Complete Elliptic Integrals and the Arithmetic–Geometric Mean

Manuel Eberl 📧

July 3, 2026

This is a development version of this entry. It might change over time and is not stable. Please refer to release versions for citations.

Abstract

This entry builds up two theories and connects them. The first consists of the complete elliptic integrals of the first and second kind \[ \begin{aligned} K(x) &= \int_0^{\frac{\pi}{2}} (1-x \sin(t)^2)^{-\frac{1}{2}}\,\text{d}t\\ E(x) &= \int_0^{\frac{\pi}{2}} (1-x \sin(t)^2)^{\frac{1}{2}}\,\text{d}t \end{aligned} \] for real or complex $x$.

The second one is the arithmetic-geometric mean function $\text{agm}(x,y)$, which is defined as the limit of the sequence obtained by replacing the pair $(x,y)$ with the pair consisting of the arithmetic and geometric means of $x$ and $y$, i.e. $(x,y)\mapsto (\frac{1}{2}(x+y), \sqrt{xy})$.

The two theories are then connected by proving (among other things) that: \[\text{agm}(a,b) = \frac{\pi a}{2K((a^2-b^2)/a^2)}\]

Various other important properties are shown, e.g.:

  • Continuity, derivatives, antiderivatives of $K$ and $E$ as well as their relation to the hypergeometric function ${}_2 F_{1}$
  • Legendre's identity \[K(x) E(1-x) + E(x) K(1-x) - K(x) K(1-x) = \frac{\pi}{2}\]
  • The convergence of the AGM iterations, including uniform convergence and an estimate of the speed of convergence
  • Upward and downward identities for $K$ and $E$, e.g. \[K(x^2) = \frac{K\left(\frac{4x}{(1+x)^2}\right)}{1+x}\]
  • The relationship of the AGM to the Jacobi theta functions
  • The Brent–Salamin algorithm to approximate $\pi$ via AGM iterations (abstractly, without rounding error analysis)

License

BSD License

Topics

Session Arithmetic_Geometric_Mean