English

I/O-efficient iterative matrix inversion with photonic integrated circuits

Emerging Technologies 2024-05-24 v3 Optics

Abstract

Photonic integrated circuits have been extensively explored for optical processing with the aim of breaking the speed bottleneck of digital electronics. However, the input/output (IO) bottleneck remains one of the key barriers. Here we report a novel photonic iterative processor (PIP) for matrix-inversion-intensive applications. The direct reuse of inputted data in the optical domain unlocks the potential to break the IO bottleneck. We demonstrate notable IO advantages with a lossless PIP for real-valued matrix inversion and integral-differential equation solving, as well as a coherent PIP with optical loops integrated on-chip, enabling complex-valued computation and a net inversion time of 1.2 ns. Furthermore, we estimate at least an order of magnitude enhancement in IO efficiency of a PIP over photonic single-pass processors and the state-of-the-art electronic processors for reservoir training tasks and MIMO precoding tasks, indicating the huge potential of PIP technology in practical applications.

Keywords

Cite

@article{arxiv.2305.18548,
  title  = {I/O-efficient iterative matrix inversion with photonic integrated circuits},
  author = {Minjia Chen and Yizhi Wang and Chunhui Yao and Adrian Wonfor and Shuai Yang and Richard Penty and Qixiang Cheng},
  journal= {arXiv preprint arXiv:2305.18548},
  year   = {2024}
}
R2 v1 2026-06-28T10:49:54.337Z