Ekeland's variational principle: Difference between revisions

Revision as of 16:10, 14 November 2013

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,

π_{1} (X, x) = π_{1} (Π_{2} (X, x)) .

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

Similarly,

π_{2} (X, x) = π_{2} (Π_{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

@@ Line 1: / Line 1: @@
-Bonus:  WP Twin and WP Twin Auto Backup: (link to  )  While not a theme, I think this software is essential if you are maintaining your Wordpress blog or regularly create new blog sites. It is used by around 25% of all new websites, and there are more than 27 thousand plugins currently available. A pinch of tablet centric strategy can get your Word - Press site miles ahead of your competitors, so here are few strategies that will give your Wordpress websites and blogs an edge over your competitors:. Hosted by Your Domain on Another Web Host - In this model, you first purchase multiple-domain webhosting, and then you can build free Wordpress websites on your own domains, taking advantage of the full power of Wordpress. If you are happy with your new look then click "Activate 'New Theme'" in the top right corner. <br><br>You just download ready made templates to a separate directory and then choose a favorite one in the admin panel. Infertility can cause a major setback to the couples due to the inability to conceive. This plugin is a must have for anyone who is serious about using Word - Press. Now, I want to anxiety that not every single query will be answered. For a Wordpress website, you don't need a powerful web hosting account to host your site. <br><br>Saying that, despite the launch of Wordpress Express many months ago, there has still been no sign of a Wordpress video tutorial on offer UNTIL NOW. After sending these details, your Word - Press blog will be setup within a few days. I've applied numerous Search engine optimization-ready Word - Press themes and I can say from knowledge that I consider the Genesis Search engine marketing panel one particular of the simplest to use. These frequent updates have created menace in the task of optimization. Premium vs Customised Word - Press Themes - Premium themes are a lot like customised themes but without the customised price and without the wait. <br><br>If you loved this article and also you would like to acquire more info about [http://htxurl.info/wordpressdropboxbackup149203 wordpress backup plugin] kindly visit our own web site. Whether your Word - Press themes is premium or not, but nowadays every theme is designed with widget-ready. Cameras with a pentaprism (as in comparison to pentamirror) ensure that little mild is lost before it strikes your eye, however these often increase the cost of the digital camera considerably. One of the great features of Wordpress is its ability to integrate SEO into your site. Fast Content Update  - It's easy to edit or add posts with free Wordpress websites. The Pakistani culture is in demand of a main surgical treatment. <br><br>Many developers design websites and give them to the clients, but still the client faces problems to handle the website. If you operate a website that's been built on HTML then you might have to witness traffic losses because such a site isn't competent enough in grabbing the attention of potential consumers. You can select color of your choice, graphics of your favorite, skins, photos, pages, etc. Word - Press is an open source content management system which is easy to use and offers many user friendly features. 95, and they also supply studio press discount code for their clients, coming from 10% off to 25% off upon all theme deals.
+{{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]]