Vector bornology

A bornology on a set X is a collection ℬ of subsets of X such that

1. ℬ covers X (i.e. X = ${\displaystyle \cup _{B\in {\mathcal {B}}}B}$);
2. ℬ is stable under inclusion (i.e. if B ∈ ℬ then every subset of B belongs to ℬ);
3. ℬ is stable under finite unions (or equivalently, the union of any two sets in ℬ also belongs to ℬ).

in which case the pair (X, ℬ) is called a bounded structure.[1] Elements of ℬ are called ℬ-bounded sets or simply bounded. A subset 𝒜 of a bornology ℬ is called a base or fundamental system of ℬ if for every B ∈ ℬ, there exists an A ∈ 𝒜 such that B ⊆ A. Given a collection 𝒮 of subsets of X, the smallest bornology containing 𝒮 is called the bornology generated by 𝒮.[1]

If (X, 𝒜) and (Y, ℬ) are bounded structures and f: X → Y is a map then f is called locally bounded or just bounded if the image under f of every 𝒜-bounded set is a ℬ-bounded set; that is, if for every A ∈ 𝒜, f(A) ∈ ℬ.[1]

If (X, 𝒜) and (Y, ℬ) are bounded structures then the product bornology on X × Y is the bornology having as a base the collection of all sets of the form A × B, where A ∈ 𝒜 and B ∈ ℬ.[1] One may show that a subset of X × Y is bounded in the product bornology if and only if its image under the canonical projections onto X and Y are both bounded.

Let X be a vector space over a field 𝔽, where 𝔽 has a bornology ℬ_𝔽. A bornology ℬ on X is called a vector bornology if its vector spaces operations of addition and scalar multiplication are bounded maps.[1] Explicitly, this means that when X is endowed with the bornology ℬ then:

1. the addition map X × X → X defined by (x, y) ↦ x + y is a bounded map, where X × X has the product bornology, and
2. the scalar multiplication map 𝔽 × X → X defined by (s, x) ↦ sx is a bounded map, where 𝔽 × X has the product bornology induced by (𝔽, ℬ_𝔽) and (X, ℬ).

Usually, 𝔽 is either the real or complex numbers, in which case we call a vector bornology ℬ on X a convex vector bornology if ℬ has a base consisting of convex sets.

Let 𝔽 be the real or complex numbers (endowed with their usual bornologies), let (T, ℬ) be a bounded structure, and let LB(T, 𝔽) denote the vector space of all locally bounded 𝔽-valued maps on T. For every B ∈ ℬ, let ${\displaystyle p_{B}\left(f\right):=\sup \left|f\left(B\right)\right|}$ for all f ∈ LB(T, 𝔽), where this defines a seminorm on X. The locally convex TVS topology on LB(T, 𝔽) defined by the family of seminorms ${\displaystyle \left\{p_{B}:B\in {\mathcal {B}}\right\}}$ is called the topology of uniform convergence on bounded set.[1] This topology makes LB(T, 𝔽) into a complete space.[1]

Let T be a topological space, 𝔽 be the real or complex numbers, and let C(T, 𝔽) denote the vector space of all continuous 𝔽-valued maps on T. The set ℰ of all equicontinuous subsets of C(T, 𝔽) forms a vector bornology on C(T, 𝔽).[1]