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Universal photonic artificial intelligence acceleration

Author

Listed:
  • Sufi R. Ahmed

    (Lightmatter)

  • Reza Baghdadi

    (Lightmatter)

  • Mikhail Bernadskiy

    (Lightmatter)

  • Nate Bowman

    (Lightmatter)

  • Ryan Braid

    (Lightmatter)

  • Jim Carr

    (Lightmatter)

  • Chen Chen

    (Lightmatter)

  • Pietro Ciccarella

    (Lightmatter)

  • Matthew Cole

    (Lightmatter)

  • John Cooke

    (Lightmatter)

  • Kishor Desai

    (Lightmatter)

  • Carlos Dorta

    (Lightmatter)

  • Jonathan Elmhurst

    (Lightmatter)

  • Bryce Gardiner

    (Lightmatter)

  • Elliot Greenwald

    (Lightmatter)

  • Shashank Gupta

    (Lightmatter)

  • Parry Husbands

    (Lightmatter)

  • Brian Jones

    (Lightmatter)

  • Anthony Kopa

    (Lightmatter)

  • Ho John Lee

    (Lightmatter)

  • Arulselvan Madhavan

    (Lightmatter)

  • Adam Mendrela

    (Lightmatter)

  • Nicholas Moore

    (Lightmatter)

  • Lakshmi Nair

    (Lightmatter)

  • Aditya Om

    (Lightmatter)

  • Subie Patel

    (Lightmatter)

  • Rutayan Patro

    (Lightmatter)

  • Rob Pellowski

    (Lightmatter)

  • Esha Radhakrishnani

    (Lightmatter)

  • Sandeep Sane

    (Lightmatter)

  • Nicholas Sarkis

    (Lightmatter)

  • Joe Stadolnik

    (Lightmatter)

  • Mykhailo Tymchenko

    (Lightmatter)

  • Gongyu Wang

    (Lightmatter)

  • Kurt Winikka

    (Lightmatter)

  • Alexandra Wleklinski

    (Lightmatter)

  • Josh Zelman

    (Lightmatter)

  • Richard Ho

    (OpenAI)

  • Ritesh Jain

    (Lightmatter)

  • Ayon Basumallik

    (Lightmatter)

  • Darius Bunandar

    (Lightmatter)

  • Nicholas C. Harris

    (Lightmatter)

Abstract

Over the past decade, photonics research has explored accelerated tensor operations, foundational to artificial intelligence (AI) and deep learning1–4, as a path towards enhanced energy efficiency and performance5–14. The field is centrally motivated by finding alternative technologies to extend computational progress in a post-Moore’s law and Dennard scaling era15–19. Despite these advances, no photonic chip has achieved the precision necessary for practical AI applications, and demonstrations have been limited to simplified benchmark tasks. Here we introduce a photonic AI processor that executes advanced AI models, including ResNet3 and BERT20,21, along with the Atari deep reinforcement learning algorithm originally demonstrated by DeepMind22. This processor achieves near-electronic precision for many workloads, marking a notable entry for photonic computing into competition with established electronic AI accelerators23 and an essential step towards developing post-transistor computing technologies.

Suggested Citation

  • Sufi R. Ahmed & Reza Baghdadi & Mikhail Bernadskiy & Nate Bowman & Ryan Braid & Jim Carr & Chen Chen & Pietro Ciccarella & Matthew Cole & John Cooke & Kishor Desai & Carlos Dorta & Jonathan Elmhurst &, 2025. "Universal photonic artificial intelligence acceleration," Nature, Nature, vol. 640(8058), pages 368-374, April.
    • Handle: RePEc:nat:nature:v:640:y:2025:i:8058:d:10.1038_s41586-025-08854-x
    DOI: 10.1038/s41586-025-08854-x
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