A General Differentiable Ray-Wave Framework for Hybrid Refractive-Diffractive System Modeling and Optimization

TL;DR

This paper introduces a differentiable ray-wave framework that models and optimizes hybrid refractive-diffractive optical systems, accommodating complex surface geometries and high-frequency holographic profiles for advanced optical applications.

Contribution

A novel, general differentiable model for hybrid optical systems that integrates ray and wave physics within standard ray tracing pipelines.

Findings

Enables gradient-based optimization of complex hybrid optical systems.

Supports both planar and curvilinear diffractive surfaces.

Demonstrates end-to-end optimization for systems with high spatial frequency responses.

Abstract

Hybrid optical systems combining refractive and diffractive optical responses have the potential to support new types of optical behavior, but they are difficult to model and optimize due to the disparate spatial scales and physics exhibited by ray and wave phenomena. In this work, we present a differentiable ray-wave framework that serves as a general model for hybrid refractive-diffractive optical systems and that operates as a plug-and-play module within standard ray tracing pipelines. Our model uniquely applies to both planar and curvilinear diffractive surfaces and can accommodate arbitrary holographic diffractive profiles with high spatial frequency responses. We analyze ray-wave modeling regimes that optimally account for the spatial frequency properties and spatial curvature of the diffractive surfaces, and we demonstrate the gradient-based end-to-end optimization of hybrid refractive-diffractive systems featuring planar and conformal diffractive surfaces. We anticipate that these modeling capabilities will enable new classes of hybrid optical systems relevant to computational imaging and display applications.