Integrated Microwave Photonic Sensors Based on Microresonators

Advanced Sensor Research Pub Date : 2024-04-17 DOI:10.1002/adsr.202300145

Xiaoyi Tian, Liwei Li, Linh Nguyen, Xiaoke Yi

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Abstract

Sensors stand as pivotal cornerstones of technology, driving progress across a spectrum of industries through their ability to precisely capture and interpret an extensive array of physical phenomena. Among these advancements, microwave photonic (MWP) sensing has emerged as a new sensing technique, elevating sensing speed and resolution for practical applications. Integrated MWP sensors exhibit unparalleled capabilities in ultra-sensitive, label-free nanoscale detection, offering the potential to synergize with advanced integration techniques for a compact footprint and versatile designs. This paper reviews and summarizes the development and recent advances in integrated MWP sensing, focusing on the schemes based on microresonators. The diverse array of existing schemes is systematically categorized, elucidating their operational principles and performance demonstration. Furthermore, the assistance of machine learning and deep learning in integrated MWP sensors is explored, highlighting the potential of intelligent sensing paradigms. Finally, current challenges and opportunities aimed at further advancing MWP sensors are discussed.

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基于微谐振器的集成微波光子传感器

传感器是技术的重要基石，通过其精确捕捉和解释大量物理现象的能力，推动着各行各业的进步。在这些进步中，微波光子（MWP）传感已成为一种新的传感技术，提高了实际应用中的传感速度和分辨率。集成式 MWP 传感器在超灵敏、无标记纳米级检测方面具有无与伦比的能力，可与先进的集成技术协同作用，实现紧凑的占地面积和多功能设计。本文回顾并总结了集成式 MWP 传感技术的发展和最新进展，重点是基于微谐振器的方案。本文对现有的各种方案进行了系统分类，阐明了它们的工作原理和性能演示。此外，还探讨了机器学习和深度学习对集成式 MWP 传感器的帮助，突出了智能传感范例的潜力。最后，还讨论了当前的挑战和机遇，旨在进一步推动 MWP 传感器的发展。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Advanced Sensor Research

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