Modular Form

Modular Form

A function f is said to be an entire modular form of weight k if it satisfies

1. f is analytic in the Upper Half-Plane H,

2. $f\left({a\tau+b\over c\tau+d}\right)=(c\tau+d)^kf(\tau)$ whenever $\left[{\matrix{a & b\cr c & d\cr}}\right]$ is a member of the Modular Group Gamma,

3. The Fourier Series of f has the form

$\begin{displaymath}f(\tau)=\sum_{n=0}^\infty c(n)e^{2\pi in\tau}\end{displaymath}$

Care must be taken when consulting the literature because some authors use the term ``dimension -k'' or ``degree -k'' instead of ``weight k,'' and others write 2k instead of k (Apostol 1997, pp. 114-115). More general types of modular forms (which are not ``entire'') can also be defined which allow poles in H or at $i\infty$ . Since Klein's Absolute Invariant J, which is a Modular Function, has a pole at $i\infty$ , it is a nonentire modular form of weight 0.

The set of all entire forms of weight k is denoted M_k, which is a linear space over the complex field. The dimension of M_k is 1 for k=4, 6, 8, 10, and 14 (Apostol 1997, p. 119).

c(0) is the value of f at $i\infty$ , and if c(0)=0, the function is called a Cusp Form. The smallest r such that $c(r)\not=0$ is called the order of the zero of f at $i\infty$ . An estimate for c(n) states that

c(n)=O(n^2k-1)

if $f\in M_{2k}$ and is not a Cusp Form (Apostol 1997, p. 135).

If $f\not=0$ is an entire modular form of weight k, let f have N zeros in the closure of the Fundamental Region $R_\Gamma$ (omitting the vertices). Then

$\begin{displaymath}k=12N+6N(i)+4N(\rho)+12N(i\infty),\end{displaymath}$

where N(p) is the order of the zero at a point p (Apostol 1997, p. 115). In addition,

: 1. The only entire modular forms of weight k=0 are the constant functions.
: 2. If k is Odd, k<0, or k=2, then the only entire modular form of weight k is the zero function.
: 3. Every nonconstant entire modular form for weight $k\geq 4$ , where k is Even.
: 4. The only entire Cusp Form of weight k<12 is the zero function.

(Apostol 1997, p. 116).

For f an entire modular form of Even weight $k\geq 0$ , define $E_0(\tau)=1$ for all $\tau$ . Then f can be expressed in exactly one way as a sum

$\begin{displaymath}f=\sum_{r=0\atop k-12r\not=2}^{\left\lfloor{k/12}\right\rfloor } a_rE_{k-12r}\Delta^r,\end{displaymath}$

where a_r are complex numbers, E_n is an Eisenstein Series, and $\Delta$ is the Discriminant of the Weierstraß Elliptic Function. Cusp Forms of Even weight k are then those sums for which a₀=0 (Apostol 1997, pp. 117-118). Even more amazingly, every entire modular form f of weight k is a Polynomial in E₄ and E₆ given by

$\begin{displaymath}f=\sum_{a,b} c_{a,b}E_4^aE_6^a,\end{displaymath}$

where the c_a,b are complex numbers and the sum is extended over all integers $a,b\geq 0$ such that 4a+6b=k (Apostol 1998, p. 118).

Modular forms satisfy rather spectacular and special properties resulting from their surprising array of internal symmetries. Hecke discovered an amazing connection between each modular form and a corresponding Dirichlet L-Series. A remarkable connection between rational Elliptic Curves and modular forms is given by the Taniyama-Shimura Conjecture, which states that any rational Elliptic Curve is a modular form in disguise. This result was the one proved by Andrew Wiles in his celebrated proof of Fermat's Last Theorem.

References

Apostol, T. M. ``Modular Forms with Multiplicative Coefficients.'' Ch. 6 in Modular Functions and Dirichlet Series in Number Theory, 2nd ed. New York: Springer-Verlag, pp. 113-141, 1997.

Hecke, E. ``Über Modulfunktionen und die Dirichlet Reihen mit Eulerscher Produktentwicklungen. I.'' Math. Ann. 114, 1-28, 1937.

Knopp, M. I. Modular Functions in Analytic Number Theory. New York: Chelsea, 1993.

Koblitz, N. Introduction to Elliptic Curves and Modular Forms. New York: Springer-Verlag, 1993.

Rankin, R. A. Modular Forms and Functions. Cambridge, England: Cambridge University Press, 1977.

Sarnack, P. Some Applications of Modular Forms. Cambridge, England: Cambridge University Press, 1993.