Isomonodromic deformation of Lam\'e connections, Painlev\'e VI equation and Okamoto symetry

Abstract

A Lam\'e connection is a logarithmic sl(2, C)-connection (E,∇) over an elliptic curve X:\y2=x(x-1)(x-t)\, t=0,1, having a single pole at infinity. When this connection is irreducible, we show that it is invariant by the standart involution and can be pushed down as a logarithmic sl(2, C)-connection over P1 with poles at 0, 1, t and ∞. Therefore, the isomonodromic deformation (Et,∇t) of an irreducible Lam\'e connection, when the elliptic curve Xt varry in the Legendre family, is parametrized by a solution q(t) of the Painlev\'e VI differential equation PVI. We compute the variation of the underlying vector bundle Et along the deformation via Tu moduli map: it is given by another solution q(t) of PVI equation related to q(t) by the Okamoto symetry s2 s1 s2 (Noumi-Yamada notation). Motivated by the Riemann-Hilbert problem for the classical Lam\'e equation, the question whether Painlev\'e transcendents do have poles is raised.