Elliptic function

In complex analysis, an elliptic function is a meromorphic function that is periodic in two directions. Just as a periodic function of a real variable is defined by its values on an interval, an elliptic function is determined by its values on a fundamental parallelogram, which then repeat in a lattice. Such a doubly periodic function cannot be holomorphic, as it would then be a bounded entire function, and by Liouville's theorem every such function must be constant. In fact, an elliptic function must have at least two poles (counting multiplicity) in a fundamental parallelogram, as it is easy to show using the periodicity that a contour integral around its boundary must vanish, implying that the residues of any simple poles must cancel.

Historically, elliptic functions were first discovered by Niels Henrik Abel as inverse functions of elliptic integrals, and their theory was improved by Carl Gustav Jacobi; these in turn were studied in connection with the problem of the arc length of an ellipse, whence the name derives. Jacobi's elliptic functions have found numerous applications in physics, and were used by Jacobi to prove some results in elementary number theory. A more complete study of elliptic functions was later undertaken by Karl Weierstrass, who found a simple elliptic function in terms of which all the others could be expressed. Besides their practical use in the evaluation of integrals and the explicit solution of certain differential equations, they have deep connections with elliptic curves and modular forms.

Definition

Formally, an elliptic function is a function f meromorphic on \mathbb{C} for which there exist two non-zero complex numbers \omega_1 and \omega_2 with \frac{\omega_1}{\omega_2}\notin\mathbb{R}, such that f(z)=f(z+\omega_1) and f(z)=f(z+\omega_2) for all z\in\mathbb{C}.

Denoting the "lattice of periods" by \Lambda=\left\{ m\omega_1+n\omega_{2}\mid m,n\in\mathbb{Z}\right\} , it follows that f(z)=f(z+\omega) for all \omega\in\Lambda.

There are two families of 'canonical' elliptic functions: those of Jacobi and those of Weierstrass. Although Jacobi's elliptic functions are older and more directly relevant to applications, modern authors mostly follow Karl Weierstrass when presenting the elementary theory, because his functions are simpler, and any elliptic function can be expressed in terms of them.

Weierstrass's elliptic functions

With the definition of elliptic functions given above (which is due to Weierstrass) the Weierstrass elliptic function \wp\left(z\right) is constructed in the most obvious way: given a lattice \Lambda as above, put

\wp\left(z\right)=\frac{1}{z^{2}}+\sum_{\omega\in\Lambda\smallsetminus\left\{ 0\right\} }\left(\frac{1}{\left(z-\omega\right)^{2}}-\frac{1}{\omega^{2}}\right)

This function is clearly invariant with respect to the transformation z\mapsto z+\omega for any \omega\in\Lambda. The addition of the -\frac{1}{\omega^{2}} terms is necessary to make the sum converge. The technical condition to ensure that an infinite sum such as this converges to a meromorphic function is that on any compact set, after omitting the finitely many terms having poles in that set, the remaining series converges normally. On any compact disk defined by \left|z\right|\leq R, and for any \left|\omega\right|>2R, one has

\left|\frac{1}{\left(z-\omega\right)^{2}}-\frac{1}{\omega^{2}}\right|=\left|\frac{2\omega z-z^{2}}{\omega^{2}\left(\omega-z\right)^{2}}\right|=\left|\frac{z\left(2-\frac{z}{\omega}\right)}{\omega^{3}\left(1-\frac{z}{\omega}\right)^{2}}\right|\leq\frac{10 R}{\left|\omega\right|^{3}}

and it can be shown that the sum

\sum_{\omega\neq0}\frac{1}{\left|\omega\right|^{3}}

converges regardless of \Lambda.[1]

By writing \wp as a Laurent series and explicitly comparing terms, one may verify that it satisfies the relation

\left(\wp'\left(z\right)\right)^2=4\left(\wp\left(z\right)\right)^3-g_2 \wp\left(z\right)-g_3

where

g_2=60\sum_{\omega\in\Lambda\smallsetminus\left\{ 0\right\} }\frac{1}{\omega^4}

and

g_3=140\sum_{\omega\in\Lambda\smallsetminus\left\{ 0\right\} }\frac{1}{\omega^6}.

This means that the pair \left(\wp,\wp'\right) parametrize an elliptic curve.

The functions \wp take different forms depending on \Lambda, and a rich theory is developed when one allows \Lambda to vary. To this effect, put \omega_1=1 and \omega_2=\tau, with \operatorname{Im}\left(\tau\right)>0. (After a rotation and a scaling factor, any lattice may be put in this form.)

A holomorphic function in the upper half plane H=\left\{ z\in\mathbb{C}|Im\left(z\right)>0\right\} which is invariant under linear fractional transformations with integer coefficients and determinant 1 is called a modular function. That is, a holomorphic function h:H\rightarrow\mathbb{C} is a modular function if

h\left(\tau\right)=h\left(\frac{a\tau+b}{c\tau+d}\right) for all \left(\begin{matrix}a & c\\
b & d
\end{matrix}\right)\in \text{SL}_{2}\left(\mathbb{Z}\right).

One such function is Klein's j-invariant, defined by

j\left(\tau\right)=\frac{1728g_{2}^{3}}{g_{2}^{3}-27g_{3}^{2}} where g_{2} and g_{3} are as above.

Jacobi's elliptic functions

Main article: Theta function
Auxiliary rectangle construction

There are twelve Jacobian elliptic functions. Each of the twelve corresponds to an arrow drawn from one corner of a rectangle to another. The corners of the rectangle are labeled, by convention, s, c, d and n. The rectangle is understood to be lying on the complex plane, so that s is at the origin, c is at the point K on the real axis, d is at the point K + iK' and n is at point iK' on the imaginary axis. The numbers K and K' are called the quarter periods. The twelve Jacobian elliptic functions are then pq, where each of p and q is one of the letters s, c, d, n.

The Jacobian elliptic functions are then the unique doubly periodic, meromorphic functions satisfying the following three properties:

More generally, there is no need to impose a rectangle; a parallelogram will do. However, if K and iK' are kept on the real and imaginary axis, respectively, then the Jacobi elliptic functions pq u will be real functions when u is real.

Properties

See also

References

  1. Cartan, Henri (1995). Elementary Theory of Analytic Functions of One or Several Complex Variables. Dover Publications. p. 154. ISBN 9780486685434.

External links

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