From mboxrd@z Thu Jan 1 00:00:00 1970 X-Msuck: nntp://news.gmane.io/gmane.science.mathematics.categories/5789 Path: news.gmane.org!not-for-mail From: Andre Joyal Newsgroups: gmane.science.mathematics.categories Subject: calculus, homotopy theory and more Date: Wed, 12 May 2010 16:02:30 -0400 Message-ID: References: <4BE81F26.4020903@dm.uba.ar> Reply-To: Andre Joyal NNTP-Posting-Host: lo.gmane.org Mime-Version: 1.0 Content-Type: text/plain; charset="iso-8859-1" Content-Transfer-Encoding: quoted-printable X-Trace: dough.gmane.org 1273757462 17326 80.91.229.12 (13 May 2010 13:31:02 GMT) X-Complaints-To: usenet@dough.gmane.org NNTP-Posting-Date: Thu, 13 May 2010 13:31:02 +0000 (UTC) To: "John Baez" , , Original-X-From: categories@mta.ca Thu May 13 15:31:00 2010 connect(): No such file or directory Return-path: Envelope-to: gsmc-categories@m.gmane.org Original-Received: from mailserv.mta.ca ([138.73.1.1]) by lo.gmane.org with esmtp (Exim 4.69) (envelope-from ) id 1OCYVA-0007xR-0n for gsmc-categories@m.gmane.org; Thu, 13 May 2010 15:31:00 +0200 Original-Received: from Majordom by mailserv.mta.ca with local (Exim 4.61) (envelope-from ) id 1OCXzm-0006vY-UO for categories-list@mta.ca; Thu, 13 May 2010 09:58:35 -0300 Original-Sender: categories@mta.ca Precedence: bulk Xref: news.gmane.org gmane.science.mathematics.categories:5789 Archived-At: Dear All, The shift n-->n+1 which occurs in the terminologies "n-braided monoidal category" =3D "(n+1)fold monoidal category" "n-connected spaces" =3D "(n+1)fold loop spaces"=20 is very natural. A similar shift occurs in calculus. The analogy between calculus and homotopy theory is far reaching. It is the basis of the theory of analytic functors of Goodwilie.=20 http://www.math.brown.edu/faculty/goodwillie.html http://arxiv.org/abs/math/0310481 http://ncatlab.org/nlab/show/Goodwillie+calculus I would to describe the very elementary aspects of this theory. I will also say a few things about the Breen-Baez-Dolan Stabilisation = Hypothesis, claiming that it is a theorem. Let me denote by K[[x]] the ring of formal power series in one variable over a field K. The ring K[[x]] bears some ressemblances with the category of pointed homotopy types (=3D pointed spaces up=20 to weak homotopy equivalences). The category of pointed=20 homotopy types is a ring (the product is the smash product=20 and the sum is the wedge). K =3D=3D=3D the category of pointed sets=20 K[[x]]=3D=3D=3D the category of pointed homotopy types x =3D=3D=3D the pointed circle. The augmentation K[[x]]-->K=20 =3D=3D=3D the functor pi_0: pointed homotopy types ---> pointed sets The augmentation ideal J=20 =3D=3D=3D the subcategory of pointed connected spaces.=20 The n+1 power of the augmentation ideal J^{n+1} =3D=3D=3D the subcategory of pointed n-connected spaces. The product of an element in J^{n+1} with an element of J^{m+1} is an element of J^{n+m+2}=20 =3D=3D=3D the smash product of a n-connected space with=20 a m-connected space is (n+m+1)-connected. Multiplication by x =3D=3D=3D the suspension functor. Division by x =3D=3D=3D the loop space functor. Notice here the difference: the loop functor is right adjoint to=20 the suspension functor, not its inverse. Moreover, the loop space of a space has a special structure (it is a group). The ideal J=3DxK[[x]] is isomorphic to K[[x]] via division by x. Similarly, the category of pointed connected spaces is equivalent to the category of topological groups via the loop space functor (it is actually an equivalence of model categories).=20 More generally, the ideal J^{n+1} is isomorphic to K[[x]] via division = by x^{n+1}. Similarly, the category of n-connected space is equivalent to the category of (n+1)-fold topological group (it is actually an equivalence of model categories) via the (n+1)-fold loop space functor. The quotient ring K[[x]]/J^{n+1} =3D=3D=3D the category of n-truncated = homotopy types (=3Dn-types) The sequence of approximations of a formal power series = f(x)=3Da_0+a_1x+... a_0 a_0+a_1x a_0+a_1x+a_2x^2 ... ... =3D=3D=3D the Postnikov tower of a pointed homotopy type X:=20 [pi0X] [pi0X;pi1X] [pi0X;pi1X,pi2X] ... ... Here, pi0X is the set of components of X, [pi0X;pi1X] is the fundamental groupoid of X, [pi0X;pi1X,pi2X] is the fundamental 2-groupoid of X, etc. The differences between f(x) and its successives approximations R0 =3D f(x)-a_0 =3D a_1x+a_2x^2+a_3x^3+.... R1 =3D f(x)-(a_0+a_1x) =3D a_2x^2+a_3x^3+a_4x^4+.... R2 =3D f(x)-(a_0+a_1x+a_2x^2) =3D a_3x^3+a_4x^4+a_5x^5+.... =3D=3D=3Dthe Whitehead tower of X, C_0=3D[0;pi1X, pi2X, pi3X,....] C_1=3D[0;0,pi2X,pi3X, pi4X,....] C_2=3D[0;0,0,pi3X,pi4X,pi4X,....] .... .... Here, C_0 is the connected component of X at the base point, C_1 is the universal cover of X constructed by from paths starting at = the base point, C_2 is the universal 2-cover of X constructed from paths starting the = base point, etc. Division by x is shifting down the coefficients of a power series If f(x)=3Da_1x+a_2x^2+..., then f(x)/x=3D a_1+a_1x^2+... Similarly, the loop space functor is shifting down the homotopy groups of a pointed space: if X=3D[a_0,a_1,a_2,...] then = Loop(X)=3D[a_1,a_2,....]. Unfortunately, the suspension functor does not shift up the homotopy = groups of a space. It is however shifting the first 2n homotopy groups of n-connected space = X (n geq 1) by a theorem of Freudenthal: http://en.wikipedia.org/wiki/Freudenthal_suspension_theorem http://en.wikipedia.org/wiki/Hans_Freudenthal=20 =20 For example, if X=3D[0;0,a_2, a_3,...] then = Susp(X)=3D[0;0,0,a_2,b_3...], and if X=3D[0;0,0, a_3, a_4, a_5,...] then Susp(X)=3D[0;0,0, 0, a_3, = a_4, b_5,...]. In other words, the canonical map=20 X-->LoopSusp(X) is a 2n-equivalence if X is n-connected (n geq 1).=20 If X[2n] denotes the 2n-type of X (the 2n-truncation of X), then we have a homotopy equivalence X[2n]-->LoopSusp(X)[2n]=3DLoop(Susp(X)[2n+1]). It follows that if X is a n-connected 2n homotopy type then we have a homotopy equivalence X--->Loop(X') where X'=3DSusp(X)[2n+1]. The space X' is said to be a *delooping* of X. By iterating this construction=20 we can construct an infinite sequence of spaces X=3DX_0, X_1, X_2,....=20 such that X_n=3DLoop(X_{n+1}). In other words, *a n-connected 2n homotopy type is an infinite loop space (canonically)* The (n+1)-fold loop space of a n-connected space=20 is an E(n+1)-space (a E(n)-space is a model of the little n-cubes operad of Boardman and Vogt, a E(1)-space is a monoid, a E(2)-space is a braided monoid,...).=20 The (n+1)-fold loop space functor induces an equivalence between the =20 category of n-connected spaces and the category of group-like = E(n+1)-space=20 (a monoid M is said to be group-like if pi0(M) is a group). Observe that the (n+1)-fold loop space of a 2n-type is a (n-1)-type. Freudenthal theorem implies that *If a (n-1) homotopy type has the structure of a group-like E(n+1)-space = then it has also the structure of an E(infty)-space (canonically)* A nicer statement is obtained by shifting the index n by one. * If a n-type has the structure of a group-like E(n+2)-space then it=20 has also the structure of an E(infty)-space (canonically)* The group-like condition can be dropped:=20 *If a n-type has the structure of an E(n+2)-space then it has the the structure of an E(infty)-space (canonically)* This is a special case of the Stabilisation Hypothesis of = Breen-Baez-Dolan; *If a n-category has the structure of an E(n+2)-category then it has the = structure of=20 symmetric monoidal category (canonically)* (Equivalently, *If a monoidal n-category is (n+1)-braided then it has = the structure of=20 symmetric monoidal category (canonically)*) It is not difficult to verify that these statements are formally = equivalent.=20 The Breen-Baez-Dolan Stabilisation Hypothesis is a theorem. 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