English

Integrated multi-operand optical neurons for scalable and hardware-efficient deep learning

Optics 2023-06-01 v1 Artificial Intelligence Hardware Architecture Emerging Technologies

Abstract

The optical neural network (ONN) is a promising hardware platform for next-generation neuromorphic computing due to its high parallelism, low latency, and low energy consumption. However, previous integrated photonic tensor cores (PTCs) consume numerous single-operand optical modulators for signal and weight encoding, leading to large area costs and high propagation loss to implement large tensor operations. This work proposes a scalable and efficient optical dot-product engine based on customized multi-operand photonic devices, namely multi-operand optical neurons (MOON). We experimentally demonstrate the utility of a MOON using a multi-operand-Mach-Zehnder-interferometer (MOMZI) in image recognition tasks. Specifically, our MOMZI-based ONN achieves a measured accuracy of 85.89% in the street view house number (SVHN) recognition dataset with 4-bit voltage control precision. Furthermore, our performance analysis reveals that a 128x128 MOMZI-based PTCs outperform their counterparts based on single-operand MZIs by one to two order-of-magnitudes in propagation loss, optical delay, and total device footprint, with comparable matrix expressivity.

Keywords

Cite

@article{arxiv.2305.19592,
  title  = {Integrated multi-operand optical neurons for scalable and hardware-efficient deep learning},
  author = {Chenghao Feng and Jiaqi Gu and Hanqing Zhu and Rongxing Tang and Shupeng Ning and May Hlaing and Jason Midkiff and Sourabh Jain and David Z. Pan and Ray T. Chen},
  journal= {arXiv preprint arXiv:2305.19592},
  year   = {2023}
}

Comments

19 pages, 10 figures

R2 v1 2026-06-28T10:51:37.738Z