English

Crouching AGM, Hidden Modularity

Number Theory 2018-01-24 v1 Classical Analysis and ODEs Combinatorics

Abstract

Special arithmetic series f(x)=n=0cnxnf(x)=\sum_{n=0}^{\infty}c_nx^n, whose coefficients cnc_n are normally given as certain binomial sums, satisfy "self-replicating" functional identities. For example, the equation 1(1+4z)2f(z(1+4z)3)=1(1+2z)2f(z2(1+2z)3)\frac1{(1+4z)^2}f\biggl(\frac{z}{(1+4z)^3}\biggr)=\frac1{(1+2z)^2}f\biggl(\frac{z^2}{(1+2z)^3}\biggr) generates a modular form f(x)f(x) of weight 2 and level 7, when a related modular parametrization x=x(τ)x=x(\tau) is properly chosen. In this note we investigate the potential of describing modular forms by such self-replicating equations as well as applications of the equations that do not make use of the modularity. In particular, we outline a new recipe of generating AGM-type algorithms for computing π\pi and other related constants. Finally, we indicate some possibilities to extend the functional equations to a two-variable setting.

Keywords

Cite

@article{arxiv.1604.01106,
  title  = {Crouching AGM, Hidden Modularity},
  author = {Shaun Cooper and Jesús Guillera and Armin Straub and Wadim Zudilin},
  journal= {arXiv preprint arXiv:1604.01106},
  year   = {2018}
}

Comments

16 pages

R2 v1 2026-06-22T13:25:13.042Z