Linear topology (original) (raw)

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In algebra, a linear topology on a left A {\displaystyle A} $A$ -module M {\displaystyle M} $M$ is a topology on M {\displaystyle M} $M$ that is invariant under translations and admits a fundamental system of neighborhoods of 0 {\displaystyle 0} $0$ that consist of submodules of M . {\displaystyle M.} $M.$ [1] If there is such a topology, M {\displaystyle M} $M$ is said to be linearly topologized. If A {\displaystyle A} $A$ is given a discrete topology, then M {\displaystyle M} $M$ becomes a topological A {\displaystyle A} $A$ -module with respect to a linear topology.

The notion is used more commonly in algebra than in analysis. Indeed, "[t]opological vector spaces with linear topology form a natural class of topological vector spaces over discrete fields, analogous to the class of locally convex topological vector spaces over the normed fields of real or complex numbers in functional analysis."[2]

The term "linear topology" goes back to Lefschetz' work.[1][2]

Examples and non-examples

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Ordered topological vector space
Ring of restricted power series – Formal power series with coefficients tending to 0Pages displaying short descriptions of redirect targets
Topological abelian group
Topological field – Algebraic structure with addition, multiplication, and divisionPages displaying short descriptions of redirect targets
Topological group – Group that is a topological space with continuous group action
Topological module
Topological ring
Topological semigroup
Topological vector space – Vector space with a notion of nearness

^ a b Ch II, Definition 25.1. in Solomon Lefschetz, Algebraic Topology
^ a b Positselski, Leonid (2024). "Exact categories of topological vector spaces with linear topology". Moscow Mathematical Journal. 24 (2): 219–286. arXiv:2012.15431. doi:10.17323/1609-4514-2024-24-2-219-286.

Bourbaki, N. (1972). Commutative algebra (Vol. 8). Hermann.