A Geometric Solution of the Schrödinger Bridge Problem on SO(2) via Stochastic Optimal Control

Abstract

We present a geometric coordinate-free solution to the isotropic Schrödinger bridge problem (SBP) for the kinematic equation on the Lie group SO(2). We consider the angular velocity of the system as the control input and assume that the given initial and terminal state probability density functions defined on SO(2) in our SBP are continuous and strictly positive. We solve the SBP by proving the existence and uniqueness of a solution to the so-called Schrödinger system of equations on SO(2), by showing that a fixed-point recursion is contractive in a complete metric space with respect to the Hilbert's projective metric. The geometric controller thus designed only uses the intrinsic geometric structure of SO(2) and does not embed it in the Euclidean plane to achieve the optimal density control. The numerical simulation verifies the validity of the theoretical construction of the Schrödinger bridge. The code and animations are publicly available at https://gitlab.com/a5akhtar/sbphttps://gitlab.com/a5akhtar/sbp.