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Single-chip silicon photonic engine for analog optical and microwave signals processing

Author

Listed:
  • Hong Deng

    (Ghent University - imec
    Ghent University)

  • Jing Zhang

    (Ghent University - imec
    Ghent University)

  • Emadreza Soltanian

    (Ghent University - imec
    Ghent University)

  • Xiangfeng Chen

    (Ghent University - imec
    Ghent University)

  • Chao Pang

    (Ghent University - imec
    Ghent University)

  • Nicolas Vaissiere

    (III-V Lab, a joint venture by Nokia, Thales and CEA)

  • Delphine Neel

    (III-V Lab, a joint venture by Nokia, Thales and CEA)

  • Joan Ramirez

    (III-V Lab, a joint venture by Nokia, Thales and CEA)

  • Jean Decobert

    (III-V Lab, a joint venture by Nokia, Thales and CEA)

  • Nishant Singh

    (Ghent University - imec)

  • Guy Torfs

    (Ghent University - imec)

  • Gunther Roelkens

    (Ghent University - imec
    Ghent University)

  • Wim Bogaerts

    (Ghent University - imec
    Ghent University)

Abstract

We present a photonic engine that processes both optical and microwave signals, and can convert signals between the two domains. Our photonic chip, fabricated in IMEC’s iSiPP50G silicon photonics process, is capable of both generation and detection of analog electrical and optical signals, and can program user-defined filter responses in both domains. This single chip integrates all essential photonic integrated components like modulators, optical filters, and photodetectors, as well as tunable lasers enabled by transfer-printed indium phosphide optical amplifiers. This makes it possible to operate the chip as a black-box microwave photonics processor, where the user can process high-frequency microwave signals without being exposed to inner optical operation of the chip. The system’s configuration is locally programmed through thermo-optic phase shifters and monitored by photodetectors, and can select any combination of optical or microwave inputs and outputs. We construct multiple systems with this engine to demonstrate its capabilities for different RF and optical signal processing functions, including optical and RF signal generation and filtering. This represents a key step towards compact and affordable microwave photonic systems that can enable higher-speed wireless communication networks and low-cost microwave sensing applications.

Suggested Citation

  • Hong Deng & Jing Zhang & Emadreza Soltanian & Xiangfeng Chen & Chao Pang & Nicolas Vaissiere & Delphine Neel & Joan Ramirez & Jean Decobert & Nishant Singh & Guy Torfs & Gunther Roelkens & Wim Bogaert, 2025. "Single-chip silicon photonic engine for analog optical and microwave signals processing," Nature Communications, Nature, vol. 16(1), pages 1-10, December.
    • Handle: RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-025-60100-0
    DOI: 10.1038/s41467-025-60100-0
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    References listed on IDEAS

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    1. Hanke Feng & Tong Ge & Xiaoqing Guo & Benshan Wang & Yiwen Zhang & Zhaoxi Chen & Sha Zhu & Ke Zhang & Wenzhao Sun & Chaoran Huang & Yixuan Yuan & Cheng Wang, 2024. "Integrated lithium niobate microwave photonic processing engine," Nature, Nature, vol. 627(8002), pages 80-87, March.
    2. Okky Daulay & Gaojian Liu & Kaixuan Ye & Roel Botter & Yvan Klaver & Qinggui Tan & Hongxi Yu & Marcel Hoekman & Edwin Klein & Chris Roeloffzen & Yang Liu & David Marpaung, 2022. "Ultrahigh dynamic range and low noise figure programmable integrated microwave photonic filter," Nature Communications, Nature, vol. 13(1), pages 1-8, December.
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