Geometric landscape annealing as an optimization principle underlying the coherent Ising machine

TL;DR

This paper develops a theoretical framework for understanding how the coherent Ising machine (CIM), a physical optimization device, navigates complex energy landscapes during annealing, revealing phase transitions and guiding optimal schedules.

Contribution

It introduces a detailed geometric landscape analysis of the CIM, connecting spin-glass theory with annealing dynamics, and proposes optimal annealing schedules based on phase transition insights.

Findings

Identifies phase transitions in the CIM energy landscape from flat to rough to rigid.

Develops a cavity method linking landscape response to supersymmetry breaking.

Provides theoretically motivated annealing schedules for near-ground state solutions.

Abstract

Given the fundamental importance of combinatorial optimization across many diverse application domains, there has been widespread interest in the development of unconventional physical computing architectures that can deliver better solutions with lower resource costs. These architectures embed discrete optimization problems into the annealed, analog evolution of nonlinear dynamical systems. However, a theoretical understanding of their performance remains elusive, unlike the cases of simulated or quantum annealing. We develop such understanding for the coherent Ising machine (CIM), a network of optical parametric oscillators that can be applied to any quadratic unconstrained binary optimization problem. Here we focus on how the CIM finds low-energy solutions of the Sherrington-Kirkpatrick spin glass. As the laser gain is annealed, the CIM interpolates between gradient descent on the soft-spin energy landscape, to optimization on coupled binary spins. By exploiting spin-glass theory, we develop a detailed understanding of the evolving geometry of the high-dimensional CIM energy landscape as the laser gain increases, finding several phase transitions, from flat, to rough, to rigid. Additionally, we develop a cavity method that provides a precise geometric interpretation of supersymmetry breaking in terms of the response of a rough landscape to specific perturbations. We confirm our theory with numerical experiments, and find detailed information about critical points of the landscape. Our extensive analysis of phase transitions provides theoretically motivated optimal annealing schedules that can reliably find near-ground states. This analysis reveals geometric landscape annealing as a powerful optimization principle and suggests many further avenues for exploring other optimization problems, as well as other types of annealed dynamics, including chaotic, oscillatory or quantum dynamics.