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We have the following quote from Eichler: "There are five elementary arithmetical operations: addition, subtraction, multiplication, division, and… modular forms."

Why did Eichler consider modular forms "elementary arithmetical operations"? Not to mention that subtraction and division are just addition and multiplication with inverse elements. Can anybody shed some light on his train of thought?

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My interpretation of the quote is different. (Granted, whether Eichler really said such a thing is a different question). It should refer to solving the algebraic equations, to the legacy of Abel and Galois and to Kronecker's Jugendtraum! To the book of Taniyama and Shimura, whereby certain abelian equations are solved by adjoining the moduli of a relevant abelian variety. In this sense, from the point of view of exact solutions to algebraic equations, the modular functions such as $j$ are indeed a natural, inevitable complement to the basic arithmetic operations $+, \times, \sqrt[n]{\cdot}$. This falls into the rubric of explicit class field theory. For a connection to modular forms such as $\Delta(\tau)$, see Ribet's converse to Herbrandt's theorem; a great introduction to this circle of ideas is Mazur's article, "How can we construct abelian Galois extensions of basic number fields?" (Bull. AMS, vol. 48, no. 2, pp. 155-209).

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    $\begingroup$ This is also a very good answer! $\endgroup$ Commented Feb 3, 2013 at 17:22
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The way I understand the quote is the following:

Modular forms are of course not "elementary", but they are a basic operation of arithmetic in the following sense: Modular forms can be used to generate sequences of integers that are most naturally defined and studied in the context of modular forms, and can also be used to prove arithmetic identities that would be significantly harder without modular forms. Furthermore, I think modular forms are unique in this respect of being a way of producing integers/rational numbers using means that cannot be reduced to the four operations of addition, subtraction, multiplication, and division.

The classic example of this is the Ramanujan tau function; tau(n) is most naturally defined as the coefficient of q^n in the unique weight 12 cusp form Delta for SL_2(Z) with leading term q. One can come up with a number of formulas for tau(n) in terms of things that can be defined using only the four standard operations of arithmetic (some of them can be found on the mathworld page above), but the easiest way to prove that these formulas all define the same function uses modular forms. Likewise, most of the other properties of tau listed on that Mathworld page are most easily understood in terms of propreties of the associated modular form Delta.

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One question is whether Eichler really did say it. One of the nice things about Google searches these days is that they let you trace the etymology of words, phrases, and aphorisms. I see a chain of references to this quote associated with Andrew Wiles and Fermat's Last Theorem. The chain seems to begin with a BBC interview in 1996 or 1997 in which Wiles says, "There's a saying attributed to Eichler that there are five fundamental operations of arithmetic: addition, subtraction, multiplication, division, and modular forms." On the other hand, this recent paper by Edixhoven, van der Geer, and Moonen calls the quote apocryphal.

I can't trace what happened before that interview. Since the documented history of this quip currently begins there, we can start with what Wiles himself meant. The interviewer wanted to know what a modular form is, but that's not easy to explain on television. Obviously it was a facetious (and witty) answer. It was also part of a general point in the interview that modular forms are widely studied and seem fundamental.

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in p-adic Hodge theory, categories (semistable, crystalline, de-Rham, Hodge-Tate) of p-adic representations of Galois groups over local fields are proved to be equivalent to linear algebra categories (filtered modules with compatible actions). But for Galois representation of global fields, no such linear categories seem to exist, since the Galois group is more complicated, but then there are modularity results. Saying that these Galois representations correspond to modular forms (the most basic level). Of course, then according to Langlands Program, there are generalizations to automorphic forms. So, in some sense, modular forms are a "global patching" of all local linear data.

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  • $\begingroup$ Can someone briefly explain why this was marked down? (N.B. I'm not disputing the reason one way or another, just curious) $\endgroup$ Commented Feb 3, 2013 at 18:58
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    $\begingroup$ @John: I didn't vote down, but I can make a guess. The essay appears to be more of an exercise in free association than an honest attempt to answer the question. $\endgroup$
    – S. Carnahan
    Commented Feb 4, 2013 at 1:49
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I too was fascinated by this quote. And then I came across a very interesting set of slides by none other than Prof. Ken Ribet (herein PKR) titled The five fundamental operations of mathematics: addition, subtraction, multiplication, division, and modular forms

I'll try to summarize his slides below. As usual, any mistakes here are my own and not PKR's.

So, to start PKR bases his around discussing the topic in terms of counting, and solving problems equations.

This talk is about counting, and it’s about solving equations

In particular, Diophantine Equations.

PKR doesn't really discuss addition, subtraction, multiplication or division. However he does provide simple answer to the question: what the heck is modular form:

Modular forms are special functions that are analogous to the trigonometric functions like $\sin$, $\cos$, $\tan$,... in that they are periodic in the same way that $\sin$ is periodic. (Recall the formula $\sin(x + 2\pi) = \sin(x)$.) Modular forms have the periodicity of the trigonometric functions plus enough extra symmetries that they are essentially unchanged under a large group of substitutions. Because of the symmetries, it is possible to write modular forms as Fourier series $\sum_{m=0}^{\infty}{}$, where the $q$ here is a shorthand for $e^{2\pi\iota\\z}$

Any how hope this helps

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