Научный форум dxdy

To summarise: the more algebraic areas of mathematics are generally in the business of establishing ever-stronger lower bounds on the amount of structure present in some mathematical object of interest, whereas the more analytic areas of mathematics are generally in the business of establishing ever-stronger upper bounds on such structure, and nowadays there are now many areas of mathematics in which there is a crucial interplay between the two sides. But it would be a mistake to judge the stature of one of these sides of mathematics through the lens of the other, either by dismissing analysis through its lack of new structures discovered, or dismissing algebra through the lack of new upper bounds discovered.

Т.е.: концептуальные математики пыхтят, отыскивают конструкции, позволяющие компактифицировать длинные и сложные доказательства, делая эти доказательства простыми и очевидными, в то время как не-концептуальные, повелители, так сказать, живого вакуума, которым эти костыли без надобности, напротив, кладут предел усилиям своих коллег.

Интересно, что думают здешние математики по этому поводу?

The example of elliptic integrals and elliptic curves, to me, is actually quite a good example of what structured mathematics is, and what its boundaries are. We have many examples of the beautiful crystalline structure of the mathematics surrounding elliptic curves being replaced by the quite different (but to my mind, still very beautiful) disorder and anti-structure when one tries to move to more general mathematical settings. For instance, when solving completely integrable equations such as the periodic Korteweg-de Vries equation, there are a beautiful set of special solutions (coming from finite gap potentials) in which the equation can be solved exactly using elliptic integrals (or more precisely, Abelian integrals which are a hyperelliptic variant), giving quasiperiodic solutions. However, when one moves to arbitrary data (with infinitely many gaps in the spectrum of the associated Lax operator), then the situation is now a nonlinear version of a Fourier series with arbitrary coefficients, and is as chaotic and disordered as one would expect from Fourier analysis. Nevertheless, we can still extract finite gap approximants to such infinite gap solutions, thus seeing the core structured behavior amidst the general chaos. In nonperiodic settings the analogue would be what is (conjecturally, at least) a “resolution of solitons” phenomenon in which the structured component and the radiative component of the solutions can be separated asymptotically in the limit, which is a sort of nonlinear version of the way that the spectral theorem can distinguish discrete spectrum from continuous spectrum. Again, the radiative component is not structured at all, being again like an arbitrary Fourier integral, and it complements the structure of the soliton component rather than being somehow “inferior” or “softer” than it. The interplay between structured components of a PDE (e.g. ground state solitons) and radiative or perturbative components is an incredibly rich subject, requiring a combination of both structured mathematics and unstructured analysis; to loosely quote Tolstoy, “true life is lived when tiny changes occur”.

Or: the rational points on an elliptic curve have an enormous amount of deep structure, of course, starting with the basic fact that they form a finite rank abelian group. But when one moves to higher genus what one sees instead is antistructure: the structure of an integer point in a higher genus curve has the tendency to destroy or repel most other possible integer points, which is what ultimately leads to results such as Faltings’ theorem (Mordell conjecture) on such curves. This type of result is much closer in spirit to what comes out of what Grothendieck called the “arid steppes” of analysis (such as Fourier analysis): analysis tells us that when analysing the Fourier coefficients of an arbitrary function, then it is occasionally possible to have a single large Fourier coefficient (which, in this context, is the structure playing the role of an integer point on a high genus curve), but this type of structure tends to repel other such structures, so that a given function cannot have too many large Fourier coefficients at once. To encapsulate this fundamental antistructure phenomenon one needs tools from analysis (in this case, things like the Plancherel identity or Bessel’s inequality) than from the structured side of mathematics. And we know from various “no go” theorems (e.g. Matiyasevich’s theorem, unsolvability of the quintic by radicals, etc.) that once one’s varieties reach a certain level of complexity, it is no longer reasonable to expect the same paradise of structure that elliptic curves enjoy in abundance. This is not just a reflection of the relative state of development of the genus one and higher genus theory, or of the relative “depth” or “importance” of each one; it is a fundamental distinction arising from the nature of mathematics itself.

The story of Szemeredi’s theorem and its variants can be viewed as a struggle to usefully separate out the structured and unstructured components of a mathematical object, in this case a set of integers and the additive patterns it contains. The way my first result with Ben worked, we were able to use tools from combinatorics and analysis to show that the primes could essentially have only a bounded number of structures in them that could influence the number of arithmetic progressions it contained, because each such structure tended to repel all the others. And then we used Szemeredi’s theorem to conclude that no matter where these bounded number of structures were distributed, arithmetic progressions would necessarily be generated. As correctly noted above, this is a result more about progressions than about primes (my coauthor, Ben Green, tends to stress this point in his own expositions, e.g. in Section 2 of http://arxiv.org/pdf/math/0508063v1.pdf ).

In my later work with Ben (and also Tamar Ziegler) on generalising this result to further additive patterns and to obtain precise asymptotics on the counts for these patterns, the primes play a more essential role. Firstly, one has to use deeper tools from analysis (in this case, the inverse conjectures for the Gowers norms) to make the “bounded number of structures” mentioned earlier far more algebraic, and in particular to give them the structure of a nilsystem. Then, in order to keep the primes additively disjoint from such nilsystems, one now has to exploit the antistructure effect encoded by the multiplicative structure of the primes, which tends to repel additive structure (this is yet another variant of the sum-product phenomenon mentioned in previous comments). Roughly speaking, when the nilsystem is coming from an “irrational” shift, then one can use the Vinogradov-Vaughan method of bilinear sums to formalise this repulsion between multiplicative and additive structure. In the case of rational shifts, one instead has to use the classical device of L-functions, and ultimately turn to Siegel’s theorem on the zeroes of such L-functions, which again ultimately boils down to an antistructure phenomenon in which one L-function zero close to 1 tends to repel all other such zeroes. At the end of the day, it is true that our arguments do not discover any new structure on the primes beyond the multiplicative structure that was already known to be present – but then again, all our conjectures about the primes (e.g. the Mobius randomness conjecture) point to the fact that no further such structure should be expected (at least within the additive framework considered here), and instead it is the antistructure of the primes which we have been able to shed some new light on rather than the structure of the primes. Again, this antistructure is an actual feature of the primes (particularly when they are viewed additively) and is not likely to be supplanted by a structured viewpoint in any time in the near future. (Even in the function field setting, for instance, where there is substantially more structure as evidenced for instance by the Weil conjectures, the primes (i.e. irreducible polynomials) are still extremely anti-structured, with only a very small minority of primes in this case being able to be manipulated explicitly (though this situation is much better than in the rational case in which we cannot really get our hands on a single large prime at all). This small set of structured primes in the function field world is enough to solve some qualitative problems that the rational case cannot (e.g. the twin prime conjecture is known in function fields), but for quantitative conjectures such as the asymptotics for twin primes, the situation is essentially just as difficult as in the rational case.)

Let me clarify how I understand the term “conceptual”. A theory is conceptual if most of the difficulties were moved from proofs to definitions (i.e. to concepts), or they are there from the very beginning (which may happen only inside of an already conceptual theory). The definitions may be difficult to digest at the first encounter, but the proofs are straightforward. A very good and elementary example is provided by the modern form of the Stokes theorem. In 19th century we had the fundamental theorem of calculus and 3 theorems, respectively due to Gauss-Ostrogradsky, Green, and Stokes, dealing with more complicated integrals. Now we have only one theorem, usually called Stokes theorem, valid for all dimensions. After all definitions are put in place, its proof is trivial. M. Spivak nicely explains this in the preface to his classics, “Calculus on manifolds”. (I would like to note in parentheses that if the algebraic concepts are chosen more carefully than in his book, then the whole theory would be noticeably simpler and the definitions would be easier to digest. Unfortunately, such approaches did not found their way into the textbooks yet.) So, in this case the conceptualization leads to trivial proofs and much more general results. Moreover, its opens the way to further developments: the de Rham cohomology turns into the most natural next thing to study.

I think that for every branch of mathematics and every theory such a conceptualization eventually turns into a necessity: without it the subject grows into a huge body of interrelated and cross-referenced results and eventually falls apart into many to a big extent isolated problems.

В блоге Гауэрса, в сообщении о присуждении премии Абеля Делиню развернулась забавная дискуссия.
В числе прочего, Тао там высказал такую мысль:

Т.е.: концептуальные математики пыхтят, отыскивают конструкции, позволяющие компактифицировать длинные и сложные доказательства, делая эти доказательства простыми и очевидными, в то время как не-концептуальные, повелители, так сказать, живого вакуума, которым эти костыли без надобности, напротив, кладут предел усилиям своих коллег.
Интересно, что думают здешние математики по этому поводу?

When you move from SL(n) for n>2 to SL(2), you are usually change the branches of mathematics. I do not think that a theorem not dealing with the SL(2) case is in any sense incomplete. There is similarly sounding problem in another branch of mathematics, but this does not diminishes the significance of your result. SL(2,Z) is essentially free group, and, as somebody said, a free group is not a group, but just a collection of words (there is a reference for this maxim, but it is attributed there to “somebody”). Of course, by moving to SL(2,Z) you are leaving the realm of crystal-like groups and enter an amorphous area where methods of combinatorics appear to be more suitable.

Теперь мне ясно, что значит "концептуальные математики", но недостаточно ясно, что подразумевал Tao в своём выводе о "the more algebraic areas / the more analytic areas of mathematics". Кроме того, я явно упускаю, что кроется за словами "the crystalline structure", "crystal" - похоже, это какой-то термин

Мне понравилось вот это пояснение sowa http://owl-sowa.blogspot.ru/2013/03/rep ... owers.html

Let me say only point out that mathematics has any value only as human activity. It is partially a science, but to a big extent it is an art. All proofs belong to the art part. They are not needed at all for applications of mathematics. If a proof cannot be understood by humans,... they have no value. Or, rather, their value is negative: a lot of human time and computer resources were wasted.

По поводу алгебраических/аналитических областей, как я понял это, написал выше.

В той же дискуссии у Гауэрса упоминается изречение, приписываемое Манину: "доказательства важнее теорем, определения важнее доказательств".

Также я встречал еще одно высказывание Манина: "за каждым определением стоит работа поколений математиков". Как-то так, не ручаюсь за дословность.

А кристаллическая решетка здесь, имхо, просто метафора. С ней сравниваются алгебраические структуры, как нечто наиболее упорядоченное. И противопоставляется беспорядок и хаос других математических объектов.

It is not easy to explain how conceptual theorems and proofs, especially the ones of the level close to the one of Grothendieck work, could be at the same time more easy and more difficult at the same time. In fact, they are easy in one sense and difficult in another. The conceptual mathematics depends on – what one expect here? – on new concepts, or, what is the same, on the new definitions in order to solve new problems. The hard part is to discover appropriate definitions. After this proofs are very natural and straightforward up to being completely trivial in many situations. They are easy. Classically, the convoluted proofs with artificial tricks were valued most of all. Classically, it is desirable to have a most elementary proof possible, no matter how complicated it is.

A lot of efforts were devoted to attempts to prove the theorem about the distribution of primes elementary. In this case the requirement was not to use the theory of complex functions. Finally, such proof was found, and it turned out to be useless. Neither the first elementary proof, nor subsequent ones had clarified anything, and none helped to prove a much more precise form of this theorem, known as Riemann hypothesis (this is still an open problem which many consider as the most important problem in mathematics).