Mazur–Ulam theorem

In mathematics, the Mazur–Ulam theorem states that if $V$ and $W$ are normed spaces over R and the mapping

f\colon V\to W

is a surjective isometry, then $f$ is affine. It was proved by Stanisław Mazur and Stanisław Ulam in response to a question raised by Stefan Banach.

For strictly convex spaces the result is true, and easy, even for isometries which are not necessarily surjective. In this case, for any $u$ and $v$ in $V$ , and for any $t$ in $[0,1]$ , write

r=\|u-v\|_{V}=\|f(u)-f(v)\|_{W}

and denote the closed ball of radius R around v by

{\bar {B}}(v,R)

. Then

tu+(1-t)v

is the unique element of

{\bar {B}}(v,tr)\cap {\bar {B}}(u,(1-t)r)

, so, since

f

is injective,

f(tu+(1-t)v)

is the unique element of

f{\bigl (}{\bar {B}}(v,tr)\cap {\bar {B}}(u,(1-t)r{\bigr )}=f{\bigl (}{\bar {B}}(v,tr){\bigr )}\cap f{\bigl (}{\bar {B}}(u,(1-t)r{\bigr )}={\bar {B}}{\bigl (}f(v),tr{\bigr )}\cap {\bar {B}}{\bigl (}f(u),(1-t)r{\bigr )},

and therefore is equal to

tf(u)+(1-t)f(v)

. Therefore

f

is an affine map. This argument fails in the general case, because in a normed space which is not strictly convex two tangent balls may meet in some flat convex region of their boundary, not just a single point.

References

Richard J. Fleming; James E. Jamison (2003). Isometries on Banach Spaces: Function Spaces. CRC Press. p. 6. ISBN 1-58488-040-6.
Stanisław Mazur; Stanisław Ulam (1932). "Sur les transformations isométriques d'espaces vectoriels normés". C. R. Acad. Sci. Paris. 194: 946–948.
Nica, Bogdan (2012). "The Mazur–Ulam theorem". Expositiones Mathematicae. 30 (4): 397–398. arXiv:1306.2380. doi:10.1016/j.exmath.2012.08.010.
Jussi Väisälä (2003). "A Proof of the Mazur–Ulam Theorem". The American Mathematical Monthly. 110 (7): 633–635. doi:10.1080/00029890.2003.11920004. JSTOR 3647749. S2CID 43171421.

Banach space topics

Types of Banach spaces

Asplund
Banach
- list
Banach lattice
Grothendieck
Hilbert
- Inner product space
- Polarization identity
(Polynomially) Reflexive
Riesz
L-semi-inner product
(B
Strictly
Uniformly) convex
Uniformly smooth
(Injective
Projective) Tensor product (of Hilbert spaces)

Banach spaces are:

Barrelled
Complete
F-space
Fréchet
- tame
Locally convex
- Seminorms/Minkowski functionals
Mackey
Metrizable
Normed
- norm
Quasinormed
Stereotype

Function space Topologies

Linear operators

Operator theory

Banach algebras
C*-algebras
Operator space
Spectrum
- C*-algebra
- radius
Spectral theory
- of ODEs
- Spectral theorem
Polar decomposition
Singular value decomposition

Theorems

Analysis

Abstract Wiener space
Banach manifold
- bundle
Bochner space
Convex series
Differentiation in Fréchet spaces
Derivatives
- Fréchet
- Gateaux
- functional
- holomorphic
- quasi
Integrals
Functional calculus
Measures
Weakly / Strongly measurable function

Types of sets

Absolutely convex
Absorbing
Affine
Balanced/Circled
Bounded
Convex
Convex cone (subset)
Convex series related ((cs, lcs)-closed, (cs, bcs)-complete, (lower) ideally convex, (Hx), and (Hwx))
Linear cone (subset)
Radial
Radially convex/Star-shaped
Symmetric
Zonotope

Subsets / set operations

Examples

Absolute continuity AC
$ba(\Sigma )$
c space
Banach coordinate BK
Besov $B_{p,q}^{s}(\mathbb {R} )$
Birnbaum–Orlicz
Bounded variation BV
Bs space
Continuous C(K) with K compact Hausdorff
Hardy H^p
Hilbert H
Morrey–Campanato $L^{\lambda ,p}(\Omega )$
ℓ^p
- $\ell ^{\infty }$
L^p
- $L^{\infty }$
- weighted
Schwartz $S\left(\mathbb {R} ^{n}\right)$
Segal–Bargmann F
Sequence space
Sobolev W^k,p
- Sobolev inequality
Triebel–Lizorkin
Wiener amalgam $W(X,L^{p})$

Applications

Functional analysis (topics – glossary)

Spaces

Banach Besov Fréchet Hilbert Hölder Nuclear Orlicz Schwartz Sobolev Topological vector
Properties	Barrelled Complete Dual (Algebraic/Topological) Locally convex Reflexive Separable