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    • adding formula search possibility

      Michael Kohlhase

      diff, v7, current

    • Have added to HowTo a description for how to label equations

      In the course of this I restructured the section “How to make links to subsections of a page” by giving it a few descriptively-titled subsections.

    • Corrected error in examples of nilpotent completions (claims only apply to connective spectra). Also, the parser complained about “Invalid LaTeX block: X^{\hat}_p” (which is a piece of TeX that was already present in the article, I didn’t add it), so I changed that too.

      diff, v9, current

    • This comment is invalid XHTML+MathML+SVG; displaying source. <div> <p>created <a href="https://ncatlab.org/nlab/show/nonabelian+group+cohomology">nonabelian group cohomology</a></p> <p>the secret title of this entry is "Schreier theory done right". (where "right" is right from the <a href="https://ncatlab.org/nlab/show/nPOV">nPOV</a>)</p> <p>this is the first part of the answer to</p> <blockquote> What is going on at <a href="https://ncatlab.org/nlab/show/nonabelian+Lie+algebra+cohomology">nonabelian Lie algebra cohomology</a>? </blockquote> <p>The second part of the answer is the statement:</p> <blockquote> The same. </blockquote> <p>;-)</p> <p>I'll expand on that eventually.</p> </div>

    • a bare list of references on arguments

      1. (by Connes) that Heisenberg’s original derivation of “matrix mechanics” and

      2. more generally (by Ibort et al.) that Schwinger’s less known “algebra of selective measurements”

      are both best understood, in modern language, as groupoid convolution algebras,

      to be !include-ed into relevant entries (such as quantum observables and groupoid algebra), for ease of synchronizing

      v1, current

    • i polished the definition in bundle gerbe and then reorganized the former material on “Interpretations” in a new section

      that first shows how to get a shifted central extension of groupoids form the bundle gerbe, and then demonstrates that this is the total space of a principal 2-bundle

    • Created a stub to record a new article and to satisfy a link.

      v1, current

    • I have expanded vertex operator algebra (more references, more items in the Properties-section) in partial support to a TP.SE answer that I posted here

    • Added a link to example showing that sober + T_1 does not imply Hausdorff.

      diff, v47, current

    • The induced map most likely isn’t a homeomorphism when X,YX, Y are locally compact Hausdorff.

      The original statement was in monograph by Postnikov without proof.

      Not only that, in the current form it couldn’t possibly be true, since the map could lack to be bijective.

      For more details see here: https://math.stackexchange.com/questions/3934265/adjunction-of-pointed-maps-is-a-homeomorphism .

      I’ve added a reference in the case when X,YX, Y are compact Hausdorff though.

      Adam

      diff, v13, current

    • Added:

      Specifically, a continuous functor CSetC\to Set is a right adjoint functor if and only if it is representable, in which case the left adjoint functor SetCSet\to C sends the singleton set to the representing object

      Related concepts

      diff, v3, current

    • I tried to start an entry theta function, but it’s hard to tell for me if anything of it has been saved. The nnLab is too busy doing something else than serving pages.

    • Made some some small improvements (ordering of sections, note on how the definition defaults to the usual definition of adjoints, fixing broken link in the references, etc) in relative adjoint functor.

    • Finally, some classical references added. Category class algebra added.

      diff, v6, current

    • Added a reference.

      Can we say exactly what kind of pretopos the category of small presheaves on a category C is?

      Is it a ΠW-pretopos, provided that PC is complete?

      diff, v9, current

    • As I’ve already said elsewhere, I’ve been working on this entry and trying to give a precise definition based on my hunches of what guys like Steenrod really meant by “a convenient category of topological spaces”. (I must immediately admit that I’ve never read his paper with that title. Of course, he meant specifically compactly generated Hausdorff spaces, but nowadays I think we can argue more generally.)

      I also said elsewhere that my proposed axiom on closed and open subspaces might be up for discussion. The other axioms maybe not so much: dropping any of them would seem to be a deal-breaker for what an algebraic topologist might consider “convenient”. Or so I think.

    • In codomain fibration one calls the function

      C \ (-) : C --> Cat

      mapping c to the slice category (C \ c) a pseudofunctor. However I fail to see how this is not functorial.

      A morphism f : a --> b is sent to the functor (C \ f) : (C \ a) --> (C \ b) defined by (g : c --> a) |--> (fg : c --> b), and this assignment clearly satisfies composition. It also preserves identity. So what am I missing here?

    • Added another definition.

      Added constructions to pass between different definitions.

      diff, v5, current

    • Created categorical model of dependent types, describing the various different ways to strictify category theory to match type theory and their interrelatedness. I wasn’t sure what to name this page — or even whether it should be part of some other page — but I like having all these closely related structures described in the same place.

    • brief category:people-entry for hyperlinking references

      v1, current

    • a stub entry, to give a home to today’s

      • Níckolas de Aguiar Alves: Lectures on the Bondi–Metzner–Sachs group and related topics in infrared physics [arXiv:2504.12521]

      v1, current

    • brief category:people-entry for hyperlinking references

      v1, current

    • starting page on hierarchy of universes in type theory

      Anonymouse

      v1, current

    • I have created an entry on the quaternionic Hopf fibration and then I have tried to spell out the argument, suggested to me by Charles Rezk on MO, that in GG-equivariant stable homotopy theory it represents a non-torsion element in

      [Σ G S 7,Σ G S 4] G [\Sigma^\infty_G S^7 , \Sigma^\infty_G S^4]_G \simeq \mathbb{Z} \oplus \cdots

      for GG a finite and non-cyclic subgroup of SO(3)SO(3), and SO(3)SO(3) acting on the quaternionic Hopf fibration via automorphisms of the quaternions.

      I have tried to make a rigorous and self-contained argument here by appeal to Greenlees-May decomposition and to tom Dieck splitting. But check.

    • Precursor of a left adjoint, Borceux I.3.1.

      v1, current

    • Added the reference:

      • François Métayer, Strict ω\omega-categories are monadic over polygraphs, Theory and Applications of Categories, Vol. 31, No. 27, 2016, pp. 799-806. [TAC]

      diff, v32, current

    • Since someone is adding links to Narya from other pages, we may as well have at least a stub page for it.

      v1, current

    • Many additions and changes to Leibniz algebra. The purpose is to outline that the (co)homology and abelian and even nonabelian extensions of Leibniz algebras follow the same pattern as Lie algebras. One of the historical motivations was that the Lie algebra homology of matrices which lead Tsygan to the discovery of the (the parallel discovery by Connes was just a stroke of genius without an apparent calculational need) cyclic homology. Now, if one does the Leibniz homology instead then one is supposedly lead the same way toward the Leibniz homology (for me there are other motivations for Leibniz algebras, including the business of double derivations relevant for the study of integrable systems).

      Matija and I have a proposal how to proceed toward candidates for Leibniz groups, that is an integration theory. But the proposal is going indirectly through an algebraic geometry of Lie algebras in Loday-Pirashvili category. Maybe Urs will come up with another path if it drags his interest.

    • I added to Galois connection the remark that some authors call an adjunction between posets a *monotone Galois connection* and a dual adjunction between posets an *antitone Galois connection*.

    • added more of the sections to the TOC, and more of their hyperlinked keywords

      diff, v3, current

    • creating stub on Hypothesis H

      Anonymous

      v1, current

    • following discussion here I am starting an entry with a bare list of references (sub-sectioned), to be !include-ed into the References sections of relevant entries (mainly at homotopy theory and at algebraic topology) for ease of updating and syncing these lists.

      The organization of the subsections and their items here needs work, this is just a start. Let’s work on it.

      I’ll just check now that I have all items copied, and then I will !include this entry here into homotopy theory and algebraic topology. It may best be viewed withing these entries, because there – but not here – will there be a table of contents showing the subsections here.

      v1, current

    • a minimum, just for completeness and to make broken links work

      v1, current

    • Not an edit, but is there anything concrete known about this kind of automorphism group for an infinity-group? Say its homotopy type?

      diff, v6, current

    • A stub from projective geometry.

      v1, current

    • moving the following old discussion from out of the entry to here, just for the record (it concerns a bygone version of the entry):

      +– {: .query} Tim: As I read the entry on nice topological spaces, it really refers to ’nice categories’ rather than ’nice spaces’! I have always thought of spaces such as CW-complexes and polyhedra as being ’locally nice’, but the corresponding categories are certainly not ’nice’ in the sense of nice topological space. Perhaps we need to adjust that other entry in some way.

      Toby: You're right, I think I've been linking that page wrongly. (I just now did it again on homotopy type!) Perhaps we should write locally nice space or locally nice topological space (you pick), and I'll fix all of the links tomorrow.

      Tim:I suggest locally nice space. (For some time I worked in Shape Theory where local singularities were allowed so the spaces were not locally nice!) There would need to be an entry on locally nice. I suggets various meanings are discussed briefly, e.g. locally contractible, locally Euclidean, … and so on, but each with a minimum on it as the real stuff is in CW-complex etc and these are the ’ideas’.

      Mike: Why not change the page nice topological space to be about CW-complexes and so on, and move the existing material there to something like convenient category of spaces, which is also a historically valid term? I am probably to blame for the current misleading content of nice topological space and I’d be happy to have this changed.

      Toby: I thought that nice topological space was supposed to be about special kinds of spaces, such as locally compact Hausdorff spaces, whose full subcategories of Sp\Sp are also nice. (Sort of a counterpoint to the dichotomy between nice objects and nice categories, whose theme is better fit by the example of locally Euclidean spaces). CW-complexes also apply —if you're interested in the homotopy categories.

      Mike: Well, that’s not what I thought. (-: I don’t really know any type of space that is nice and whose corresponding subcategory of Top is also nice. The category of locally compact Hausdorff spaces, for instance, is not really all that nice. In fact, I can’t think of anything particularly good about it. I don’t even see any reason for it to be complete or cocomplete!

      I think it would be better, and less confusing, to have separate pages for “nice spaces” and “nice categories of spaces,” or whatever we call them. And, as I said, I don’t see any need to invent a new term like “locally nice.”

      When algebraic topologists (and, by extension, people talking about \infty-groupoids) say “nice space” they usually mean either (1) an object of some convenient category of spaces, or (2) a CW-complex-like space, between which weak homotopy equivalences are homotopy equivalences. Actually, there is a precise term for the latter sort: an m-cofibrant space, aka a space of the (non-weak) homotopy type of a CW complex.

      Toby: I thought the full subcategory of locally compact Hausdorff spaces was cartesian closed? Maybe not, and it's not mentioned above.

      But you can see that most of the examples above list nice properties of their full subcategories. And the page begins by talking about what a lousy category Top\Top is. So it seems clearly wrong that you can't make Top\Top a nicer category by taking a full subcategory of nice spaces. (Not all of the examples are subcategories, of course.)

      Mike: It’s true that locally compact Hausdorff spaces are exponentiable in TopTop. However, I don’t think there’s any reason why the exponential should again be locally compact Hausdorff.

      I guess you are right that one could argue that compactly generated spaces themselves are “nice,” although I think the main reason they are important is that the category of compactly generated spaces is nice. I propose the following:

      1. Move the current content of this page to convenient category of spaces.
      2. Create m-cofibrant space (I’ll do that in a minute).
      3. Update most links to point to one or the other of the above, since I think that in most places one or the other of them is what is meant.
      4. At nice topological space, list many niceness properties of topological spaces. Some of them, like compact generation, will also produce a convenient category of spaces; others, like CW complexes, will be in particular m-cofibrant; and yet others, like locally contractible spacees, will do neither.

      Toby: I believe that the compact Hausdorff reflection (the Stone–Čech compactification) of Y XY^X is an exponential object.

      Anyway, your plan sounds fine, although nice category of spaces might be another title. (I guess that it's up to whoever gets around to writing it first.) Although I'm not sure that people really mean m-cofibrant spaces when they speak of nice topological spaces when doing homotopy theory; how do we know that they aren't referring to CW-complexes? (which is what I always assumed that I meant).

      Mike: I guess nice category of spaces would fit better with the existing cumbersomely-named dichotomy between nice objects and nice categories. I should have said that when people say “nice topological space” as a means of not having to worry about weak homotopy equivalences, they might as well mean (or maybe even “should” mean) m-cofibrant space. If people do mean CW-complex for some more precise reason (such as wanting to induct up the cells), then they can say “CW complex” instead.

      Re: exponentials, the Stone-Čech compactification of Y XY^X will (as long as Y XY^X isn’t already compact) have more points than Y XY^X; but by the isomorphism Hom(1,Y X)Hom(X,Y)Hom(1,Y^X)\cong Hom(X,Y), points of an exponential space have to be in bijection with continuous maps XYX\to Y.

      Toby: OK, I'll have to check how exactly they use the category of locally compact Hausdorff spaces. (One way is to get compactly generated spaces, of course, but I thought that there was more to it than that.) But anyway, I'm happy with your plan and will help you carry it out.

      =–

      diff, v23, current

    • starting page on bar induction

      Anonymouse

      v1, current

    • Added reference

      note that the website linked on this page doesn’t work anymore

      Anonymouse

      diff, v3, current

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