Saved in:
Bibliographic Details
Main Authors: Shafiee, Amin, Ghanaatian, Zahra, Charbonnier, Benoit, Nikdast, Mahdi
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2510.27013
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866911242626531328
author Shafiee, Amin
Ghanaatian, Zahra
Charbonnier, Benoit
Nikdast, Mahdi
author_facet Shafiee, Amin
Ghanaatian, Zahra
Charbonnier, Benoit
Nikdast, Mahdi
contents In this paper, we propose a novel fully programmable linear photonic processor, which we call LightPro, with improved scalability, performance, and footprint. At the heart of LightPro are compact, low-loss, and programmable silicon photonic (SiPh) directional coupler (DC) devices that deploy phase-change material (PCM) for programming the DC's splitting ratio. By thermally inducing phase transitions in the PCM, the coupling coefficient of the DC can be dynamically adjusted to achieve different splitting ratios in the device output. Building on this device foundation, we develop a neural architecture search (NAS) and pruning algorithm to optimize the architecture of the processor for performing MVM operations. Our simulation results show that LightPro achieves up to an 85% reduction in footprint and more than 50% improvement in power consumption. In addition, LightPro is evaluated by performing inference with weight matrices trained on MNIST and linearly separable Gaussian datasets, showing less than a 5% drop in accuracy when scaling up the network. Prototyping results, using a commercial photonic processor (iPronics SmartLight), show LightPro's efficiency and performance (e.g., computational accuracy) compared to conventional photonic MVM hardware, demonstrating the experimental evaluation and feasibility of LightPro for next-generation photonic AI accelerators.
format Preprint
id arxiv_https___arxiv_org_abs_2510_27013
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle LightPro: A Linear Photonic Processor with Full Programmability
Shafiee, Amin
Ghanaatian, Zahra
Charbonnier, Benoit
Nikdast, Mahdi
Optics
In this paper, we propose a novel fully programmable linear photonic processor, which we call LightPro, with improved scalability, performance, and footprint. At the heart of LightPro are compact, low-loss, and programmable silicon photonic (SiPh) directional coupler (DC) devices that deploy phase-change material (PCM) for programming the DC's splitting ratio. By thermally inducing phase transitions in the PCM, the coupling coefficient of the DC can be dynamically adjusted to achieve different splitting ratios in the device output. Building on this device foundation, we develop a neural architecture search (NAS) and pruning algorithm to optimize the architecture of the processor for performing MVM operations. Our simulation results show that LightPro achieves up to an 85% reduction in footprint and more than 50% improvement in power consumption. In addition, LightPro is evaluated by performing inference with weight matrices trained on MNIST and linearly separable Gaussian datasets, showing less than a 5% drop in accuracy when scaling up the network. Prototyping results, using a commercial photonic processor (iPronics SmartLight), show LightPro's efficiency and performance (e.g., computational accuracy) compared to conventional photonic MVM hardware, demonstrating the experimental evaluation and feasibility of LightPro for next-generation photonic AI accelerators.
title LightPro: A Linear Photonic Processor with Full Programmability
topic Optics
url https://arxiv.org/abs/2510.27013