Inverse-Designed Phase Prediction in Digital Lasers Using Deep Learning and Transfer Learning

TL;DR

This paper introduces a deep learning framework using cGAN and U-Net architectures to predict phase patterns in digital lasers, effectively modeling nonlinear effects and enabling transfer learning for various structured light fields.

Contribution

It presents the first learning-based approach for digital laser phase prediction, incorporating transfer learning to improve generalization across different structured light types.

Findings

Superior performance on non-analytical light fields

Effective transfer learning across different beam classes

Provides an efficient alternative to manual phase design methods

Abstract

Digital lasers control the laser beam by dynamically updating the phase patterns of the spatial light modulator (SLM) within the laser cavity. Due to the presence of nonlinear effects, such as mode competition and gain saturation in digital laser systems, it is often necessary to rely on specifically manually tailored approach or iteration processes to find suitable loaded phases in Digital lasers. This study proposes a model based on Conditional Generative Adversarial Networks (cGAN) and a modified U-Net architecture, with designed loss functions to inverse design the loaded phases. In this work, we employ deep neural networks to learn the nonlinear effects in simulated L-shape digital lasers, enabling the prediction of SLM-loaded phases for both analytical and non-analytical arbitrary structured light fields. The results demonstrate superior performance on non-analytical light fields compared to the current methods in L-shape Digital lasers. Furthermore, a transfer learning strategy is introduced, allowing knowledge obtained from one class of structured beams to be effectively reused for another, thereby enhancing generalization and improving performance under limited training data. Importantly, this method, the first proposed learning framework for digital lasers, is not limited to the L-shaped digital lasers discussed in this study, providing an efficient alternative for generating structured light in other digital laser systems.