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I have not studied category theory in extreme depth, so perhaps this question is a little naive, but I have always wondered if analysis could be taught naturally using categories. I ask this because it seems like a quite a lot of topological and group theoretic concepts can be defined most succinctly using categorical concepts, and the categorical definitions are more revealing. So my question is: (1) Is it possible/beneficial to teach analysis using category theory? and (2) Are there any good textbooks that use this method?

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    $\begingroup$ Defining is a lot different than motivating or using. $\endgroup$ Commented Sep 15, 2010 at 0:56
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    $\begingroup$ Which parts of analysis did you have in mind, and what level of course or treatment are you thinking of? I tend to think that one should look for the nail before using the hammer, especially if the nail turns out to be a screw... $\endgroup$
    – Yemon Choi
    Commented Sep 15, 2010 at 0:58
  • $\begingroup$ What I think might be interesting is to see if one could profitably take a (more) structuralist perspective when teaching analysis. But I don't know if that is the same as "using categories". $\endgroup$
    – Yemon Choi
    Commented Sep 15, 2010 at 1:05
  • $\begingroup$ I was mainly wondering if basic concepts like the derivative and integral could be defined axiomatically, in the sense of the Eilenberg–Steenrod axioms. $\endgroup$ Commented Sep 15, 2010 at 1:30
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    $\begingroup$ The Lebesgue integral can be defined by a universal property: golem.ph.utexas.edu/category/2014/07/… $\endgroup$
    – David Roberts
    Commented May 28, 2016 at 11:24

3 Answers 3

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I hesitate to let this out, but there's always this cute little note that I learned from another MO answer (I don't know which one): https://www.maths.ed.ac.uk/~tl/glasgowpssl/banach.pdf. Maybe this will satisfy your curiosity, but I maintain that it takes a warped mind to identify such a categorical formulation of integration as the "right" way to think about integrals.


The advantage of categorical thinking in my view is that it helps to organize computations and arguments involving several different kinds of structures at the same time. For instance, (co)homology is all about capturing useful invariants associated to a complicated structure (e.g. a geometric object) in a much simpler structure (e.g. an abelian group). When we want to determine how the invariants behave under certain operations on the complicated structure (e.g. products, (co)limits) it helps to have a theory already set up to tell us what will happen to the simpler structure. That's where category theory comes into its own, and instances of this paradigm are so ubiquitous in algebra and topology that category theory has taken on a life of its own. It seems that people working in those areas have found it convenient to build categorical constructions into the foundations of their work in order to emphasize generality (one can treat algebraic varieties and solutions to diophantine equations on virtually the same footing), keep track of different notions of equivalence (e.g. homotopy versus homeomorphism), build new kinds of spaces (e.g. groupoids), and to achieve many other aims.

In many kinds of analysis, this kind of abstraction isn't necessary because there's often only one structure to keep track of: $\mathbb{R}$. When you think about it, analysis is only possible because we are willing to seriously overburden $\mathbb{R}$. Take, for example, the expression "$\frac{d}{dt}\int_X f_t(x) d\mu(x)$" and consider all of the different ways real numbers are being used. It is used as a geometric object (odds are X is built out of some construction involving the real numbers or a subspace thereof), a way to give $X$ additional structure (it wouldn't hurt to guess that $\mu$ is a real valued measure), a parameter ($t$), and a reference system ($f$ probably takes values in $\mathbb{R}$ or something related to it). In algebraic geometry, one would probably take each of these roles seriously and understand what kind of structure they are meant to bring to the problem. But part of the power and flexibility of analysis is that we can sweep these considerations under the rug and ultimately reduce most complications to considerations involving the real numbers.

All that being said, the tools of category theory and homological algebra actually have started to make their way into analysis. Because of the fact that analysts generally consider problems tied to certain very specific kinds of structure, they have historically focused on providing the sharpest and most detailed solutions to their problems rather than extracting the crude, qualitative invariants for which cohomological thinking is most appropriate. However, as analysts have become more and more attuned to the deep relationships between functional analysis and geometry, they have turned to ideas from category theory to help keep things organized. K-theory and K-homology have become indispensable tools in operator theory; there is even a bivariant functor $KK(-,-) $ from the category of C-algebras to the category of abelian groups relating the two constructions, and many deep theorems can be subsumed in the assertion that there is a category whose objects are C-algebras and whose morphism spaces are given by $KK(A,B)$. Cyclic homology and cohomology has also become extremely relevant to the interface between analysis and topology.

So ultimately I think it all comes down to what kinds of subtleties are most relevant in a given problem. There is just something fundamentally different about the kind of thinking required to estimate the propagation speed of the solution operator for a nonlinear PDE compared to the kind of thinking required to relate the fixed point theory in characteristic 0 of a linear group acting on a variety to that in characteristic p.

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    $\begingroup$ @Paul Siegel Indeed the link is broken. I believe this is the new address: maths.ed.ac.uk/~tl/glasgowpssl/banach.pdf. Can anyone confirm this? $\endgroup$
    – Alp Uzman
    Commented Jun 9, 2015 at 18:46
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    $\begingroup$ @Qfwfq: I don't think many functional analysts would agree that there is "so much category theory in functional analysis". $\endgroup$
    – Nik Weaver
    Commented May 28, 2016 at 14:10
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    $\begingroup$ I'm amused to discover ten years later that I have a "warped mind". The result is written up properly, along with various stronger and related results, here: arxiv.org/abs/2011.00412 And Alp's link is the correct one for a shorter version. I've updated it in the answer. $\endgroup$ Commented Jan 6, 2021 at 16:48
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    $\begingroup$ Seriously, no one (including me) is claiming that the universal property of $L^1$ is 'the "right" way to think about integrals'. We all agree that (1) antidifferentiation, and (2) area under the curve, are of fundamental importance. But isn't it interesting that (3) Lebesgue integrability and integration are uniquely characterized by a universal property with no conceptual dependence on either (1) or (2)? $\endgroup$ Commented Jan 6, 2021 at 16:52
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    $\begingroup$ @TomLeinster I think my mind might be warped too, because this perspective has grown on me since I wrote this answer. It also got me interested in your work on the categorical foundations of entropy, something that I think about a lot these days. Sorry for the slander - I look forward to checking out your preprint soon! $\endgroup$ Commented Jan 7, 2021 at 4:00
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Others can definitely give better opinions, but I currently have "Lectures and exercises on functional analysis" checked out from the library, and I have been enjoying the few parts that I've read so far.

I can not comment on the use of category theory in analysis, but for people who aren't very comfortable with more abstract fields where category theory plays a major role a book like the one above is great since it goes over a lot of basic category theory while keeping the main characters from analysis. At the very least it's a great way to get accustomed to the language.

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    $\begingroup$ I briefly skimmed over that book in the library a year or two ago... a nice read, though in places I felt in a strange way that AYaH wasn't going far enough. (Certainly more people at this level should say that $\ell^1$ is the free Banach space functor, left adjoint to the forgetful unit ball functor, and similar stuff. How much this helps people with Rolle's theorem, I don't know... ) $\endgroup$
    – Yemon Choi
    Commented Sep 15, 2010 at 1:32
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    $\begingroup$ @StevenGubkin I have a sinking feeling that I started writing up details for myself back in the halcyon days when I was (slightly more) Optimistic And Energetic but have lost them under the weight of 10 years of crud. There is a book of Semadeni which tried to take this kind of framework seriously, and the particular fact about the ball functor and its left adjoint was known to people like Linton, Manes and others of that generation $\endgroup$
    – Yemon Choi
    Commented Jan 6, 2021 at 18:18
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    $\begingroup$ @YemonChoi Thanks for the book recommendation. I am sorry that your optimism has been buried under the crud: this is a very easy thing to have happen. I was buried for a long time myself, but recently therapy and medications have helped me a lot. A rekindling of my mathematical joy (and the desire to share that joy) has been a nice side benefit. $\endgroup$ Commented Jan 6, 2021 at 18:33
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    $\begingroup$ @StevenGubkin Thanks Steven. If you just want a sketch of this particular adjunction it may be quicker to email me, but if you are after more of a systematic exposition of "the category of Banach spaces and contractive linear maps" then as I said unfortunately the details and my knowledge of the literature are a bit hazy by now $\endgroup$
    – Yemon Choi
    Commented Jan 6, 2021 at 18:47
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    $\begingroup$ @StevenGubkin I think we should probably continue in chat chat.stackexchange.com/rooms/info/118125/… to avoid needlessly pinging Gjergji - but if you have a specific rather than general question then sure, feel free to post it $\endgroup$
    – Yemon Choi
    Commented Jan 6, 2021 at 19:04
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This community wiki answer is addressed to the OP's comment that he is looking for an "axiomatic" approach to the integral.

I don't (yet) understand what axioms have to do with category theory. In particular, with respect to the example you give, I don't see what is particularly categorical about the Eilenberg-Steenrod axioms (unless you mean to count the functorial nature of co/homology as one of the axioms).

As an example of an axiomatic treatment of the (Riemann) integral, see Section 2 of

http://alpha.math.uga.edu/~pete/243integrals1.pdf (Wayback Machine)

(Note: this is nothing very original. For instance, shortly after I wrote this I saw that Lang had almost the same treatment in his undergraduate analysis text.)

Here I see no category theory whatsoever. Is this what you had in mind? Why or why not?

Perhaps you were talking about the Lebesgue integral rather than the Riemann integral. In that respect, I would say that the Daniell approach to the Lebesgue integral (i.e., characterizing it in terms of the completion of a certain normed linear space) feels "axiomatic" to me but still not categorical.

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    $\begingroup$ Since I may sometimes give the impression of being insufficiently categorically enlightened, shall I be the one to plug the perspective in Tom Leinster's note here: maths.gla.ac.uk/~tl/glasgowpssl (I should emphasise that I don't know if one'd want to base a course on integration around this, or even use it, but I do find it an interesting point of view.) $\endgroup$
    – Yemon Choi
    Commented Sep 15, 2010 at 2:37
  • $\begingroup$ @Yemon: the link seems interesting. Moreover, it seems at least as relevant to the question as a whole than my throw-away answer (I gave an example of an axiomatic characterization of an integral which is not categorical in nature; you gave one which is). Maybe you should post it as a separate answer? $\endgroup$ Commented Sep 15, 2010 at 3:42
  • $\begingroup$ Oops, sorry to duplicate - I spent awhile typing up my answer. $\endgroup$ Commented Sep 15, 2010 at 4:35
  • $\begingroup$ That's fine, Paul; your answer is much more thorough than anything I'd have got round to writing. (I am rather fond of TL's note as I was in the audience at that talk and failed, to my chagrin, to guess the right answer.) $\endgroup$
    – Yemon Choi
    Commented Sep 15, 2010 at 7:21
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    $\begingroup$ For an algebraic characterisation of analysis see Peter Freyd's Real Algebraic Analysis: tac.mta.ca/tac/volumes/20/10/20-10abs.html. As its publication in Theory and Applications of Categories suggests, there's category theoretic thinking going on it. $\endgroup$ Commented Sep 15, 2010 at 8:09

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