Difference between revisions of "Linear topology"
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− | ''on a ring | + | {{TEX|done}} |
+ | ''on a ring $A$'' | ||
− | A topology on a ring for which there is a fundamental system of neighbourhoods of zero consisting of left ideals (in this case the topology is said to be left linear). Similarly, a topology on a left | + | A topology on a ring for which there is a fundamental system of neighbourhoods of zero consisting of left ideals (in this case the topology is said to be left linear). Similarly, a topology on a left $A$-module $E$ is linear if there is a fundamental system of neighbourhoods of zero consisting of submodules. The most extensively used is the [[Adic topology|adic topology]], a basis of which is given by the powers of an ideal. |
− | A separable linearly topologized | + | A separable linearly topologized $A$-module $E$ is called a [[Linearly-compact module|linearly-compact module]] if any filter basis (cf. [[Filter|Filter]]) consisting of affine linear varieties of $E$ (that is, subsets of the form $x+E'$, where $x\in E$ and $E'$ is a submodule of $E$) has a limit point. Any module of finite type over a complete local Noetherian ring is linearly compact. |
====References==== | ====References==== |
Latest revision as of 19:21, 14 August 2014
on a ring $A$
A topology on a ring for which there is a fundamental system of neighbourhoods of zero consisting of left ideals (in this case the topology is said to be left linear). Similarly, a topology on a left $A$-module $E$ is linear if there is a fundamental system of neighbourhoods of zero consisting of submodules. The most extensively used is the adic topology, a basis of which is given by the powers of an ideal.
A separable linearly topologized $A$-module $E$ is called a linearly-compact module if any filter basis (cf. Filter) consisting of affine linear varieties of $E$ (that is, subsets of the form $x+E'$, where $x\in E$ and $E'$ is a submodule of $E$) has a limit point. Any module of finite type over a complete local Noetherian ring is linearly compact.
References
[1] | N. Bourbaki, "Elements of mathematics. Commutative algebra" , Addison-Wesley (1972) (Translated from French) |
Comments
Gabriel topologies on rings are examples of linear topologies; these appear in the theory of localization (cf. Localization in a commutative algebra) or torsion theory. Gabriel topologies correspond to Serre localizing subcategories of the category of left modules over the ring.
References
[a1] | J.S. Golan, "Localization of noncommutative rings" , M. Dekker (1975) |
[a2] | B. Stenström, "Rings of quotients" , Springer (1975) |
[a3] | F. Van Oystaeyen, A. Verschoren, "Reflectors and localization. Application to sheaf theory" , M. Dekker (1979) |
[a4] | J. Lambek, "Torsion theories, additive semantics and rings of quotients" , Lect. notes in math. , 77 , Springer (1971) |
Linear topology. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Linear_topology&oldid=12900