Tsirelson space

In mathematics, especially in functional analysis, the Tsirelson space is the first example of a Banach space in which neither an ℓ^p space nor a c₀ space can be embedded. The Tsirelson space is reflexive. It was introduced by B. S. Tsirelson in 1974. The same year, Figiel and Johnson published a related article ((Figiel Johnson)) where they used the notation T for the dual of Tsirelson's example. Today, the letter T is the standard notation^[1] for the dual of the original example, while the original Tsirelson example is denoted by T*. In T* or in T, no subspace is isomorphic, as Banach space, to an ℓ^p space, 1 ≤ p < ∞, or to c₀.

All classical Banach spaces known to (Banach 1932), spaces of continuous functions, of differentiable functions or of integrable functions, and all the Banach spaces used in functional analysis for the next forty years, contain some ℓ^p or c₀. Also, new attempts in the early '70s^[2] to promote a geometric theory of Banach spaces led to ask ^[3] whether or not every infinite-dimensional Banach space has a subspace isomorphic to some ℓ^p or to c₀. Moreover, it was shown by Baudier, Lancien, and Schlumprecht that ℓ^p and c₀ do not even coarsely embed into T*.

The radically new Tsirelson construction is at the root of several further developments in Banach space theory: the arbitrarily distortable space of Thomas Schlumprecht ((Schlumprecht 1991)), on which depend Gowers' solution to Banach's hyperplane problem^[4] and the Odell–Schlumprecht solution to the distortion problem. Also, several results of Argyros et al.^[5] are based on ordinal refinements of the Tsirelson construction, culminating with the solution by Argyros–Haydon of the scalar plus compact problem.^[6]

Tsirelson's construction

On the vector space ℓ^∞ of bounded scalar sequences x = {x_j} _j∈N, let P_n denote the linear operator which sets to zero all coordinates x_j of x for which j ≤ n.

A finite sequence [math]\displaystyle{ \{x_n\}_{n=1}^N }[/math] of vectors in ℓ^∞ is called block-disjoint if there are natural numbers [math]\displaystyle{ \textstyle \{a_n, b_n\}_{n=1}^N }[/math] so that [math]\displaystyle{ a_1 \leq b_1 \lt a_2 \leq b_2 \lt \cdots \leq b_N }[/math], and so that [math]\displaystyle{ (x_n)_i=0 }[/math] when [math]\displaystyle{ i\lt a_n }[/math] or [math]\displaystyle{ i\gt b_n }[/math], for each n from 1 to N.

The unit ball B_∞ of ℓ^∞ is compact and metrizable for the topology of pointwise convergence (the product topology). The crucial step in the Tsirelson construction is to let K be the smallest pointwise closed subset of B_∞ satisfying the following two properties:^[7]

a. For every integer j in N, the unit vector e_j and all multiples [math]\displaystyle{ \lambda e_j }[/math], for |λ| ≤ 1, belong to K.

b. For any integer N ≥ 1, if [math]\displaystyle{ \textstyle (x_1,\ldots,x_N) }[/math] is a block-disjoint sequence in K, then [math]\displaystyle{ \textstyle{{1\over2}P_N(x_1 + \cdots + x_N)} }[/math] belongs to K.

This set K satisfies the following stability property:

c. Together with every element x of K, the set K contains all vectors y in ℓ^∞ such that |y| ≤ |x| (for the pointwise comparison).

It is then shown that K is actually a subset of c₀, the Banach subspace of ℓ^∞ consisting of scalar sequences tending to zero at infinity. This is done by proving that

d: for every element x in K, there exists an integer n such that 2 P_n(x) belongs to K,

and iterating this fact. Since K is pointwise compact and contained in c₀, it is weakly compact in c₀. Let V be the closed convex hull of K in c₀. It is also a weakly compact set in c₀. It is shown that V satisfies b, c and d.

The Tsirelson space T* is the Banach space whose unit ball is V. The unit vector basis is an unconditional basis for T* and T* is reflexive. Therefore, T* does not contain an isomorphic copy of c₀. The other ℓ^p spaces, 1 ≤ p < ∞, are ruled out by condition b.

Properties

The Tsirelson space $T*$ is reflexive ((Tsirel'son 1974)) and finitely universal, which means that for some constant $C$ ≥ 1, the space $T*$ contains $C$ -isomorphic copies of every finite-dimensional normed space, namely, for every finite-dimensional normed space $X$ , there exists a subspace $Y$ of the Tsirelson space with multiplicative Banach–Mazur distance to $X$ less than $C$ . Actually, every finitely universal Banach space contains almost-isometric copies of every finite-dimensional normed space,^[8] meaning that $C$ can be replaced by 1 + ε for every ε > 0. Also, every infinite-dimensional subspace of $T*$ is finitely universal. On the other hand, every infinite-dimensional subspace in the dual $T$ of $T*$ contains almost isometric copies of [math]\displaystyle{ \scriptstyle{\ell^1_n} }[/math], the $n$ -dimensional ℓ¹-space, for all $n$ .

The Tsirelson space $T$ is distortable, but it is not known whether it is arbitrarily distortable.

The space $T*$ is a minimal Banach space.^[9] This means that every infinite-dimensional Banach subspace of $T*$ contains a further subspace isomorphic to $T*$ . Prior to the construction of $T*$ , the only known examples of minimal spaces were ℓ^p and $c$ ₀. The dual space $T$ is not minimal.^[10]

The space $T*$ is polynomially reflexive.

Derived spaces

The symmetric Tsirelson space S(T) is polynomially reflexive and it has the approximation property. As with T, it is reflexive and no ℓ^p space can be embedded into it.

Since it is symmetric, it can be defined even on an uncountable supporting set, giving an example of non-separable polynomially reflexive Banach space.

Notes

↑ see for example (Casazza Shura), p. 8; (Lindenstrauss Tzafriri), p. 95; The Handbook of the Geometry of Banach Spaces, vol. 1, p. 276; vol. 2, p. 1060, 1649.
↑ see (Lindenstrauss 1970), (Milman 1970).
↑ The question is formulated explicitly in (Lindenstrauss 1970), (Milman 1970), (Lindenstrauss 1971) on last page. (Lindenstrauss Tzafriri), p. 95, say that this question was "a long standing open problem going back to Banach's book" ((Banach 1932)), but the question does not appear in Banach's book. However, Banach compares the linear dimension of ℓ^p to that of other classical spaces, a somewhat similar question.
↑ The question is whether every infinite-dimensional Banach space is isomorphic to its hyperplanes. The negative solution is in Gowers, "A solution to Banach's hyperplane problem". Bull. London Math. Soc. 26 (1994), 523-530.
↑ for example, S. Argyros and V. Felouzis, "Interpolating Hereditarily Indecomposable Banach spaces", Journal Amer. Math. Soc., 13 (2000), 243–294; S. Argyros and A. Tolias, "Methods in the theory of hereditarily indecomposable Banach spaces", Mem. Amer. Math. Soc. 170 (2004), no. 806.
↑ S. Argyros and R. Haydon constructed a Banach space on which every bounded operator is a compact perturbation of a scalar multiple of the identity, in "A hereditarily indecomposable L_∞-space that solves the scalar-plus-compact problem", Acta Mathematica (2011) 206: 1-54.
↑ conditions b, c, d here are conditions (3), (2) and (4) respectively in (Tsirel'son 1974), and a is a modified form of condition (1) from the same article.
↑ this is because for every $n$ , $C$ and ε, there exists $N$ such that every $C$ -isomorph of ℓ^∞_$N$ contains a (1 + ε)-isomorph of ℓ^∞_n, by James' blocking technique (see Lemma 2.2 in Robert C. James "Uniformly Non-Square Banach Spaces", Annals of Mathematics, Vol. 80, 1964, pp. 542-550), and because every finite-dimensional normed space (1 + ε)-embeds in ℓ^∞_$n$ when $n$ is large enough.
↑ see (Casazza Shura), p. 54.
↑ see (Casazza Shura), p. 56.

References

"'Not every Banach space contains an imbedding of ℓ^p or c₀", Functional Analysis and Its Applications 8: 138–141, 1974, doi:10.1007/BF01078599 .
Template:Banach Théorie des Opérations Linéaires
Figiel, T. (1974), "A uniformly convex Banach space which contains no ℓ^p", Compositio Mathematica 29: 179–190, http://www.numdam.org/item?id=CM_1974__29_2_179_0 .
Casazza, Peter G.; Shura, Thaddeus J. (1989), Tsirelson's Space, Lecture Notes in Mathematics, 1363, Berlin: Springer-Verlag, ISBN 3-540-50678-0 .
Johnson, William B.; J. Lindenstrauss, Joram, eds. (2001), Handbook of the Geometry of Banach Spaces, 1, Elsevier .
Johnson, William B.; J. Lindenstrauss, Joram, eds. (2003), Handbook of the Geometry of Banach Spaces, 2, Elsevier .
"Some aspects of the theory of Banach spaces", Advances in Mathematics 5: 159–180, 1970, doi:10.1016/0001-8708(70)90032-0 .
"The geometric theory of the classical Banach spaces", Actes du Congrès Intern. Math., Nice 1970: 365–372, 1971 .
Classical Banach Spaces I, Sequence Spaces, Ergebnisse der Mathematik und ihrer Grenzgebiete, 92, Berlin: Springer-Verlag, 1977, ISBN 3-540-08072-4 .
"Geometric theory of Banach spaces. I. Theory of basic and minimal systems" (in Russian), Uspekhi Mat. Nauk 25 no. 3: 113–174, 1970 . English translation in Russian Math. Surveys 25 (1970), 111-170.
Schlumprecht, Thomas (1991), "An arbitrary distortable Banach space", Israel Journal of Mathematics 76: 81–95, doi:10.1007/bf02782845 .
Baudier, Florent; Lancien, Gilles; Schlumprecht, Thomas (2018), "The coarse geometry of Tsirelson's space and applications", Journal of the American Mathematical Society 31: 699--717, doi:10.1090/jams/899 .

External links

Boris Tsirelson's reminiscences on his web page

0.00

(0 votes)

Original source: https://en.wikipedia.org/wiki/Tsirelson space. Read more

[Standard-1] see for example (Casazza Shura), p. 8; (Lindenstrauss Tzafriri), p. 95; The Handbook of the Geometry of Banach Spaces, vol. 1, p. 276; vol. 2, p. 1060, 1649.

[2] see (Lindenstrauss 1970), (Milman 1970).

[3] The question is formulated explicitly in (Lindenstrauss 1970), (Milman 1970), (Lindenstrauss 1971) on last page. (Lindenstrauss Tzafriri), p. 95, say that this question was "a long standing open problem going back to Banach's book" ((Banach 1932)), but the question does not appear in Banach's book. However, Banach compares the linear dimension of ℓ^p to that of other classical spaces, a somewhat similar question.

[4] The question is whether every infinite-dimensional Banach space is isomorphic to its hyperplanes. The negative solution is in Gowers, "A solution to Banach's hyperplane problem". Bull. London Math. Soc. 26 (1994), 523-530.

[5] r example, S. Argyros and V. Felouzis, "Interpolating Hereditarily Indecomposable Banach spaces", Journal Amer. Math. Soc., 13 (2000), 243–294; S. Argyros and A. Tolias, "Methods in the theory of hereditarily indecomposable Banach spaces", Mem. Amer. Math. Soc. 170 (2004), no. 806.

[6] S. Argyros and R. Haydon constructed a Banach space on which every bounded operator is a compact perturbation of a scalar multiple of the identity, in "A hereditarily indecomposable L_∞-space that solves the scalar-plus-compact problem", Acta Mathematica (2011) 206: 1-54.

[Conditions-7] tions b, c, d here are conditions (3), (2) and (4) respectively in (Tsirel'son 1974), and a is a modified form of condition (1) from the same article.

[8] this is because for every $n$ , $C$ and ε, there exists $N$ such that every $C$ -isomorph of ℓ^∞_$N$ contains a (1 + ε)-isomorph of ℓ^∞_n, by James' blocking technique (see Lemma 2.2 in Robert C. James "Uniformly Non-Square Banach Spaces", Annals of Mathematics, Vol. 80, 1964, pp. 542-550), and because every finite-dimensional normed space (1 + ε)-embeds in ℓ^∞_$n$ when $n$ is large enough.

[9] see (Casazza Shura), p. 54.

[10] see (Casazza Shura), p. 56.

[1]

[2]

[3]

[4]

[5]

[6]

[7]

[8]

[9]

[10]

v t e Functional analysis (topics)
Topological vector spaces	Asplund Banach (list) Banach lattice Barrelled Bornological Brauner F-space Fréchet (tame) Hilbert (Inner product space Polarization identity) LF-space Locally convex (Seminorms/Minkowski functionals) Mackey Montel Nuclear Normed (norm) Quasinormed Reflexive Riesz Smith Stereotype Strictly convex Webbed Topological tensor product (of Hilbert spaces)
Topologies of function spaces	Dual Dual space (Dual norm) Operator Ultraweak Weak (polar operator) Mackey Strong (polar operator) Ultrastrong Uniform convergence
Linear operators	Adjoint Bilinear (form operator sesquilinear) (Un)Bounded Closed Compact (on Hilbert spaces) (Dis)Continuous Densely defined Fredholm Hilbert–Schmidt Functionals (positive) Normal Nuclear Self-adjoint Strictly singular Trace class Transpose Unitary
Operator theory	Banach algebras C-algebras Spectrum (C-algebra radius) Spectral theory (of ODEs Spectral theorem) Polar decomposition Singular value decomposition
Theorems	Banach–Alaoglu Banach–Mazur Banach–Saks Banach–Schauder (open mapping) Banach–Steinhaus (Uniform boundedness) Bessel's inequality Cauchy–Schwarz inequality Closed graph Closed range Eberlein–Šmulian Freudenthal spectral Gelfand–Mazur Gelfand–Naimark Goldstine Hahn–Banach (hyperplane separation) Kakutani fixed-point Krein–Milman Lomonosov's invariant subspace Mackey–Arens Mazur's lemma M. Riesz extension Riesz representation Parseval's identity Schauder fixed-point
Analysis	Abstract Wiener space Bochner space Differentiation in Fréchet spaces Derivatives (Fréchet Gateaux functional holomorphic) Integrals (Bochner Dunford Gelfand–Pettis regulated Paley–Wiener weak) Functional calculus (Borel continuous holomorphic) Inverse function theorem (Nash–Moser theorem) Measures (Lebesgue Projection-valued Vector) Weakly measurable function
Types of sets	Absolutely convex Absorbing Balanced Bounded Convex Convex cone (subset) Linear cone (subset) Radial Star-shaped Symmetric Zonotope
Subsets / set operations	Algebraic interior (core) Bounding points Convex hull Extreme point Interior Minkowski addition Polar

Anonymous

Search

Tsirelson space

Namespaces

More

Page actions

Contents

Tsirelson's construction

Properties

Derived spaces

See also

Notes

References

External links

Navigation

Navigation

Help

Translate

Wiki tools

Wiki tools

Anonymous

Search

Tsirelson space

Tsirelson's construction

Properties

Derived spaces

See also

Notes

References

External links

Navigation

Wiki tools

Page tools

Other projects

Categories