Ekeland's variational principle: Difference between revisions

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29 yr old Orthopaedic Surgeon Grippo from Saint-Paul, spends time with interests including model railways, top property developers in singapore developers in singapore and dolls. Finished a cruise ship experience that included passing by Runic Stones and Church. In mathematics, a 2-group, or 2-dimensional higher group, is a certain combination of group and groupoid. The 2-groups are part of a larger hierarchy of n-groups. In some of the literature, 2-groups are also called gr-categories or groupal groupoids.

Definition

A 2-group is a monoidal category G in which every morphism is invertible and every object has a weak inverse. (Here, a weak inverse of an object x is an object y such that xy and yx are both isomorphic to the unit object.)

Strict 2-groups

Much of the literature focuses on strict 2-groups. A strict 2-group is a strict monoidal category in which every morphism is invertible and every object has a strict inverse (so that xy and yx are actually equal to the unit object).

A strict 2-group is a group object in a category of categories; as such, they are also called groupal categories. Conversely, a strict 2-group is a category object in the category of groups; as such, they are also called categorical groups. They can also be identified with crossed modules, and are most often studied in that form. Thus, 2-groups in general can be seen as a weakening of crossed modules.

Every 2-group is equivalent to a strict 2-group, although this can't be done coherently: it doesn't extend to 2-group homomorphisms.

Properties

Weak inverses can always be assigned coherently: one can define a functor on any 2-group G that assigns a weak inverse to each object and makes that object an adjoint equivalance in the monoidal category G.

Given a bicategory B and an object x of B, there is an automorphism 2-group of x in B, written Aut_B(x). The objects are the automorphisms of x, with multiplication given by composition, and the morphisms are the invertible 2-morphisms between these. If B is a 2-groupoid (so all objects and morphisms are weakly invertible) and x is its only object, then Aut_B(x) is the only data left in B. Thus, 2-groups may be identified with one-object 2-groupoids, much as groups may be idenitified with one-object groupoids and monoidal categories may be identified with one-object bicategories.

If G is a strict 2-group, then the objects of G form a group, called the underlying group of G and written G₀. This will not work for arbitrary 2-groups; however, if one identifies isomorphic objects, then the equivalence classes form a group, called the fundamental group of G and written π₁(G). (Note that even for a strict 2-group, the fundamental group will only be a quotient group of the underlying group.)

As a monoidal category, any 2-group G has a unit object I_G. The automorphism group of I_G is an abelian group by the Eckmann–Hilton argument, written Aut(I_G) or π₂(G).

The fundamental group of G acts on either side of π₂(G), and the associator of G (as a monoidal category) defines an element of the cohomology group H³(π₁(G),π₂(G)). In fact, 2-groups are classified in this way: given a group π₁, an abelian group π₂, a group action of π₁ on π₂, and an element of H³(π₁,π₂), there is a unique (up to equivalence) 2-group G with π₁(G) isomorphic to π₁, π₂(G) isomorphic to π₂, and the other data corresponding.

Fundamental 2-group

Given a topological space X and a point x in that space, there is a fundamental 2-group of X at x, written Π₂(X,x). As a monoidal category, the objects are loops at x, with multiplication given by concatenation, and the morphisms are basepoint-preserving homotopies between loops, with these morphisms identified if they are themselves homotopic.

Conversely, given any 2-group G, one can find a unique (up to weak homotopy equivalence) pointed connected space whose fundamental 2-group is G and whose homotopy groups π_n are trivial for n > 2. In this way, 2-groups classify pointed connected weak homotopy 2-types. This is a generalisation of the construction of Eilenberg–Mac Lane spaces.

If X is a topological space with basepoint x, then the fundamental group of X at x is the same as the fundamental group of the fundamental 2-group of X at x; that is,

\pi _{1}(X,x)=\pi _{1}(\Pi _{2}(X,x)).\!

This fact is the origin of the term "fundamental" in both of its 2-group instances.

Similarly,

\pi _{2}(X,x)=\pi _{2}(\Pi _{2}(X,x)).\!

Thus, both the first and second homotopy groups of a space are contained within its fundamental 2-group. As this 2-group also defines an action of π₁(X,x) on π₂(X,x) and an element of the cohomology group H^{3(π₁(X,x),π₂(X,x)), this is precisely the data needed to form the Postnikov tower of X if X is a pointed connected homotopy 2-type.}

References

John C. Baez and Aaron D. Lauda, Higher-Dimensional Algebra V: 2-Groups, Theory and Applications of Categories 12 (2004), 423–491.
John C. Baez and Danny Stevenson, The Classifying Space of a Topological 2-Group.
R. Brown and P.J. Higgins, ``The classifying space of a crossed complex, Math. Proc. Camb. Phil. Soc. 110 (1991) 95-120.
R. Brown, P.J. Higgins, R. Sivera, Nonabelian algebraic topology: filtered spaces, crossed complexes, cubical homotopy groupoids, EMS Tracts in Mathematics Vol. 15, 703 pages. (2011).
Hendryk Pfeiffer, 2-Groups, trialgebras and their Hopf categories of representations, Adv. Math. 212 No. 1 (2007) 62–108.
2-group at the n-Category Lab.

External links

2008 Workshop on Categorical Groups at the Centre de Recerca Matemàtica

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+{{About|2-dimensional higher groups|2-primary groups|p-primary group}}
+In [[mathematics]], a '''2-group''', or '''2-dimensional higher group''', is a certain combination of [[Group (mathematics)|group]] and [[groupoid]].  The 2-groups are part of a larger hierarchy of [[n-group (category theory)|''n''-groups]].  In some of the literature, 2-groups are also called '''gr-categories''' or '''groupal groupoids'''.
+== Definition ==
+A 2-group is a [[monoidal category]] ''G'' in which every morphism is invertible and every object has a weak inverse.  (Here, a ''weak inverse'' of an object ''x'' is an object ''y'' such that ''xy'' and ''yx'' are both isomorphic to the unit object.)
+== Strict 2-groups ==
+Much of the literature focuses on ''strict 2-groups''.  A strict 2-group is a ''strict'' monoidal category in which every morphism is invertible and every object has a strict inverse (so that ''xy'' and ''yx'' are actually equal to the unit object).
+A strict 2-group is a [[group object]] in a [[category of categories]]; as such, they are also called ''groupal categories''.  Conversely, a strict 2-group is a [[category object]] in the [[category of groups]]; as such, they are also called ''categorical groups''.  They can also be identified with [[crossed module]]s, and are most often studied in that form.  Thus, 2-groups in general can be seen as a weakening of [[crossed modules]].
+Every 2-group is equivalent to a strict 2-group, although this can't be done coherently: it doesn't extend to 2-group homomorphisms.
+== Properties ==
+Weak inverses can always be assigned coherently: one can define a [[functor]] on any 2-group ''G'' that assigns a weak inverse to each object and makes that object an [[adjoint equivalance]] in the monoidal category ''G''.
+Given a [[bicategory]] ''B'' and an object ''x'' of ''B'', there is an ''automorphism 2-group'' of ''x'' in ''B'', written Aut<sub>''B''</sub>(''x'').  The objects are the [[automorphism]]s of ''x'', with multiplication given by composition, and the morphisms are the invertible 2-morphisms between these.  If ''B'' is a [[2-groupoid]] (so all objects and morphisms are weakly invertible) and ''x'' is its only object, then Aut<sub>''B''</sub>(''x'') is the only data left in ''B''.  Thus, 2-groups may be identified with one-object 2-groupoids, much as groups may be idenitified with one-object groupoids and monoidal categories may be identified with one-object bicategories.
+If ''G'' is a strict 2-group, then the objects of ''G'' form a group, called the ''underlying group'' of ''G'' and written ''G''<sub>0</sub>.  This will not work for arbitrary 2-groups; however, if one identifies isomorphic objects, then the [[equivalence class]]es form a group, called the ''fundamental group'' of ''G'' and written π<sub>1</sub>(''G'').  (Note that even for a strict 2-group, the fundamental group will only be a [[quotient group]] of the underlying group.)
+As a monoidal category, any 2-group ''G'' has a unit object ''I''<sub>''G''</sub>.  The [[automorphism group]] of ''I''<sub>''G''</sub> is an [[abelian group]] by the [[Eckmann–Hilton argument]], written Aut(''I''<sub>''G''</sub>) or π<sub>2</sub>(''G'').
+The fundamental group of ''G'' [[group action|act]]s on either side of π<sub>2</sub>(''G''), and the associator of ''G'' (as a monoidal category) defines an element of the [[group cohomology|cohomology group]] H<sup>3</sup>(π<sub>1</sub>(''G''),π<sub>2</sub>(''G'')).  In fact, 2-groups are [[classification theorem|classified]] in this way: given a group π<sub>1</sub>, an abelian group π<sub>2</sub>, a group action of π<sub>1</sub> on π<sub>2</sub>, and an element of H<sup>3</sup>(π<sub>1</sub>,π<sub>2</sub>), there is a unique ([[up to]] equivalence) 2-group ''G'' with π<sub>1</sub>(''G'') isomorphic to π<sub>1</sub>, π<sub>2</sub>(''G'') isomorphic to π<sub>2</sub>, and the other data corresponding.
+== Fundamental 2-group ==
+Given a [[topological space]] ''X'' and a point ''x'' in that space, there is a ''fundamental 2-group'' of ''X'' at ''x'', written Π<sub>2</sub>(''X'',''x'').  As a monoidal category, the objects are [[loop (topology)|loop]]s at ''x'', with multiplication given by concatenation, and the morphisms are basepoint-preserving [[homotopy|homotopies]] between loops, with these morphisms identified if they are themselves homotopic.
+Conversely, given any 2-group ''G'', one can find a unique ([[up to]] [[weak homotopy equivalence]]) [[pointed space|pointed]] [[connected space]] whose fundamental 2-group is ''G'' and whose [[homotopy group]]s π<sub>''n''</sub> are trivial for ''n''&nbsp;&gt; 2.  In this way, 2-groups [[classification theorem|classify]] pointed connected weak homotopy 2-types.  This is a generalisation of the construction of [[Eilenberg–Mac Lane space]]s.
+If ''X'' is a topological space with basepoint ''x'', then the [[fundamental group]] of ''X'' at ''x'' is the same as the fundamental group of the fundamental 2-group of ''X'' at ''x''; that is,
+: <math> \pi_{1}(X,x) = \pi_{1}(\Pi_{2}(X,x)) .\!</math>
+This fact is the origin of the term "fundamental" in both of its 2-group instances.
+Similarly,
+: <math> \pi_{2}(X,x) = \pi_{2}(\Pi_{2}(X,x)) .\!</math>
+Thus, both the first and second [[homotopy group]]s of a space are contained within its fundamental 2-group.  As this 2-group also defines an action of π<sub>1</sub>(''X'',''x'') on π<sub>2</sub>(''X'',''x'') and an element of the cohomology group H<sup>3</sub>(π<sub>1</sub>(''X'',''x''),π<sub>2</sub>(''X'',''x'')), this is precisely the data needed to form the [[Postnikov tower]] of ''X'' if ''X'' is a pointed connected homotopy 2-type.
+== References ==
+* [[John C. Baez]] and Aaron D. Lauda, [http://arxiv.org/abs/math.QA/0307200 Higher-Dimensional Algebra V: 2-Groups], Theory and Applications of Categories 12 (2004), 423–491.
+* [[John C. Baez]] and Danny Stevenson, [http://arxiv.org/abs/0801.3843 The Classifying Space of a Topological 2-Group].
+* [[Ronald Brown (mathematician)|R. Brown]] and P.J. Higgins, ``The classifying space of a crossed complex'', Math. Proc. Camb. Phil. Soc. 110 (1991) 95-120.
+* [[Ronald Brown (mathematician)|R. Brown]], P.J. Higgins, R. Sivera, '' Nonabelian algebraic topology: filtered spaces, crossed complexes, cubical homotopy groupoids,'' EMS Tracts in Mathematics Vol. 15, 703 pages. (2011).
+* Hendryk Pfeiffer, [http://arxiv.org/abs/math/0411468 2-Groups, trialgebras and their Hopf categories of representations], Adv. Math. 212 No. 1 (2007) 62–108.
+* [http://ncatlab.org/nlab/show/2-group 2-group] at the [[nLab|''n''-Category Lab]].
+== External links ==
+* 2008 [http://mat.uab.cat/~kock/crm/hocat/cat-groups/ Workshop on Categorical Groups] at the [[Centre de Recerca Matemàtica]]
+[[Category:Group theory]]
+[[Category:Higher category theory]]
+[[Category:Homotopy theory]]