Saved in:
Bibliographic Details
Main Authors: Wang, Kaiyuan, Li, Yunlong, Wu, Tiange, Liu, Deming, Zheng, Shuang, Zhang, Minming
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2402.13447
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866929250441887744
author Wang, Kaiyuan
Li, Yunlong
Wu, Tiange
Liu, Deming
Zheng, Shuang
Zhang, Minming
author_facet Wang, Kaiyuan
Li, Yunlong
Wu, Tiange
Liu, Deming
Zheng, Shuang
Zhang, Minming
contents On-chip optical neural networks (ONNs) have recently emerged as an attractive hardware accelerator for deep learning applications, characterized by high computing density, low latency, and compact size. As these networks rely heavily on massive matrix multiplication, photonic computing cores for matrix computation become crucial components for on-chip ONNs, which harness the degree of freedoms (DOFs) in photonics including space, wavelength and mode dimensions. However, previous photonic computing devices have not fully utilized the orthogonality and the conversion characteristic of the waveguide modes, which as we show here, allows for the simultaneous parallel computing of several independent matrix-vector multiplications within the same device. In this work, we propose an inverse-designed photonic computing core for parallel matrix-vector multiplication. The matrices are implemented through a mode conversion process, where the input fundamental modes are simultaneously converted into several orthogonal output modes. Specifically, we target the complex-valued conversion matrices between input and output modes and inversely design the dielectric distribution within the device to achieve parallel matrix-vector multiplication. As a demonstration, the proposed photonic computing core supports simultaneous parallel computing of two independent matrix-vector multiplications, with an ultra-compact footprint and high computing precision (relative error < 8%) at 1550 nm wavelength. The inverse-designed photonic computing devices hold great potential for high-performance on-chip ONNs with low energy consumption and high computing density.
format Preprint
id arxiv_https___arxiv_org_abs_2402_13447
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Inverse-designed Photonic Computing Core for Parallel Matrix-vector Multiplication
Wang, Kaiyuan
Li, Yunlong
Wu, Tiange
Liu, Deming
Zheng, Shuang
Zhang, Minming
Optics
On-chip optical neural networks (ONNs) have recently emerged as an attractive hardware accelerator for deep learning applications, characterized by high computing density, low latency, and compact size. As these networks rely heavily on massive matrix multiplication, photonic computing cores for matrix computation become crucial components for on-chip ONNs, which harness the degree of freedoms (DOFs) in photonics including space, wavelength and mode dimensions. However, previous photonic computing devices have not fully utilized the orthogonality and the conversion characteristic of the waveguide modes, which as we show here, allows for the simultaneous parallel computing of several independent matrix-vector multiplications within the same device. In this work, we propose an inverse-designed photonic computing core for parallel matrix-vector multiplication. The matrices are implemented through a mode conversion process, where the input fundamental modes are simultaneously converted into several orthogonal output modes. Specifically, we target the complex-valued conversion matrices between input and output modes and inversely design the dielectric distribution within the device to achieve parallel matrix-vector multiplication. As a demonstration, the proposed photonic computing core supports simultaneous parallel computing of two independent matrix-vector multiplications, with an ultra-compact footprint and high computing precision (relative error < 8%) at 1550 nm wavelength. The inverse-designed photonic computing devices hold great potential for high-performance on-chip ONNs with low energy consumption and high computing density.
title Inverse-designed Photonic Computing Core for Parallel Matrix-vector Multiplication
topic Optics
url https://arxiv.org/abs/2402.13447