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    • Harry Gindi points out that “infinity-field” redirects here, clashing with the unrelated entry of the same name.

      I can’t fix it right now. Maybe later.

      diff, v8, current

    • brief category:people-entry for hyperlinking references

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    • starting something – not done yet

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    • brief category:people-entry for hyperlinking references

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    • brief category:people-entry for hyperlinking references

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    • brief category:people-entry for hyperlinking references

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    • an absolute minimum, just to make the term linkable

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    • I rewrote a good bit of the entry sheaf, trying to polish and strengthen the exposition.

      The rewritten material is what now constituttes the section “Definition”. This subsumes essentially everything that was there before, except for some scattered remarks which I removed and instad provided hyperlinks for, since they have meanwhile better discussions in other entries.

      I left the discussion of sheaves and the general notion of localization untouched (it is now in the section “Sheaves” and localization”). This would now need to be harmonized notationally a bit better. Maybe later.

    • a stub entry, for the moment just to make the link work

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    • For some text I need to explain the relation between sequents in the syntax of dependent type theory and morphisms in their categorical semantics.

      I wanted to explain this table:

      types terms
      (∞,1)-topos theory XEType XtXE
      homotopy type theory x:XE(x):Type x:Xt(x):E(x)

      So I was looking for a place where to put it. This way I noticed that sequent used to redirect to sequent calculus. I think this doesn’t do justice to the notion and so I have

      • split off a new entry sequent

      • added a brief Idea-blurb

      • added my table and some explanation leading up to it

      leaving the whole entry in genuinely stubby state. But no harm done, I think, if we compare to the previous state of affairs.

    • Created a stub for this concept.

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    • Todd,

      when you see this here and have a minute, would you mind having a look at monoidal category to see if you can remove the query-box discussion there and maybe replace it by some crisp statement?

      Thanks!

    • Created a stub for the concept.

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    • I added to star-autonomous category a mention of “*-autonomous functors”.

    • externalizing the table, so we can update it across several pages

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    • Created:

      Beck modules

      The category of Beck modules over a C^∞-ring A is equivalent to the category of ordinary modules over the underlying real algebra of A.

      This is established using the proof given at Beck module for ordinary rings, using the fact that ideals of C^∞-rings coincide with ideals in the ordinary sense and the square zero extension construction used there can be promoted to a C^∞-ring using Taylor expansions.

      Furthermore, the resulting notion of a Beck derivation coincides with that of a C^∞-derivation.

      Kainz–Kriegl–Michor modules

      A different, nonequivalent definition was proposed by Kainz–Kriegl–Michor in 1987.

      Suppose k is a commutative ring. Denote by Polyk the following category. Objects are k-modules. Morphisms MN are polynomial maps MN, i.e., elements of SymM*kN.

      A commutative algebra A can be identified with a product-preserving functor FinPolykSet, where FinPolyk is the full subcategory of Polyk on finitely generated free modules. The value A(X) for XFinPolyk can be thought of as the space of regular functions SpecAX, where SpecA is the Zariski spectrum of A.

      The starting observation is that a module M over a commutative k-algebra A can be identified with a dinatural transformation (dinatural in XCartPoly)

      η:Polyk(X,M)×A(X)M.

      We require η to be linear in the first argument.

      That is to say, to specify an A-module M, we have to single out polynomial maps knM, together with a way to compose a polynomial map knM with a regular function SpecAkn, obtaining a regular map SpecAM. Interpreting M as the module of sections of a quasicoherent sheaf over SpecA, a regular map SpecAM can be restricted to the diagonal SpecA, obtaining an element of M as required.

      The proposal of Kainz–Kriegl–Michor is then to replace polynomial maps with smooth maps:

      A C^∞-module over a C^∞-ring A is a Hausdorff locally convex topological vector space M together with a dinatural transformation

      η:C(X,M)×A(X)M

      that is linear in the first argument. If η is also continuous in the first argument, we say that M is a continuous C^∞-module.

      Topological vector spaces in the above definition can be replaced by any notion of a vector space that allows for smooth maps, e.g., convenient vector space etc.

      Related concepts

      References

      • G. Kainz, A. Kriegl, P. Michor, C∞-algebras from the functional analytic view point, Journal of Pure and Applied Algebra 46:1 (1987), 89-107. doi

      v1, current

    • Created:

      Idea

      The abstract notion of a derivation corresponding to that of a Beck module.

      Definition

      Given a category C with finite limits, a Beck module in C over an object AC is an abelian group object in the slice category C/A.

      The forgetful functor from modules to rings is modeled by the forgetful functor

      UA:Ab(C/A)C/A.

      Given MAb(C/A), a Beck derivation AM is a a morphism idAUA(M) in C/A.

      If UA has a left adjoint ΩA, then ΩA is known as the Beck module of differentials over A. Thus, Beck derivations AM are in bijection with morphisms of Beck modules

      ΩAM,

      generalizing the universal property of Kähler differentials.

      Examples

      For ordinary commutative algebras, Beck derivations coincide with ordinary derivations.

      For C^∞-rings, Beck derivations coincide with C^∞-derivations.

      References

      The original definition is due to Jon Beck. An exposition can be found in Section 6.1 of

      v1, current

    • added a remark (here) that the expression 1i<jn(xjxi) changes sign under exchange of any pair of variables.

      Also tried to beautify the formatting throught the entry.

      diff, v4, current

    • Started this page. No doubt it could be more elegant.

      v1, current

    • brief category:people-entry for hyperlinking references

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    • brief category:people-entry for hyperlinking references

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    • brief category:people-entry for hyperlinking references

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    • I started an idea section at transgression, but it could probably use some going over by an expert. I hope I didn’t mess things up too badly. I was reading Urs’ note on “integration without integration” on the train ride home and fooled myself into thinking I understood something.

      By the way, this reminded me of a discussion we had a while back

      Integrals: Loops space vs target space

    • brief category:people-entry for hyperlinking references

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    • brief category:people-entry for hyperlinking references

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    • brief category:people-entry for hyperlinking references

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    • brief category:people-entry for hyperlinking references

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    • I wrote a little piece at general covariance on how to formalize the notion in homotopy type theory. Just for completeness, I also ended up writing a little blurb at the beginning about the genera idea of general covariance.

    • creating this minimal entry, just to make the term linkable

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    • brief category:people-entry for hyperlinking references

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    • Page created, but author did not leave any comments.

      Anonymous

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    • added to polynomial functor the evident but previously missing remark why it is called a “polynomial”, here.

    • Mentioned the alternative terminology “Zappa–Szép product” and added redirects.

      diff, v5, current

    • The cotangent complex theorem

      Natalie Stewart

      diff, v3, current

    • Adding the actual definition.

      Natalie Stewart

      diff, v5, current

    • I have added to orthogonal factorization system

      1. in the Definition-section three equivalent explicit formulations of the definition;

      2. in the Properties-section the statement of the cancellability property.

      Wanted to add more (and to add the proofs). But have to quit now. Maybe later.

    • At the old entry cohomotopy used to be a section on how it may be thought of as a special case of non-abelian cohomology. While I (still) think this is an excellent point to highlight, re-reading this old paragraph now made me feel that it was rather clumsily expressed. Therefore I have rewritten (and shortened) it, now the third paragraph of the Idea-section.

      (We had had long discussion about this entry back in the days, but it must have been before we switched to nForum discussion, because on the nForum there seems to be no trace of it.)

    • added section labels and a table of contents

      Anonymous

      diff, v6, current

    • starting page on antithesis partial orders

      Anonymouse

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    • a stub entry, for the moment just to make the link work

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    • starting page on zero-dimensional rings

      Anonymouse

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    • brief category:people-entry for hyperlinking references

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