From mboxrd@z Thu Jan 1 00:00:00 1970 X-Msuck: nntp://news.gmane.io/gmane.science.mathematics.categories/2886 Path: news.gmane.org!not-for-mail From: jim stasheff Newsgroups: gmane.science.mathematics.categories Subject: fibrations as ... Date: Sun, 20 Nov 2005 09:18:17 -0500 Message-ID: <438085A9.3090403@math.upenn.edu> NNTP-Posting-Host: main.gmane.org Mime-Version: 1.0 Content-Type: text/plain; charset=ISO-8859-1; format=flowed Content-Transfer-Encoding: 7bit X-Trace: ger.gmane.org 1241018963 6219 80.91.229.2 (29 Apr 2009 15:29:23 GMT) X-Complaints-To: usenet@ger.gmane.org NNTP-Posting-Date: Wed, 29 Apr 2009 15:29:23 +0000 (UTC) To: Categories List Original-X-From: rrosebru@mta.ca Sun Nov 20 21:09:25 2005 -0400 Return-path: Envelope-to: categories-list@mta.ca Delivery-date: Sun, 20 Nov 2005 21:09:25 -0400 Original-Received: from Majordom by mailserv.mta.ca with local (Exim 4.52) id 1Ee02z-0004s8-Bg for categories-list@mta.ca; Sun, 20 Nov 2005 21:00:41 -0400 User-Agent: Mozilla/5.0 (Windows; U; Windows NT 5.1; en-US; rv:1.7.2) Gecko/20040804 Netscape/7.2 (ax) X-Accept-Language: en-us, en X-Scanned-By: MIMEDefang 2.53 on 128.91.55.26 X-Spam-Checker-Version: SpamAssassin 3.0.4 (2005-06-05) on mx1.mta.ca X-Spam-Level: X-Spam-Status: No, score=0.0 required=5.0 tests=none autolearn=disabled version=3.0.4 Original-Sender: cat-dist@mta.ca Precedence: bulk X-Keywords: X-UID: 31 Original-Lines: 327 Xref: news.gmane.org gmane.science.mathematics.categories:2886 Archived-At: John and anyone else who cares to weigh in, here are some comments from the purely topological or rather homtopy theory side: For both bundles and fibrations (e.g. over a paracompact base), your last slogan is the oldest: FIBRATIONS WITH FIBER F OVER THE SPACE B ARE "THE SAME" AS MAPS FROM B TO THE CLASSIFYING SPACE OF AUT(F) `the same as' referring to homotopy classes For bundles, Aut(F) now means the structure group of the bundle This standard approach is great - I'm not knocking it - but Schreier theory is more general: it's really a branch of "nonabelian cohomology theory". It's not all that hard to explain, either. So, I'll explain it and then talk about various simplifying assumptions people make. The goal of Schreier theory is to classify short exact sequences of groups: 1 -> F -> E -> B -> 1 for a given choice of F and B. "Exact" means that the arrows stand for homomorphisms and the image of each arrow is the kernel of the next. Here this just means that F is a normal subgroup of E and B is the quotient group E/F. Such a short exact sequence is also called an "extension of B by F", since E is bigger than B and contains F. The simplest choice is to let E be the direct sum of F and B. Usually there are other more interesting extensions as well. To classify these, the trick is to use the analogy between group theory and topology. As I explained in "week213", you can think of a group as a watered-down version of a connected space with a chosen point. The reason is that given such a space, we get a group consisting of homotopy classes of loops based at the chosen point. This is called the "fundamental group" of our space. There's a lot more information in our space than this group. But pretty much anything you can do for groups, you can do for such spaces. It's usually harder, but it's completely analogous! In particular, classifying short exact sequences is a lot like classifying "fibrations": 1 -> F -> E -> B -> 1 where now the letters stand for connected spaces with a chosen point, and the arrows stand for continuous maps. If you're a physicist or geometer you may prefer fiber bundles to "fibrations" - but luckily, they're so similar we can ignore the difference in a vague discussion like this. The idea is basically just that E maps onto B, and sitting over each point of B we have a copy of F. We call B the "base space", E the "total space" and F the "fiber". If we want to classify such fibrations we can consider carrying the fiber F around a loop in B and see how it twists around. For example, if all our spaces are smooth manifolds, we can pick a connection on the total space E and see what parallel transport around a loop in the base space B does to points in the fiber F. This gives a kind of homomorphism Omega(B) -> Aut(F) sending loops in B to invertible maps from F to itself. And, the cool thing is: this homomorphism lets us classify the fibration! Here I say "kind of homomorphism" since Omega(B), the space of loops in B based at the chosen point, is only "kind of" a topological group: the group laws only hold up to homotopy. As Peter May points out, you can use the strict monoid of Moore loops instead of Poincare's, but kind of homomorphism" still does not mean strict but rather A-\infty map even though both domain and range are strictly associative So intrepreted, the equivalence with B --> Aut F is clear. If you wnat a strict homomorphism, try using a classical connection - at least in the smooth case. But let's not worry about this technicality - especially since I'm being vague about all sorts of other equally important issues! The reason I can get away with not worrying about these issues is that I'm trying to explain a very robust powerful principle - one that can easily survive a dose of vagueness that would kill a lesser idea. Namely, if B is a connected space with a chosen basepoint, FIBRATIONS OVER THE BASE SPACE B WITH FIBER F ARE "THE SAME" AS HOMOMORPHISMS SENDING LOOPS IN B TO AUTOMORPHISMS OF F. This could be called "the basic principle of Galois theory", for reasons explained in "week213". There I explained the special case where the fiber is discrete. Then our fibration called a "covering space", and the basic principle of Galois theory boils down to this: COVERING SPACES OVER B WITH FIBER F ARE "THE SAME" AS HOMOMORPHISMS FROM THE FUNDAMENTAL GROUP OF B TO AUTOMORPHISMS OF F. Okay. Now let's use the same principle to classify extensions of a group B by a group F: 1 -> F -> E -> B -> 1 The group B here acts like "loops in the base". But what acts like "automorphisms of the fiber"? You might guess it's the group of automorphisms of F. But, it's actually the *2-group* of automorphisms of F! A 2-group is a categorified version of a group where all the usual group laws hold up to natural isomorphism. They play a role in higher gauge theory like that of groups in ordinary gauge theory. In higher gauge theory, parallel transport along a path is described by an *object* in a 2-group, while parallel transport along a path-of-paths is described by a *morphism*. In 2-form electromagnetism we use a very simple "abelian" 2-group, which has one object and either the real line or the circle as morphism. But there are other more interesting "nonabelian" examples. If you want to learn more about 2-form electromagnetism from this perspective, try "week210". For 2-groups in general, try this paper: 9) John Baez and Aaron Lauda, Higher-dimensional algebra V: 2-groups, Theory and Applications of Categories 12 (2004), 423-491. Available online at http://www.tac.mta.ca/tac/volumes/12/14/12-14abs.html or as math.QA/0307200. Anyway: it turns out that any group F gives a 2-group AUT(F) where the objects are automorphisms of F and the morphisms are "conjugations" - and conjugations correspond to homtopies at the classifying space level elements of F acting to conjugate one automorphism and yield another. And, extensions 1 -> F -> E -> B -> 1 are classified by homomorphisms B -> AUT(F) where we think of B as a 2-group with only identity morphisms. More precisely: EXTENSIONS OF THE GROUP B BY THE GROUP F ARE "THE SAME" AS HOMOMORPHISMS FROM B TO THE 2-GROUP AUT(F) It's fun to work out the details, but it's probably not a good use of our time together grinding through them here. So, I'll just sketch how it works. Starting with our extension i p 1 --> F --> E --> B --> 1 we pick a "section" s E <-- B meaning a function with p(s(b)) = b for all b in B. We can find a section because p is onto. However, the section usually *isn't* a homomorphism. Given the section s, we get a function alpha: B -> Aut(F) where Aut(F) is the group of automorphisms of F. Here's how: alpha(b) f = s(b) f s(b)^{-1} However, usually alpha *isn't* a homomorphism. So far this seems a bit sad: functions between groups want to be homomorphisms. But, we can measure how much s fails to be a homomorphism using the function g: B2 -> F given by g(b,b') = s(bb') s(b')^{-1} s(b)^{-1} Note that g = 1 iff s is a homomorphism. We can then use this function g to save alpha. The sad thing about alpha is that it's not a homomorphism... but the good thing is, it's a homomorphism up to conjugation by g! In other words: alpha(bb') f = g(b,b') [alpha(b) alpha(b') f] g(b,b')^{-1} Taken together, alpha and g satisfy some equations ("cocycle conditions") which say precisely that they form a homomorphism from B to the 2-group AUT(F). Conversely, any such homomorphism gives an extension of B by F. In fact, isomorphism classes of extensions of B by F correspond in a 1-1 way with isomorphism classes of homorphisms from B to AUT(F). So, we've classified these extensions! In fact, something even better is true! It's evil to "decategorify" by taking isomorphism classes as we did in the previous paragraph. To avoid this, we can form a groupoid whose objects are extensions of B by F, and a groupoid whose objects are homomorphisms B -> AUT(F). I'm pretty sure that if you form these groupoids in the obvious way, they're equivalent. And that's what this slogan really means: EXTENSIONS OF THE GROUP B BY THE GROUP F ARE "THE SAME" AS HOMOMORPHISMS FROM B TO THE 2-GROUP AUT(F) Ah, your 2-group must be hiding my homotopies - I'd love to see that Next, let me say how Schreier theory reduces to more familiar ideas in two special cases. People have thought a lot about the special case where F is abelian and lies in the center of E. These are called "central extensions". This is just the case where alpha = 1. The set of isomorphism classes of central extensions is called H2(B,F) - the "second cohomology" of B with coefficients in F. People have also thought about "abelian extensions". That's an even more special case where all three groups are abelian. The set of isomorphism classes of such extensions is called Ext(B,F). Since we don't make any simplifying assumptions like this in Schreier theory, it's part of a subject called "nonabelian cohomology". It was actually worked out by Dedecker in the 1960's, based on much earlier work by Schreier: 10) O. Schreier, Ueber die Erweiterung von Gruppen I, Monatschefte fur Mathematik and Physick 34 (1926), 165-180. Ueber die Erweiterung von Gruppen II, Abh. Math. Sem. Hamburg 4 (1926), 321-346. 11) P. Dedecker, Les foncteuers Ext_Pi, H2_Pi and H2_Pi non abeliens, C. R. Acad. Sci. Paris 258 (1964), 4891-4895. More recently, Schreier theory was pushed one step up the categorical ladder by Larry Breen. As far as I can tell, he essentially classified the extensions of a 2-group B by a 2-group F in terms of homomorphisms B -> AUT(F), where AUT(F) is the *3-group* of automorphisms of F: 12) Lawrence Breen, Theorie de Schreier superieure, Ann. Sci. Ecole Norm. Sup. 25 (1992), 465-514. Also available at http://www.numdam.org/numdam-bin/feuilleter?id=ASENS_1992_4_25_5 We can keep pushing Schreier theory upwards like this, but we can also expand it "sideways" by replacing groups with groupoids. You should have been annoyed by how I kept assuming my topological spaces were connected and equipped with a specified point. I did this to make them analogous to groups. For example, it's only spaces like this for which the fundamental group is sufficiently powerful to classify covering spaces. For more general spaces, we should use the fundamental *groupoid* instead of the fundamental group. And, we can set up a Schreier theory for extensions of groupoids: 13) V. Blanco, M. Bullejos and E. Faro, Categorical non abelian cohomology, and the Schreier theory of groupoids, available as math.CT/0410202. In fact, these authors note that Grothendieck did something similar back in 1971: he classified *all* groupoids fibered over a groupoid B in terms of weak 2-functors from B to Gpd, which is the 2-groupoid of groupoids! The point here is that Gpd contains AUT(F) for any fixed groupoid F: 14) Alexander Grothendieck, Categories fibrees et descente (SGA I), Lecture Notes in Mathematics 224, Springer, Berlin, 1971. Having extended the idea "sideways" like this, one can then continue marching "upwards". I don't know how much work has been done on this, but the slogan should be something like this: n-GROUPOIDS FIBERED OVER AN n-GROUPOID B ARE "THE SAME" AS WEAK (n+1)-FUNCTORS FROM B TO THE (n+1)-GROUPOID nGpd aha, weak or lax as much above will likely be also Grothendieck also studied this kind of thing with categories replacing groupoids, so there should also be an n-category version, I think... but it's more delicate to define "fibrations" for categories than for groupoids, so I'm a bit scared to state a slogan suitable for n-categories. However, I'm not scared to go from n-groupoids to omega-groupoids, which are basically the same as spaces. In terms of spaces, the slogan goes like this: SPACES FIBERED OVER THE SPACE B ARE "THE SAME" AS MAPS FROM B TO THE SPACE OF ALL SPACES This is how James Dolan taught it to me. Most mortals are scared of "the space of all spaces" - both for fear of Russell's paradox, and because we really need a *space* of all spaces, not just a mere set of them. To avoid these terrors, you can water down Jim's slogan by choosing a specific space F to be the fiber: FIBRATIONS WITH FIBER F OVER THE SPACE B ARE "THE SAME" AS MAPS FROM B TO THE CLASSIFYING SPACE OF AUT(F) where AUT(F) is the topological group of homotopy self-equivalences of F. The fearsome "space of all spaces" is then the disjoint union of the classifying spaces of all these topological groups AUT(F). It's too large to be a space unless you pass to a larger universe of sets, but otherwise it's perfectly fine. Grothendieck invented the notion of a "Grothendieck universe" for precisely this purpose: 14) Wikipedia, Grothendieck universe, http://en.wikipedia.org/wiki/Grothendieck_universe -----------------------------------------------------------------------