Separation of variables and explicit theta-function solution of the classical Steklov--Lyapunov systems: A geometric and algebraic geometric background

TL;DR

This paper revisits the explicit integration of the classical Steklov--Lyapunov systems using separation of variables, providing geometric insights and explicit solutions via theta functions, and analyzing their pole structure on Abelian varieties.

Contribution

It offers a geometric interpretation of separating variables and derives explicit theta-function solutions, clarifying the integration process of the classical systems.

Findings

Explicit theta-function solutions for Steklov--Lyapunov systems

Geometric interpretation of separating variables

Analysis of pole structure on Abelian varieties

Abstract

The paper revises the explicit integration of the classical Steklov--Lyapunov systems via separation of variables, which was first made by F. K\"otter in 1900, but was not well understood until recently. We give a geometric interpretation of the separating variables and then, applying the Weierstrass hyperelliptic root functions, obtain explicit theta-function solution to the problem. We also analyze the structure of its poles on the corresponding Abelian variety. This enables us to obtain a solution for an alternative set of phase variables of the systems that has a specific compact form.