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 ${\displaystyle \{x_{n}\}_{n=1}^{N}}$  of vectors in ℓ^∞ is called block-disjoint if there are natural numbers ${\displaystyle \textstyle \{a_{n},b_{n}\}_{n=1}^{N}}$  so that ${\displaystyle a_{1}\leq b_{1}<a_{2}\leq b_{2}<\cdots \leq b_{N}}$ , and so that ${\displaystyle (x_{n})_{i}=0}$  when ${\displaystyle i<a_{n}}$  or ${\displaystyle i>b_{n}}$ , 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 ${\displaystyle \lambda e_{j}}$ , for |λ| ≤ 1, belong to K.

b. For any integer N ≥ 1, if ${\displaystyle \textstyle (x_{1},\ldots ,x_{N})}$  is a block-disjoint sequence in K, then ${\displaystyle \textstyle {{1 \over 2}P_{N}(x_{1}+\cdots +x_{N})}}$  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.

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 ${\displaystyle \scriptstyle {\ell _{n}^{1}}}$ , 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 c₀. The dual space T is not minimal.^[10]

The space T* is polynomially reflexive.

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.

• Distortion problem
• Sequence space, Schauder basis
• James' space

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• Baudier, Florent; Lancien, Gilles; Schlumprecht, Thomas B. (2018), "The coarse geometry of Tsirelson's space and applications", Journal of the American Mathematical Society, 31: 699--717, arXiv:1705.06797, doi:10.1090/jams/899, MR 3787406.

• Boris Tsirelson's reminiscences on his web page