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a bare list of references, to be !include-ed into relevant entries (such as Witten genus, M5-brane elliptic genus but also inside elliptic cohomology – references) – for ease of harmonizing lists of references
started a stub for ambidextrous adjunction, but not much there yet
I added to biadjunction the statement and some references for the fact that any incoherent one can be improved to a coherent one.
am expanding out this reference item at several places:
This is a brief description of the construction that started appearing in category-theoretic accounts of deep learning and game theory. It appeared first in Backprop As Functor (https://arxiv.org/abs/1711.10455) in a specialised form, but has slowly been generalised and became a cornerstone of approaches unifying deep learning and game theory (Towards Foundations of categorical Cybernetics, https://arxiv.org/abs/2105.06332), (Categorical Foundations of Gradient-based Learning, https://arxiv.org/abs/2103.01931).
Our group here in Glasgow is using this quite heavily, so since I couldn’t find any related constructions on the nLab I decided to add it. This is also my first submission. I’ve read the “HowTo” page, followed the instructions, and I hope everything looks okay.
There’s quite a few interesting properties of Para, and eventually I hope to add them (most notably, it’s an Para is an oplax colimit of a functor BM -> Cat, where B is the delooping of a monoidal category M).
A notable thing to mention is that I’ve added some animated GIF’s of this construction. Animating categorical concepts is something I’ve been using as a pedagogical tool quite a bit (more here https://www.brunogavranovic.com/posts/2021-03-03-Towards-Categorical-Foundations-Of-Neural-Networks.html) and it seems to be a useful tool getting the idea across with less friction. If it renders well (it seems to) and is okay with you, I might add more to the Optics section, and to the neural networks section (I’m hoping to get some time to add our results there).
Bruno Gavranović
Discussion of the formulas for the standard characteristic forms has been missing in various entries (e.g. at Chern class at characteristic form, etc.). Since there is little point in discussing the Chern forms independently from the Pontrjagin forms etc. I am now making it a stand-alone section to be !include-ed into relevant entries, to have it all in one place.
Not done yet, though, but it’s a start.
added pointer to the original article:
New stub, Gauss-Manin connection.
I am going to polish the entry local system now.
The following is long forgotten discussion that had been sitting in a query box there. Everybody involved should check what of that still needs further discussion and then have that discussion here on the forum.
Urs: I am hoping that maybe David Speyer, whose expositional blog entry is linked to below, or maybe somebody else would enjoy filling in some material here.
Bruce: Could it perhaps be “On a topological space (why do we need connected?) this is the same as a sheaf of flat sections of a finite-dimensional vector bundle equipped with flat connection;”. I guess by “flat connection” in this general topological context we would mean simply a functor from the homotopy groupoid to the category of vector spaces?
Zoran Škoda: connected because otherwise you do not have even the same dimension of the typical stalk of teh lcoally constant sheaf. Maybe there is a fancy wording with groupoids avoiding this, but when you have a representation on a single space, you need connectedness.
Ronnie Brown I do not have time to write more tonight but mention that there is a section of the paper
on local systems, where a module over the fundamental groupoid of a space is regarded as a special case of a crossed complex. This seems convenient for the singular theories but has not been developed in a Cech setting. The homotopy classification theorem
where is the skeletal filtration of the CW-complex , is a crossed complex, and is the classifying space of , thus includes the local coefficient version of the classical Eilenberg-Mac Lane theory.
Tim: Quoting an exercise in Spanier (1966) on page 58:
A local system on a space is a covariant functor from the fundamental groupoid of to some category.
A reference is given to a paper by Steenrod: Homology with local coefficients, Annals 44 (1943) pp. 610 - 627.
Perhaps the entry could reflect the origins of the idea. The current one seems to me to be much too restrictive. There are other applications of the idea than the ones at present indicated, although of course those are important at the moment. Reference to vector bundles is not on the horizon in Spanier!!!!.
Local systems with other codomains than vector spaces are used in rational homotopy theory.
Urs: I am all in favor of emphasizing that “local system” is nothing but a functor from a fundamental groupoid. That’s of course right up my alley, compare the discussion with David Ben-Zvi at the “Journal Club”. Whoever finds the time to write something along these lines here should do so (and in clude in particular the reference Ronnie Brown gives above).
BUT at the same time it seems to me that many practitioners will by defualt think of the explicitly sheaf-theoretic notion when hearing “local syetem” which the entry currently states. We should emphasize this explicitly, something like: “while in general a local system is to be thought of as a representation of a fundamental groupoid, often the term is understood exclusively in its realization within abelian sheaf theory as follows …”
(to be continued in next comment)
started a category:reference entry
in the course of this I added some stuff here and there, for instance at Abel-Jacobi map. But very stubby for the moment.
brief category:people-entry for hyperlinking references at logarithm and Mercator series
Indicated where to find (in the nLab) a proof of the equivalence with the axiom of choice and with Zorn’s lemma (<– it’s there).
Added a reference
a minimum, just for completeness and to satisfy a link that had long been requetsed at Taylor series
I am hereby giving the material at determinant – Properties – As a polynomial in traces of powers its own entry, for ease of cross-linking to it (notably at trace, but also at characteristic polynomial and elsewhere)
a stub (nothing here yet), for the moment just to satisfy a link that had long been requested at determinant
expanded L-infinity-algebra as indicated on the nCafe, here
added brief pointer to the derivation of gauge group via tadpole cancellation, and some references on type I phenomenology. Will add these also to string phenomenology and to GUT, as far as relevant there
a stub, just to satisfy a requested link at string diagram
The relation between the homotopy theory of -algebras and dg-Lie algebras is discussed, or at least mentioned, in several entries. But not all of them provide the same amount of information. So I am giving this its own page now, to provide a central resource.
On the other hand, I had steam only for writing a kind of survey here, so far. But at least I’ll make all other relevant entries cross-point to/from here now.
concerning the discussion here: notice that an entry rig category had once been created, already.
I noticed we didn’t have a standalone entry on the tensor product of functors, so I created a stub and linked it with tensor product, tensor product of modules, co-Yoneda lemma, weighted colimit, free cocompletion, and geometric realization. More links and more content are still missing though, for instance I did not discuss the enriched setting.
added pointer to these two recent references, identifying further -algebra structure in Feynman amplitudes/S-matrices of perturbative quantum field theory:
Markus B. Fröb, Anomalies in time-ordered products and applications to the BV-BRST formulation of quantum gauge theories (arXiv:1803.10235)
Alex Arvanitakis, The -algebra of the S-matrix (arXiv:1903.05643)
added the statement of the Fubini theorem for ends to a new section Properties.
(I wish this page would eventually give a good introduction to ends. I remember the long time when I banged my head against Kelly’s book and just didn’t get it. Then suddenly it all became obvious. It’s some weird effect with this enriched category theory that some of it is obvious once you understand it, but looks deeply mystifying to the newcomer. Kelly’s book for instance is a magnificently elegant resource for everyone who already understands the material, but hardly serves as an exposition of the ideas involved. I am hoping that eventually the nLab entries on enriched category theory can fill this gap. Currently they do not really. But I don’t have time for it either.)
I have expanded, streamlined and re-organized a little at differential forms on simplices.
stub for model structure on spectra
included in large cardinal a jpg with a big diagram showing their relations.
created Sullivan model
added this remark:
Under the formal duality between -algebras and their Chevalley-Eilenberg dgc-algebras, connective nilpotent -algebras correspond bijectively to the connected Sullivan models (Berglund 2015, Thm. 2.3).
and pointer to
brief category:people-entry for hyperlinking references at H-space and strong homotopy map
started to add to internalization a list of links to examples. Probably we have much more.
created red-shift conjecture
One small question that has often occurred to me:
(Technical note: I chose the “Latest Changes” category, even though no change to monoidal bicategory was made yet, because monoidal bicategory appears to not have had a thread of its own yet, and it is not inconceivable that this page will evolve in the future and need a thread)
added pointer to:
brief category:people-entry for hyperlinking references at monoidal 2-category and elsewhere
… whereby the periodic table is fianlly un-grayed
brief category:people-entry for hyperlinking references at monoidal 2-category and braided monoidal 2-category
added pointer to:
sylleptic monoidal 2-category, symmetric monoidal 2-category
… but now I am running out of steam…
brief category:people-entry for hyperlinking references at Eckmann-Hilton argument and (∞,1)-operads
have added to (infinity,1)-operad the basics for the “-category of operators”-style definition
at braided monoidal 2-categiry the following query box was sitting, which I hereby move from there to here
+–{: .query} Ben Webster: I would very much like to know: what structure on a (triangulated/dg-/stable infinity/whatever you like) monoidal category would make its 2-category of module categories (give that phrase any sensible construal you like) is braided monoidal.
If one decategorifies this question, one gets the question “what structure on a ring makes its category of representations braided monoidal” and the answer to this question is well-known: a quasi-triangular quasi-Hopf structure.
I asked a MathOverflow question on the same topic. No interesting answers yet. =–