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Revision as of 02:41, 14 October 2021 edit Dabed (talk \| contribs) Extended confirmed users 4,308 edits →Algebra: Bianchi classification ← Previous edit		Latest revision as of 04:52, 15 September 2024 edit undo Linkhyrule5 (talk \| contribs) 63 edits Explained "realizable". Tag: Visual edit
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Line 1: {{short description\|Describes the objects of a given type, up to some equivalence}} {{Unreferenced\|date=December 2009}} In [[mathematics]], a '''classification theorem''' answers the [[classification]] problem: "What are the objects of a given type, up to some [[Equivalence relation\|equivalence]]?". It gives a non-redundant [[enumeration]]: each object is equivalent to exactly one class. A few issues related to classification are the following. The equivalence problem is "given two objects, determine if they are equivalent". A [[complete set of invariants]], together with which invariants are ~~{{clarify span\|~~realizable,~~\|reason=This notion should be introduced.\|date=October 2020}}~~ solves the classification problem, and is often a step in solving it. (A combination of invariant values is realizable if there in fact exists an object whose invariants take on the specified set of values) A {{clarify span\|computable complete set of invariants\|reason=Shouldn't this be "finite set of computable invariants"? Computability (whatever this is supposed to mean on a set of functions) is of no help if infinitely many functions must be evaluated or if an uncomputable function must be evaluated.\|date=October 2020}} (together with which invariants are realizable) solves both the classification problem and the equivalence problem. A [[canonical form]] solves the classification problem, and is more data: it not only classifies every class, but provides a distinguished (canonical) element of each class. Line 13: ==Geometry== * [[{{annotated link\|Euclidean plane isometry#Classification of Euclidean plane isometries\|Classification of Euclidean plane isometries]]}} * ~~'''~~[[Platonic solid#Classification\|Classification ~~theorem~~ of ~~surfaces'''~~Platonic solids]] [[Classification theorems of ~~two-dimensional closed manifolds]]~~surfaces [[{{annotated link\|Classification of two-dimensional closed manifolds]]}}▼ [[{{annotated link\|Enriques–Kodaira classification]]}} of [[algebraic surfaces]] (complex dimension two, real dimension four) [[{{annotated link\|Nielsen–Thurston classification]]}} which characterizes homeomorphisms of a compact surface * Thurston's eight model geometries, and the [[{{annotated link\|geometrization conjecture]]}} * [[Symmetric space#Classification of Riemannian symmetric spaces\|Classification of Riemannian symmetric spaces]]▼ * [[{{annotated link\|Holonomy#The Berger classification\|Berger classification]]}} ▲* [[{{annotated link\|Symmetric space#Classification ~~of Riemannian symmetric spaces~~result\|Classification of Riemannian symmetric spaces]]}} ▲* [[Classification of manifolds]] * {{annotated link\|Lens space#Classification of 3-dimensional lens spaces\|Classification of 3-dimensional lens spaces}} * {{annotated link\|Classification of manifolds}} ==Algebra== * [[{{annotated link\|Classification of finite simple groups]]}} ** {{annotated link\|Abelian group#Classification\|Classification of Abelian groups}} * [[Artin–Wedderburn theorem]] — a classification theorem for semisimple rings▼ ** {{annotated link\|Finitely generated abelian group#Classification\|Classification of Finitely generated abelian group}} * [[Classification of Clifford algebras]]▼ [[{{annotated link\|Multiple transitivity\|Classification of ~~low-dimensional~~Rank ~~real~~3 ~~Lie~~permutation ~~algebras]]~~group}} {{annotated link\|Rank 3 permutation group#Classification\|Classification of 2-transitive permutation groups}} * [[Bianchi classification]]▼ ▲* [[{{annotated link\|Artin–Wedderburn theorem]]}} — a classification theorem for semisimple rings * [[ADE classification]]▼ ▲* [[{{annotated link\|Classification of Clifford algebras]]}} * {{annotated link\|Classification of low-dimensional real Lie algebras}} * Classification of Simple Lie algebras and groups {{annotated link\|Semisimple Lie algebra#Classification\|Classification of simple complex Lie algebras}} {{annotated link\|Satake diagram\|Classification of simple real Lie algebras}} {{annotated link\|Simple Lie group#Full classification\|Classification of centerless simple Lie groups}} {{annotated link\|List of simple Lie groups\|Classification of simple Lie groups}} ▲* [[{{annotated link\|Bianchi classification]]}} ▲* [[{{annotated link\|ADE classification]]}} {{annotated link\|Langlands classification}} ==Linear algebra== [[{{annotated link\|Finite-dimensional vector space]]}}s (by dimension) * [[{{annotated link\|Rank–nullity theorem]]}} (by rank and nullity) * [[{{annotated link\|Structure theorem for finitely generated modules over a principal ideal ___domain]]}} * [[{{annotated link\|Jordan normal form]]}} * {{annotated link\|Frobenius normal form}} (rational canonical form) * [[{{annotated link\|Sylvester's law of inertia]]}} ==Analysis== * [[{{annotated link\|Classification of discontinuities]]}} ==~~Complex~~Dynamical ~~analysis~~systems== * [[{{annotated link\|Classification of Fatou components]]}} * [[Ratner's theorems#Short description\|Ratner classification theorem]] ==Mathematical physics== * [[{{annotated link\|Classification of electromagnetic fields]]}} * [[{{annotated link\|Petrov classification]]}} * [[{{annotated link\|Segre classification]]}} * {{annotated link\|Wigner's classification}} ==See also== * {{annotated link\|Representation theorem}} * {{annotated link\|Comparison theorem}} * {{annotated link\|List of manifolds}} * [[List of theorems]] ==References== {{reflist}} {{DEFAULTSORT:Classification Theorem}} [[Category:Mathematical theorems]] [[Category:Mathematical classification systems]]