English

Optical Neural Ordinary Differential Equations

Machine Learning 2023-02-08 v1 Optics

Abstract

Increasing the layer number of on-chip photonic neural networks (PNNs) is essential to improve its model performance. However, the successively cascading of network hidden layers results in larger integrated photonic chip areas. To address this issue, we propose the optical neural ordinary differential equations (ON-ODE) architecture that parameterizes the continuous dynamics of hidden layers with optical ODE solvers. The ON-ODE comprises the PNNs followed by the photonic integrator and optical feedback loop, which can be configured to represent residual neural networks (ResNet) and recurrent neural networks with effectively reduced chip area occupancy. For the interference-based optoelectronic nonlinear hidden layer, the numerical experiments demonstrate that the single hidden layer ON-ODE can achieve approximately the same accuracy as the two-layer optical ResNet in image classification tasks. Besides, the ONODE improves the model classification accuracy for the diffraction-based all-optical linear hidden layer. The time-dependent dynamics property of ON-ODE is further applied for trajectory prediction with high accuracy.

Keywords

Cite

@article{arxiv.2209.12898,
  title  = {Optical Neural Ordinary Differential Equations},
  author = {Yun Zhao and Hang Chen and Min Lin and Haiou Zhang and Tao Yan and Xing Lin and Ruqi Huang and Qionghai Dai},
  journal= {arXiv preprint arXiv:2209.12898},
  year   = {2023}
}
R2 v1 2026-06-28T02:08:08.135Z