitrary $d \in D$ . Take any $e \in E$ . Then $[d, e] \subseteq D \subseteq S_{X}$ . By (2), $d \in s t (e, B_{X})$ . The arbitrariness of $e \in E$ shows that

$d \in ⋂_{e \in E} s t (e, B_{X}) = s t (E) = E .$

The arbitrariness of $d \in D$ implies that $D \subseteq E$ . This proves that E is a convex component of $S_{X}$ .

□

Example 3

(Almost flat set which is not flat). This example serves to show the existence of almost flat sets which are not flat. It strongly relies on Remark 9 and Lemma 1. The unit ball displayed in the next figures is a convex polyhedron whose facets are equilateral triangles and diamonds. An easy way to construct this unit ball is by taking a regular octahedron and placing a regular tetrahedron (with the same triangles) on top and the opposite tetrahedron on the bottom. If E denotes the set of all four vertices of the top regular tetrahedron, then E is clearly almost flat but not flat, since

co (E)

is the whole regular tetrahedron, which is clearly not contained in the boundary of the previous unit ball.

The previous example motivates the following definition.

Definition 18

(Flat property). A normed space is said to have the flat property or the F-property (Fp) if every almost flat subset of its unit sphere is flat.

Example 3 shows the existence of Banach spaces lacking the Fp. In fact, the next theorem shows that every Banach space with dimension greater than or equal to 3 can be equivalently renormed to fail Fp.

Theorem 8.

Let X be a Banach space with

dim (X) \geq 3

. There exists an equivalent norm on X for which X fails Fp.

Proof.

Let Y be a 3-dimensional subspace of X. There exists a closed subspace Z of X such that

X = Y \oplus Z

. Since Y is isomorphic to the 3-dimensional Banach space given in Example 3, we may endow Y with the equivalent norm provided by the unit ball of Example 3, which we can call

Y^{'}

. If we keep the same norm in Z, then X is clearly isomorphic to

X^{'} : = Y^{'} \oplus_{2} Z

, which trivially fails Fp because so does

Y^{'}

. □

The following lemma shall be an useful tool to determine conditions for a convex subset of the unit ball to be contained in the unit sphere. It also provides a sufficient condition for an almost flat set to be flat.

Lemma 7.

Let X be a normed space. Let D be a convex subset of

B_{X}

. Then:

If $inn (D) \cap S_{X} \neq ⌀$ , then $D \subseteq S_{X}$ .
If $D \subseteq S_{X}$ is almost flat and there exists $d \in D$ such that $d \in inn (co (D))$ , then D is flat.

Proof.

Fix $d_{0} \in inn (D) \cap S_{X}$ . Take any $d \in D ∖ {d_{0}}$ . By hypothesis, there exists $e \in D ∖ {d_{0}, d}$ such that $d_{0} \in (d, e)$ . Since $d, e \in D \subseteq B_{X}$ , it must necessarily occur that $[d, e] \subseteq S_{X}$ .
Notice that $d \in inn (co (D)) \cap S_{X}$ , thus, by Lemma 7(1), $co (D) \subseteq S_{X}$ .

□

Lemma 8(1) constitutes the generalization of ([3], Lemma 2) to infinite dimensions. Lemma 8(2,5) are the infinite dimensional version of ([3], Corollary 3).

Lemma 8.

Let X be a normed space. Let

E \subseteq S_{X}

. Then:

If E is a face of $B_{X}$ , $e \in inn (E)$ and $y \in S_{X}$ is so that $[e, y] \subseteq S_{X}$ , then $co (E \cup {y}) \subseteq S_{X}$ and $E \subseteq s t (y, B_{X})$ .
If E is a convex component of $S_{X}$ and there exists $e \in E$ such that E is the only convex component of $S_{X}$ containing e, then $E = s t (e, B_{X})$ .
If E is a facet of $B_{X}$ , then every $e \in {int}_{S_{X}} (E)$ satisfies that E is the only convex component of $S_{X}$ containing e.
If E is a convex component of $S_{X}$ for which there exists a dense sequence ${(e_{n})}_{n \in N}$ in E such that $e : = \sum_{n = 1}^{\infty} \frac{e_{n}}{2^{n}}$ is convergent, then E is the only convex component of $S_{X}$ containing e.
If E is a maximal face of $B_{X}$ with $inn (E) \neq ⌀$ , then every $e \in inn (E)$ satisfies that E is the only convex component of $S_{X}$ containing e.

Proof.

Observe that $co (E \cup {y}) = ⋃_{d \in E} [d, y]$ . By hypothesis, we already know that $[e, y] \subseteq S_{X}$ . So, fix an arbitrary $d \in E ∖ {e}$ . Since $e \in inn (E)$ , there exists $c \in E ∖ {e, d}$ such that $e \in (d, c)$ . If $d, c, y$ are aligned, then the convexity and the extremal condition satisfied by E force that $y \in E$ , hence we trivially obtain that $co (E \cup {y}) = E \subseteq S_{X}$ and $E \subseteq s t (y, B_{X})$ . Thus, let us assume that $d, c, y$ are not aligned. Then we can call on Remark 6 to conclude that $(e, y) \subseteq inn (co ({d, c, y}))$ . Finally, since $(e, y) \subseteq S_{X}$ , by applying Lemma 7, we have that $co ({d, c, y}) \subseteq S_{X}$ . In particular, $[d, y] \subseteq S_{X}$ . The arbitrariness of $d \in E ∖ {e}$ shows that $co (E \cup {y}) \subseteq S_{X}$ , hence $E \subseteq s t (y, B_{X})$ .
We know by Lemma 6(1) that $E \subseteq s t (e, B_{X})$ . Take any $x \in s t (e, B_{X})$ . Then $‖ x + e ‖ = 2$ , that is, $[x, e] \subseteq S_{X}$ . We can find a convex component D of $S_{X}$ containing $[x, e]$ . By hypothesis, $E = D$ , thus $x \in E$ .
It is sufficient to call on Lemma 5(3) to conclude that every $e \in {int}_{S_{X}} (E)$ is a smooth point of $B_{X}$ and then it clearly satisfies that E is the only convex component of $S_{X}$ containing e.
Let $D \subseteq S_{X}$ be a convex component of $S_{X}$ containing e. There exists a functional $g \in S_{X^{*}}$ such that $D = F (g)$ . Since $e \in D$ , we have that $g (e) = 1$ , which implies that $g (e_{n}) = 1$ for all $n \in N$ . The density of ${(e_{n})}_{n \in N}$ in E assures that $g (E) = {1}$ , in other words, $E \subseteq F (g) = D$ . This fact contradicts the maximality of E.
Let F be another maximal face of $B_{X}$ containing e. Fix any arbitrary $d \in E ∖ {e}$ . There exists $c \in E ∖ {d, e}$ such that $e \in (d, c)$ . The extremal condition satisfied by F forces that $d, c \in F$ . The arbitrariness of $d \in E ∖ {e}$ implies that $E \subseteq F$ . The maximality of E means that $E = F$ .

□

Theorem 9.

Let X be a normed space. For every

x \in S_{X}

,

s t (x, B_{X})

satisfies the extremal condition with respect to

B_{X}

. Even more, if

s t (x, B_{X})

is convex, then

s t (x, B_{X})

is the only maximal face of

B_{X}

containing x.

Proof.

Take any

x_{1}, x_{2} \in B_{X}

and

t \in (0, 1)

such that

t x_{1} + (1 - t) x_{2} \in s t (x, B_{X})

. By

()

, there exists a maximal face C such that

t x_{1} + (1 - t) x_{2} \in C

, in particular, C satisfies the extremal condition, which implies that

x_{1}, x_{2} \in C \subseteq s t (x, B_{X})

. Now suppose that

s t (x, B_{X})

is also convex, and therefore it is a face by definition. Let D be a maximal face of

B_{X}

containing x. By using again (2),

D \subseteq s t (x, B_{X})

. As a consequence,

s t (x, B_{X})

is the only maximal face of

B_{X}

containing x. □

The set of rotund points of the unit ball can be described in terms of starlike sets.

Remark 11.

Let X be a normed space. Then

rot (B_{X}) = \{x \in S_{X} : s t (x, B_{X}) = {x}\} .

The following result combined with Theorem 9 constitute a generalization of ([43], Lemma 2.7).

Theorem 10.

Let X be a normed space. If

x \in smo (B_{X})

, then

s t (x, B_{X})

is convex. Even more,

s t (x, B_{X}) = F (ν (x))

.

Proof.

The smoothness of x implies that there is only one exposed face of

B_{X}

containing x, which is precisely

F (ν (x))

, hence there is only one maximal face of

B_{X}

containing x. By (2),

s t (x, B_{X})

coincides with that maximal face. □

3.4. Preservation of Flatness and Faces under Surjective Isometries

We will begin by providing a very simple proof of ([10], Theorem 3.7), by simply relying on Theorem 1, Remark 2, and Theorem 7.

Theorem 11.

If

T : S_{X} \to S_{Y}

is a surjective isometry between the unit spheres of Banach spaces

X, Y

, then

T (frm (B_{X})) = frm (B_{Y})

.

Proof.

By relying on Theorem 7, by taking into consideration that T is a homeomorphism, and by noticing that

T (C_{X}) = C_{Y}

(see Theorem 1 together with Remark 2), we have that

\begin{matrix} T (frm (B_{X})) & = & T (S_{X} ∖ ⋃_{C \in C_{X}} {int}_{S_{X}} (C)) = T (S_{X}) ∖ ⋃_{C \in C_{X}} T ({int}_{S_{X}} (C)) \\ = & T (S_{X}) ∖ ⋃_{C \in C_{X}} {int}_{S_{Y}} (T (C)) = S_{Y} ∖ ⋃_{D \in C_{Y}} {int}_{S_{Y}} (D) \\ = & frm (B_{Y}) . \end{matrix}

□

Example 4.

Let X be a Banach space such that the frame of its unit ball has empty interior relative to the unit sphere, that is,

{int}_{S_{X}} (frm (B_{X})) = ⌀

. If Y is another Banach space such that there exists a surjective isometry

T : S_{X} \to S_{Y}

, then

T (frm (B_{X})) = frm (B_{Y})

according to Theorem 11. Even more, since T is a homeomorphism, we conclude that

{int}_{S_{Y}} (frm (B_{Y})) = {int}_{S_{Y}} (T (frm (B_{X}))) = T ({int}_{S_{X}} (frm (B_{X}))) = T (⌀) = ⌀ .

We would like to make the reader beware that Theorem 12(2) and Theorem 12(5) state the same sentence in view of Lemma 6(2). We have just included both items in the following theorem because Theorem 12(5) does not need to rely on Theorem 3 whereas Theorem 12(2) does.

Theorem 12.

Let

X, Y

be Banach spaces and let

T : S_{X} \to S_{Y}

be a surjective isometry. Let

E \subseteq S_{X}

. Then:

$T (s t (E)) = s t (T (E))$ .
If E is starlike compatible, then $T (E)$ is starlike compatible.
If E is starlike generated, then $T (E)$ is starlike generated.
If E is flat, then $T (E)$ is flat.
If E is almost flat, then $T (E)$ is almost flat.

Proof.

Simply keep in mind Theorem 3 to observe that

$\begin{matrix} T (s t (E)) & = & T (⋂_{e \in E} s t (e, B_{X})) = ⋂_{e \in E} T (s t (e, B_{X})) \\ = & ⋂_{e \in E} s t (T (e), B_{Y}) = ⋂_{d \in T (E)} s t (d, B_{Y}) = s t (T (E)) . \end{matrix}$
By definition, $E \subseteq s t (E)$ , so $T (E) \subseteq T (s t (E)) = s t (T (E))$ , meaning that $T (E)$ is starlike compatible.
Follows a similar proof as right above.
By definition, $co (E) \subseteq S_{X}$ . Let D be a convex component of $S_{X}$ containing $co (E)$ . In view of Theorem 1, $T (D)$ is a convex component of $S_{Y}$ . Since $E \subseteq co (E) \subseteq D$ , we obtain that $T (E) \subseteq T (co (E)) \subseteq T (D)$ . The convexity of $T (D)$ allows that $co (T (E)) \subseteq T (D) \subseteq S_{Y}$ , meaning that $T (E)$ is flat.
Fix arbitrary elements $e, f \in E$ . We have to prove that $[T (e), T (f)] \subseteq S_{Y}$ . By hypothesis, since E is almost flat, we have that $[e, f] \subseteq S_{X}$ . There exists a convex component F of $S_{X}$ containing $[e, f]$ . By Theorem 1, $T (F)$ is a maximal face of $B_{Y}$ . Notice also that $T ([e, f]) \subseteq T (F)$ since $[e, f] \subseteq F$ . Therefore, $T (e), T (f) \in T (F)$ . Finally, the convexity of $T (F)$ allows that $[T (e), T (f)] \subseteq T (F) \subseteq S_{Y}$ .

□

Example 5.

Let us consider

R^{3}

endowed with the unit ball given in Example 3. In the first place, note that this unit ball is a convex polyhedron, therefore,

R^{3}

endowed with this unit ball satisfies MUp by keeping in mind ([8], Theorem 4.5). On the other hand, we have already seen in Example 3 that the set E consisting of all four vertices of the top regular tetrahedron is almost flat but not flat. Finally, any of the diamonds that compose the boundary of the unit ball is a maximal convex component, hence starlike generated in view of Lemma 6(6).

Let X be a normed space. For every flat subset C of

S_{X}

, we will denote

M_{C} : = \{D \subseteq S_{X} : D is a maximal face of B_{X} containing C\} .

Notice that

M_{C} = M_{co (C)}

. If

C = {c}

is a singleton, then we will simply write

M_{c}

. The following result relies on Theorem 1.

Theorem 13.

Let

X, Y

be Banach spaces and consider a surjective isometry

T : S_{X} \to S_{Y}

. Let E be a flat subset of

S_{X}

. Then:

$T (M_{E}) = M_{T (E)}$ .
If X has Pp and E is a face of $B_{X}$ , then $T (E)$ is a face of $B_{Y}$ .

Proof.

Fix any arbitrary $D \in M_{E}$ . By Theorem 1, $T (D)$ is a maximal face of $B_{Y}$ containing $T (E)$ . Therefore, $T (D) \in M_{T (E)}$ . This shows that $T (M_{E}) \subseteq M_{T (E)}$ . The reverse inclusion can be accomplished by using $T^{- 1}$ .
By hypothesis, since X has Pp, $E = ⋂_{D \in M_{E}} D$ . Next, $T (E)$ is flat by Theorem 12(4), therefore, $T (M_{E}) = M_{T (E)}$ by (1). Notice,

$T (E) = T (⋂_{D \in M_{E}} D) = ⋂_{D \in M_{E}} T (D) = ⋂_{C \in M_{T (E)}} C .$

This means that $T (E)$ is an intersection of (maximal) faces of $B_{Y}$ , thus $T (E)$ is a face of $B_{Y}$ .

□

Lemma 9.

Let X be a normed space and let

x, y \in S_{X}

. Then:

If $ν (x) \subseteq ν (y)$ , then $M_{x} \subseteq M_{y}$ .
If $x, y \in smo (B_{X})$ and $M_{x} \subseteq M_{y}$ , then $M_{x} = M_{y}$ and $ν (x) = ν (y)$ .
$s t (x, B_{X}) \subseteq s t (y, B_{X})$ if and only if $M_{x} \subseteq M_{y}$ .
$s t (x, B_{X}) = s t (y, B_{X})$ if and only if $M_{x} = M_{y}$ .

Proof.

Take any $D \in M_{x}$ . Since maximal faces are exposed faces, there exists $f \in S_{X^{*}}$ such that $D = F (f)$ . Then $f \in ν (x) \subseteq ν (y)$ . This implies that $f (y) = 1$ , hence $y \in F (f) = D$ and $D \in M_{y}$ .
In accordance with Theorems 9 and 10, we have that $M_{x} = {s t (x, B_{X})}$ and $M_{y} = {s t (y, B_{X})}$ , so both $M_{x}$ and $M_{y}$ are singletons, so they must be equal because $M_{x} \subseteq M_{y}$ . By calling again on Theorem 10, we have that $F (ν (x)) = s t (x, B_{X}) = s t (y, B_{X}) = F (ν (y))$ . The smoothness of x and y forces that $ν (x) = ν (y)$ .
Suppose first that $s t (x, B_{X}) \subseteq s t (y, B_{X})$ . Let $D \in M_{x}$ . It is clear that $D \subseteq s t (x, B_{X})$ in view of (2). We will show that $co (D \cup {y}) \subseteq S_{X}$ . Indeed, notice that $co (D \cup {y}) = ⋃_{d \in D} [d, y]$ . Notice that, by assumption $D \subseteq s t (x, B_{X}) \subseteq s t (y, B_{X})$ , so $[d, y] \subseteq S_{X}$ for every $d \in D$ . As a consequence, $co (D \cup {y}) = ⋃_{d \in D} [d, y] \subseteq S_{X}$ . Since D is a maximal face of $B_{X}$ , we conclude that $co (D \cup {y}) = D$ , hence $y \in D$ . This proves that $D \in M_{y}$ . The arbitrariness of $D \in M_{x}$ shows that $M_{x} \subseteq M_{y}$ . Conversely, suppose that $M_{x} \subseteq M_{y}$ . By relying again on (2), we have that

$s t (x, B_{X}) = ⋃ M_{x} \subseteq ⋃ M_{y} = s t (y, B_{X}) .$
It is a direct consequence of Lemma 9(3).

□

The converse to Lemma 9(1) does not hold true as shown in the following example.

Example 6.

Let

X : = R^{2}

endowed with the norm provided by the unit ball resulting from the intersection of the Euclidean ball

B_{ℓ_{2}^{2}}

with the band

\{(x_{1}, x_{2}) \in R^{2} : - \frac{1}{2} \leq x_{2} \leq \frac{1}{2}\}

. Take

x : = (\frac{\sqrt{3}}{2}, \frac{1}{2})

and

y : = (0, \frac{1}{2})

. Notice that

M_{x} = M_{y} = \{[(\frac{- \sqrt{3}}{2}, \frac{1}{2}), (\frac{\sqrt{3}}{2}, \frac{1}{2})]\}

. However,

ν (x) ⊈ ν (y)

because

y \in smo (B_{X})

and

x \notin smo (B_{X})

, which implies that

ν (y)

is a singleton and

ν (x)

is infinite.

Corollary 5.

Let

X, Y

be Banach spaces and let

T : S_{X} \to S_{Y}

be a surjective isometry. If Y is smooth, then

ν (T (- x)) = - ν (T (x))

.

Proof.

On the one hand,

T (s t (x, B_{X})) = (- T (- x), B_{Y})

by Remark 4. On the other hand,

T (s t (x, B_{X})) = s t (T (x), B_{X})

by Theorem 3. By combining the two previous equalities, we obtain that

s t (- T (- x), B_{Y}) = s t (T (x), B_{Y})

. In accordance with Lemma 9(4),

M_{- T (- x)} = M_{T (x)}

, and Lemma 9(2) assures that

- ν (T (- x)) = ν (- T (- x)) = ν (T (x))

. □

The following result provides a very simple proof of Theorem 1 for singleton maximal faces of the unit ball. Recall that singleton maximal faces of the unit ball are precisely the rotund points.

Theorem 14.

Let

X, Y

be Banach spaces and let

T : S_{X} \to S_{Y}

be a surjective isometry. Then

T (rot (B_{X})) = rot (B_{Y})

. Even more,

T (- x) = - T (x)

for all

x \in rot (B_{X})

.

Proof.

Fix an arbitrary

x \in rot (B_{X})

. Since

{x}

is a maximal face of

B_{X}

, we have that

{x} = s t (x, B_{X})

(see Remark 11). Then, by Remark 4,

{T (x)} = T (s t (x, B_{X})) = s t (- T (- x), B_{Y}) .

Since

- T (- x) \in s t (- T (- x), B_{Y})

, we conclude that

- T (- x) = T (x)

and

{- T (- x)} = s t (- T (- x), B_{Y})

, which implies that

- T (- x) \in rot (B_{Y})

in virtue of Remark 11, hence

T (- x) \in rot (B_{Y})

. If we repeat the same argument with

- x \in rot (B_{X})

, we end up having that

T (x) \in rot (B_{Y})

. This shows that

T (rot (B_{X})) \subseteq rot (B_{Y})

. By using the same reasoning with

T^{- 1}

, we obtain the desired equality. □

Corollary 6.

Let

X, Y

be Banach spaces and let

T : S_{X} \to S_{Y}

be a surjective isometry. If X is strictly convex, then so is Y.

The previous results motivate the following definition.

Definition 19

(Inner property). A normed space X is said to have the inner property or the I-property (Ip) if it is strictly convex or all the non-singleton maximal faces of

B_{X}

have inner points.

According to ([30], Theorem 5.1), every finite dimensional Banach space satisfies the Ip. The following example shows the existence of infinite dimensional Banach spaces lacking the Ip.

Example 7.

A Banach space X is called transitive if for every

x, y \in S_{X}

there exists a surjective linear isometry

T : X \to X

such that

T (x) = y

. In ([44], Corollary 2.21), it is shown that every Banach space can be isometrically regarded as a subspace of a suitable transitive Banach space. With this in hand, if we take any non-strictly convex Banach space Y, there exists a transitive Banach space X such that X contains a subspace isomometrically isomorphic to Y. Then X cannot be strictly convex because it contains a non-strictly convex subspace. According to ([45], Theorem 3.2), all non-singleton maximal faces of

B_{X}

are free of inner points. As a consequence, X does not satisfy the Ip.

Another example of Banach space lacking the Ip follows.

Example 8.

Consider the space of all absolute summable sequences

ℓ_{1} : = \{{(x_{n})}_{n \in N} \in R^{N} : \sum_{n = 1}^{\infty} | x_{n} | < \infty\},

with the norm given by

{∥{(x_{n})}_{n \in N}∥}_{1} : = \sum_{n = 1}^{\infty} | x_{n} | .

Notice that

D : = \{{(x_{n})}_{n \in N} \in S_{ℓ_{1}} : x_{n} \geq 0 \forall n \in N\}

is a maximal face of

B_{ℓ_{1}}

. In virtue of ([30], Theorem 5.4),

inn (D) = ⌀

. As a consequence,

ℓ_{1}

fails Ip.

The following theorem generalizes ([3], Lemmas 12 and 13) to infinite dimensions.

Theorem 15.

Let

X, Y

be Banach spaces and let

T : S_{X} \to S_{Y}

be a surjective isometry. Let

F \subseteq S_{X}

be a maximal face with

inn (F) \neq ⌀

. Then:

$T (- F) = - T (F)$ .
If there exists $x \in inn (F)$ for which there exists $E \in M_{T (x)}$ with $inn (E) \neq ⌀$ , then $T (F) \subseteq E$ .

Proof.

Fix an arbitrary $x \in inn (F)$ . In virtue of Lemma 8(2,5), we have that $F = s t (x, B_{X})$ . By Remark 6, $T (F) = T (s t (x, B_{X})) = s t (- T (- x), B_{Y})$ , so $- T (- x) \in T (F)$ , hence $T (- x) \in - T (F)$ . The arbitrariness of $x \in inn (F)$ means that $T (- inn (F)) \subseteq - T (F)$ . Since $inn (F)$ is dense in F by Remark 5, T is continuous, and $T (F)$ is closed in $S_{Y}$ , we deduce that $T (- F) \subseteq - T (F)$ . Finally, $- F$ is also a maximal face of $B_{X}$ with $inn (F) \neq ⌀$ , so $T (F) \subseteq - T (- F)$ , obtaining the desired equality.
Fix any $e \in inn (E)$ . By Lemma 8(2,5), we have that $E = s t (e, B_{Y})$ . By Remark 4, $T^{- 1} (E) = (- T^{- 1} (- e), B_{X})$ . Since $x \in T^{- 1} (E)$ , we obtain that $[x, - T^{- 1} (- e)] \subseteq S_{X}$ , hence, by Lemma 8(1), $F \subseteq (- T^{- 1} (- e), B_{X})$ . Thus, $F \subseteq T^{- 1} (E)$ and $T (F) \subseteq E$ .

□

The reader may observe that ([3], Lemma 13) has already been fully generalize to infinite dimensions in |([6], Lemma 5.1) and in ([10], Lemma 3.5) (see also Theorem 1). However, here in Corollary 7(1) we propose an alternative and simpler proof for the case that the Banach spaces satisfy the Ip. In Corollary 7(2), we propose an alternative and easier proof of Theorem 3 without having to rely on Theorem 1.

Corollary 7.

Let

X, Y

be Banach spaces and let

T : S_{X} \to S_{Y}

be a surjective isometry. Suppose that both

X, Y

satisfy the Ip. Then:

If $F \subseteq S_{X}$ is a maximal face of $B_{X}$ , then $T (F)$ is a maximal face of $B_{Y}$ .
$T (s t (x, B_{X})) = s t (T (x), B_{Y})$ for all $x \in S_{X}$ .

Proof.

If $F = {x}$ is a singleton, then $x \in rot (B_{X})$ and we only need to call on Theorem 14. Thus, let us assume that F is not a singleton. BY hypothesis, $inn (F) \neq ⌀$ , hence we can fix any $x \in inn (F)$ . Take any $E \in M_{T (x)}$ . By hypothesis, $inn (E) \neq ⌀$ , therefore, by Theorem 15(2), $T (F) \subseteq E$ . Next, take any $e \in inn (E)$ and any $D \in M_{T^{- 1} (e)}$ . Since $inn (D) \neq ⌀$ by hypothesis, we can apply again Theorem 15(2) to conclude that $T^{- 1} (E) \subseteq D$ . Thus, we end up with the chain of inclusions $F \subseteq T^{- 1} (E) \subseteq D$ . The maximality of F forces that $F = T^{- 1} (E) = D$ .
We will rely on Lemma 9, so it only suffices to prove that $M_{T (x)} = M_{- T (- x)}$ because $T (s t (x, B_{X})) = s t (- T (- x), B_{Y})$ in view of Remark 4. Indeed, let $C \in M_{T (x)}$ . Then $x \in T^{- 1} (C)$ , so $- x \in - T^{- 1} (C) = T^{- 1} (- C)$ in virtue of Theorem 15(1), therefore $T (- x) \in - C$ , that is, $- T (- x) \in C$ , hence $C \in M_{- T (- x)}$ . The arbitrariness of $C \in M_{T (x)}$ means that $M_{T (x)} \subseteq M_{- T (- x)}$ . Following a similar reasoning, we obtain the reverse inclusion, concluding with the desired equality.

□

Example 9.

According to Example 7, there exists a Banach space X which is transitive, not strictly convex, and whose unit ball

B_{X}

contains a maximal face C such that

inn (C) = ⌀

. Notice that

rot (B_{X}) = ⌀

, since otherwise, the transitivity of X forces that

rot (B_{X}) = S_{X}

, meaning that X is strictly convex. As a consequence,

rot (B_{X}) = ⌀

. If Y is another Banach space and

T : S_{X} \to S_{Y}

is a surjective isometry, then we can conclude that

T (C)

is a maximal face of

B_{Y}

in view of Theorem 1 and

rot (B_{Y}) = ⌀

according to Theorem 14.

Example 9 motivates the following result. First, let us recall that a topological space is said to be homogeneous provided that any two points there exists a homeomorphism on the space mapping one to another.

Theorem 16.

Let X be a transitive Banach space, Y a Banach space, and

T : S_{X} \to S_{Y}

a surjective isometry. Then

S_{Y}

is homogeneous. If, in addition, X is separable, then Y is strictly convex.

Proof.

Fix arbitrary elements

y_{1}, y_{2} \in S_{Y}

. Since X is transitive, there exists a surjective linear isometry

S : X \to X

such that

S (T^{- 1} (y_{1})) = T^{- 1} (y_{2})

. Next, it only suffices to consider the surjective isometry

T \circ S \circ T^{- 1} : S_{Y} \to S_{Y}

, which is clearly a homeormorphism and maps

y_{1}

to

y_{2}

. Finally, if X is separable, then X is strictly convex in view of ([46], Theorem 28). As a consequence, Y is strictly convex as well by bearing in mind Corollary 6. □

3.5. Invariance of Segments

This final subsection is aimed at studying the invariance of segments under surjective isometries between unit spheres.

Theorem 17.

Let

X, Y

be Banach spaces and

T : S_{X} \to S_{Y}

a surjective isometry. Let

x, y \in S_{X}

with

x \neq y

and

[x, y] \subseteq S_{X}

. If

T ([x, y])

is convex, then

T ([x, y]) = [T (x), T (y)]

and T is affine on

[x, y]

, that is,

T (t x + (1 - t) y) = t T (x) + (1 - t) T (y)

for all

t \in [0, 1]

.

Proof.

Note that

T ([x, y])

is compact and convex. In fact,

T ([x, y])

is homeomorphic to

[x, y]

. Let us prove first that

T ([x, y])

is a segment. Suppose on the contrary that

T ([x, y])

is not a segment. Since it is convex by hypothesis, it contains at least three points not aligned. Then

[x, y] ∖ \{\frac{x + y}{2}\}

is not connected, thus

T ([x, y] ∖ \{\frac{x + y}{2}\}) = T ([x, y]) ∖ \{T (\frac{x + y}{2})\}

is not connected either. However, Remark 8 assures that it is connected. As a consequence,

T ([x, y])

is a segment, so

T ([x, y]) = [a, b]

for some

a, b \in S_{Y}

. Let

t, s \in [0, 1]

in such a way that

T (t x + (1 - t) y) = a

and

T (s x + (1 - s) y) = b

. Since isometries preserve diameters, we obtain that

\begin{matrix} ‖ x - y ‖ & = & diam ([x, y]) \\ = & diam (T ([x, y])) \\ = & ‖ a - b ‖ \\ = & ‖ T (t x + (1 - t) y) - T (s x + (1 - s) y) ‖ \\ = & ‖ t x + (1 - t) y - (s x + (1 - s) y) ‖ \\ = & | t - s | ‖ x - y ‖ . \end{matrix}

Thus, the only possibility is that

| t - s | = 1

, hence either

t = 0

and

s = 1

, or

t = 0

and

s = 1

. In any case,

T ([x, y]) = [T (x), T (y)]

. Let us finally prove that T is affine on

[x, y]

. Indeed, fix an arbitrary

t \in (0, 1)

. There exists

s \in (0, 1)

such that

T (t x + (1 - t) y) = s T (x) + (1 - s) T (y)

. Following similar reasoning as above,

\begin{matrix} (1 - s) ‖ x - y ‖ & = & (1 - s) ‖ T (x) - T (y) ‖ \\ = & ‖ (s T (x) + (1 - s) T (y)) - T (x) ‖ \\ = & ‖ T (t x + (1 - t) y) - T (x) ‖ \\ = & ‖ (t x + (1 - t) y) - x ‖ \\ = & (1 - t) ‖ x - y ‖ . \end{matrix}

As a consequence, we obtain that

t = s

. □

As a direct consequence of Theorem 17 together with Theorem 1, we obtain the following corollary.

Corollary 8.

Let

X, Y

be Banach spaces and

T : S_{X} \to S_{Y}

a surjective isometry. Let

x, y \in S_{X}

with

x \neq y

and

[x, y] \subseteq S_{X}

. If

[x, y]

is a maximal face of

B_{X}

, then T is affine on

[x, y]

, that is,

T (t x + (1 - t) y) = t T (x) + (1 - t) T (y)

for all

t \in [0, 1]

.

Proof.

By Theorem 1,

T ([x, y])

is a maximal face of

B_{Y}

, so it is convex. Finally, Theorem 17 does the rest. □

Example 10.

In ([47], Example 3.8), a 3-dimensional Banach space was constructed whose unit ball only contains rotund points except for two maximal segments. These two maximal segments are, in fact, maximal faces, so this unit ball satisfies the conditions of Corollary 8.

4. Discussion

As we mention in the introduction, in ([23], Corollary 3.8) it is proved that every 2-dimensional non-strictly convex Banach space satisfies the MUp. Here, we propose the following idea to prove that every 2-dimensional strictly convex Banach space satisfies the MUp, by relying on ([23], Corollary 3.8). The idea is to make a slight perturbation on the unit ball of a strictly convex 2-dimensional Banach space to introduce a small segment in its unit sphere. This way we obtain a non-strictly convex 2-dimensional Banach space whose unit ball is very similar to the one of the strictly convex space. The point is to redefine an isometry.

This renorming technique to introduce a facet in the unit sphere has already been used in [48,49,50]. Let X be a Banach space. For every

0 < t < 1

and every

x^{*} \in X^{*}

with

‖ x^{*} ‖ = 1

,

B : = B_{X} \cap {(x^{*})}^{- 1} ([- t, t])

(6)

is a bounded, closed, absolutely convex subset of X with nonempty interior, thus it defines an equivalent norm on X,

{‖ \cdot ‖}_{B}

, satisfying that:

$B \subseteq B_{X}$ , hence $‖ \cdot ‖ \leq {‖ \cdot ‖}_{B}$ .
$int (B) = U_{X} \cap {(x^{*})}^{- 1} ((- t, t))$ .
$bd (B) = [S_{X} \cap {(x^{*})}^{- 1} ((- t, t))] \cup [B_{X} \cap {(x^{*})}^{- 1} ({- t, t})]$ .
$B_{X} \cap {(x^{*})}^{- 1} ({- t})$ and $B_{X} \cap {(x^{*})}^{- 1} ({t})$ are maximal faces of $B$ with non-empty interior relative to $bd (B)$ .

Now, let

X, Y

be Banach spaces and

T : S_{X} \to S_{Y}

a surjective isometry between their unit spheres. Now we apply the renorming given by (6) to both

X, Y

to obtain

B_{X}, B_{Y}

, respectively. In order to obtain

B_{X}

, the idea is to choose

0 < t < 1

very small and to take

x^{*} \in S_{X^{*}}

in such a way that

x^{*}

attains its norm at a smooth point a of

B_{X}

, that is,

x^{*} = ν (a)

. To obtain

B_{Y}

, we choose the same t and an element

y^{*} \in ν (T (a)) .

Next, it is precise to transport T to a surjective isometry

\tilde{T} : bd (B_{X}) \to bd (B_{Y})

in such a way that

\tilde{T} (x) = T (x)

for all

x \in S_{X} \cap {(x^{*})}^{- 1} ([- t, t])

. To accomplish this, it is necessary to compute

‖ x_{1} - x_{2} ‖_{B_{X}}

and

‖ y_{1} - y_{2} ‖_{B_{Y}}

for all

x_{1}, x_{2} \in bd (B_{X})

and all

y_{1}, y_{2} \in bd (B_{Y})

. The following technical lemmas are devoted to achieve this.

Lemma 10.

Let X be a Banach space. Let

0 < t < 1

and

x^{*} \in X^{*}

with

‖ x^{*} ‖ = 1

. Let

B : = B_{X} \cap {(x^{*})}^{- 1} ([- t, t])

. For every

x \in X ∖ {0}

,

{‖ x ‖}_{B} = \{\begin{matrix} ‖ x ‖ & if \frac{x}{{‖ x ‖}_{B}} \in S_{X} \cap {(x^{*})}^{- 1} ((- t, t)), \\ \frac{| x^{*} (x) |}{t} & if \frac{x}{{‖ x ‖}_{B}} \in B_{X} \cap {(x^{*})}^{- 1} ({- t, t}) . \end{matrix}

Proof.

Fix an arbitrary

x \in X ∖ {0}

. Notice that

\frac{x}{{‖ x ‖}_{B}} \in bd (B) = [S_{X} \cap {(x^{*})}^{- 1} ((- t, t))] \cup [B_{X} \cap {(x^{*})}^{- 1} ({- t, t})]

. Therefore, we have two possibilities:

$\frac{x}{{‖ x ‖}_{B}} \in S_{X} \cap {(x^{*})}^{- 1} ((- t, t))$ . In this case, $∥\frac{x}{{‖ x ‖}_{B}}∥ = 1$ , so $‖ x ‖ = {‖ x ‖}_{B}$ .
$\frac{x}{{‖ x ‖}_{B}} \in B_{X} \cap {(x^{*})}^{- 1} ({- t, t}) .$ In this case, $|x^{*} (\frac{x}{{‖ x ‖}_{B}})| = t$ , hence ${‖ x ‖}_{B} = \frac{| x^{*} (x) |}{t}$ .

□

Notice that, under the settings of the previous lemma, if

\frac{x}{{‖ x ‖}_{B}} \in S_{X} \cap {(x^{*})}^{- 1} ({- t, t})

, then

{‖ x ‖}_{B} = ‖ x ‖ = \frac{| x^{*} (x) |}{t}

.

Lemma 11.

Let X be a Banach space. Let

0 < t < 1

and

x^{*} \in X^{*}

with

‖ x^{*} ‖ = 1

. Let

B : = B_{X} \cap {(x^{*})}^{- 1} ([- t, t])

. Let

x, y \in bd (B)

with

x \neq y

such

x, y \in B_{X} \cap {(x^{*})}^{- 1} ({- t, t})

. Then:

If $x^{*} (x) = x^{*} (y)$ , then $\frac{x - y}{{‖ x - y ‖}_{B}} \in S_{X} \cap {(x^{*})}^{- 1} ((- t, t)) .$
If $x^{*} (x) \neq x^{*} (y)$ , then $\frac{x - y}{{‖ x - y ‖}_{B}} \in B_{X} \cap {(x^{*})}^{- 1} ({- t, t}) .$

In particular,

{‖ x - y ‖}_{B} = \{\begin{matrix} ‖ x - y ‖ & if x^{*} (x) = x^{*} (y), \\ 2 & if x^{*} (x) \neq x^{*} (y) . \end{matrix}

Proof.

Notice that

\frac{x - y}{{‖ x - y ‖}_{B}} \in bd (B) = [S_{X} \cap {(x^{*})}^{- 1} ((- t, t))] \cup [B_{X} \cap {(x^{*})}^{- 1} ({- t, t})] .

Suppose on the contrary that

$\frac{x - y}{{‖ x - y ‖}_{B}} \in B_{X} \cap {(x^{*})}^{- 1} ({- t, t}) .$

Then

$t = |x^{*} (\frac{x - y}{{‖ x - y ‖}_{B}})|$

so ${t ‖ x - y ‖}_{B} = |x^{*} (x - y)| = |x^{*} (x) - x^{*} (y)| = 0$ , which is not possible since $x \neq y$ and $t > 0$ . Therefore,

$\frac{x - y}{{‖ x - y ‖}_{B}} \in S_{X} \cap {(x^{*})}^{- 1} ((- t, t)) .$

In particular,

$∥\frac{x - y}{{‖ x - y ‖}_{B}}∥ = 1,$

so ${‖ x - y ‖}_{B} = ∥x - y∥$ .
Suppose on the contrary that

$\frac{x - y}{{‖ x - y ‖}_{B}} \in S_{X} \cap {(x^{*})}^{- 1} ((- t, t)) .$

Observe that

$t > |x^{*} (\frac{x - y}{{‖ x - y ‖}_{B}})| = \frac{2 t}{{‖ x - y ‖}_{B}},$

meaning that ${‖ x - y ‖}_{B} > 2$ , which is impossible since $x, y \in B$ . As a consequence,

$\frac{x - y}{{‖ x - y ‖}_{B}} \in B_{X} \cap {(x^{*})}^{- 1} ({- t, t}) .$

In particular,

$t = |x^{*} (\frac{x - y}{{‖ x - y ‖}_{B}})| = \frac{2 t}{{‖ x - y ‖}_{B}},$

which implies that ${‖ x - y ‖}_{B} = 2$ .

□

5. Conclusions

The main conclusion that we infer from this work is that still there are plenty of geometric invariants under surjective isometries to be found. Before this work, the main geometric invariants known were starlike sets, maximal faces, and facets in the general case and antipodal points in the finite-dimensional case. After this work, we know new geometric invariants such as flat sets, starlike envelopes, starlike compatible sets, and starlike generated sets. This list should be enlarged with convex sets, faces, and segments. It is particularly interesting to prove that surjective isometries between unit spheres map segments to segments, which leads to the surjective isometry being affine on segments in the unit sphere. In this work, we have accomplished this if the segment is a convex component of the unit sphere.

Author Contributions

Conceptualization, A.C.-J. and F.J.G.-P.; Formal analysis, A.C.-J. and F.J.G.-P.; Investigation, A.C.-J. and F.J.G.-P.; Methodology, A.C.-J. and F.J.G.-P. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by Ministry of Science, Innovation and Universities of Spain, grant number PGC-101514-B-I00; and by the 2014–2020 ERDF Operational Programme and by the Department of Economy, Knowledge, Business and University of the Regional Government of Andalusia, grant number FEDER-UCA18-105867.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Acknowledgments

The authors would like to express their most sincere gratitude towards the reviewers, whose comments and suggestions helped improve the quality of the manuscript, as well as to the PIs of the Research Grant PGC-101514-B-I00, Fernando León-Saavedra and María Concepción Muriel-Patino, for their valuable guidance.

Conflicts of Interest

The authors declare no conflict of interest. The funders had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript, or in the decision to publish the results.

Abbreviations

The following abbreviations are used in this manuscript:

MUp	Mazur-Ulam property
Pp	P-property or property P
Ip	I-property or inner property
Fp	F-property or flat property
PI	Principal Investigator

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Campos-Jiménez, A.; García-Pacheco, F.J. Geometric Invariants of Surjective Isometries between Unit Spheres. Mathematics 2021, 9, 2346. https://doi.org/10.3390/math9182346

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Campos-Jiménez A, García-Pacheco FJ. Geometric Invariants of Surjective Isometries between Unit Spheres. Mathematics. 2021; 9(18):2346. https://doi.org/10.3390/math9182346

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Campos-Jiménez, Almudena, and Francisco Javier García-Pacheco. 2021. "Geometric Invariants of Surjective Isometries between Unit Spheres" Mathematics 9, no. 18: 2346. https://doi.org/10.3390/math9182346

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Geometric Invariants of Surjective Isometries between Unit Spheres

Abstract

1. Introduction

2. Materials and Methods

2.1. Extremal Structure

2.2. Starlike Structure

2.3. Smoothness

2.4. Inner Structure

2.5. Minkowski Functional

3. Results

3.1. Banach Spaces Lacking Pp

3.2. Geometric Structure of Facets and Frames

3.3. Flatness

3.4. Preservation of Flatness and Faces under Surjective Isometries

3.5. Invariance of Segments

4. Discussion

5. Conclusions

Author Contributions

Funding

Institutional Review Board Statement

Informed Consent Statement

Data Availability Statement

Acknowledgments

Conflicts of Interest

Abbreviations

References

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