面向声学感知与识别的微纳光纤传感器研究进展
Research Progress on Micro-Nano Fiber Optic Sensors for Acoustic Sensing and Recognition
DOI: 10.12677/app.2026.164031, PDF,    科研立项经费支持
作者: 范计锋*#, 程钰博:沈阳航空航天大学理学院,辽宁 沈阳;周世豪:沈阳航空航天大学航空宇航学院,辽宁 沈阳
关键词: 微纳光纤传感器声学感知语音识别信号处理光子集成Micro-Nano Fiber Sensor Acoustic Sensing Speech Recognition Signal Processing Photonic Integration
摘要: 作为人类信息交流最核心的媒介,高精度、高鲁棒性的语音感知技术是推动人机交互与智能医疗发展的关键。传统电声传感器在复杂电磁环境、生物相容性及柔性集成等方面面临固有局限。微纳光纤凭借其亚波长尺度下的强倏逝场效应、高机械柔性及本质抗电磁干扰等独特物理特性,已成为构建高灵敏度声学传感平台的研究热点。本文系统综述了面向声学感知与识别的微纳光纤传感器研究进展。首先阐述了微纳光纤的传感机理及其在微小振动与人体生理信号监测领域的奠基性应用;随后,重点梳理了其在声音信号检测及语音识别领域的探索性成果,并深入探讨了适配光纤信号非线性特征的信号处理算法与机器学习模型,旨在揭示从物理量提取到语义识别的转换逻辑。针对工程化应用,本文进一步分析了不同制备工艺的规模化潜力,以及封装材料对声学响应特性的调制作用。最后,通过与成熟电声系统的多维度对比,客观分析了光纤声学系统在成本、体积及功耗等方面的工程化瓶颈,并提出通过光子集成技术(PIC)实现解调系统小型化、低成本化的未来演进方向,为高性能光纤声学交互系统的开发提供参考。
Abstract: As the most natural and core medium for human information exchange, high-precision and robust speech perception technology is essential for the advancement of human-machine interaction and intelligent healthcare. Traditional electroacoustic sensors face inherent limitations in complex electromagnetic environments, biocompatibility, and flexible integration. Micro-nano fibers (MNFs), characterized by their strong evanescent field effects at the sub-wavelength scale, high mechanical flexibility, and intrinsic immunity to electromagnetic interference, have emerged as a prominent research focus for constructing highly sensitive acoustic sensing platforms. This paper systematically reviews the research progress of MNF-based sensors for acoustic sensing and recognition. First, the sensing mechanisms and foundational applications of MNFs in tiny vibration and human physiological signal monitoring are elaborated. Subsequently, the exploratory achievements in acoustic signal detection and speech recognition are summarized, with a detailed analysis of signal processing algorithms and machine learning models tailored to the nonlinear characteristics of optical fiber signals, aiming to reveal the transformation logic from physical measurement to semantic recognition. Addressing engineering applications, this paper further analyzes the scaling potential of various fabrication processes and the modulation effects of packaging materials on acoustic response characteristics. Finally, through multi-dimensional comparisons with mature electroacoustic systems, the engineering bottlenecks of fiber-optic acoustic systems in terms of cost, size, and power consumption are objectively analyzed. Future evolutionary directions, such as miniaturizing and cost-reducing demodulation systems via Photonic Integrated Circuits (PIC), are proposed to provide a reference for developing high-performance fiber-optic acoustic interaction systems.
文章引用:范计锋, 程钰博, 周世豪. 面向声学感知与识别的微纳光纤传感器研究进展[J]. 应用物理, 2026, 16(4): 335-348. https://doi.org/10.12677/app.2026.164031

参考文献

[1] Zhang, Q. and Tong, K. (2023) Vocal Cord Vibration Signal Recognition Model Based on Feature Engineering Preprocessing. IEEE Sensors Journal, 23, 31380-31388. [Google Scholar] [CrossRef
[2] Xu, H., Lv, Y., Qiu, D., Zhou, Y., Zeng, H. and Chu, Y. (2019) An Ultra-Stretchable, Highly Sensitive and Biocompatible Capacitive Strain Sensor from an Ionic Nanocomposite for On-Skin Monitoring. Nanoscale, 11, 1570-1578. [Google Scholar] [CrossRef] [PubMed]
[3] Zhu, Y., Zhou, R., Yao, Y., Su, S., Wang, Z. and Yan, H. (2022) Fabrication of Robust Convex Array Microstructured PDMS-Based Capacitance Sensor Molded by Laser Patterned Silicon for Human-Being Acoustic Monitoring. Materials Technology, 37, 2011-2021. [Google Scholar] [CrossRef
[4] Lee, S., Roh, H., Kim, J., Chung, S., Seo, D., Moon, W., et al. (2022) An Electret‐Powered Skin‐Attachable Auditory Sensor That Functions in Harsh Acoustic Environments. Advanced Materials, 34, Article ID: 2205537. [Google Scholar] [CrossRef] [PubMed]
[5] Gong, S., Yap, L.W., Zhu, Y., Zhu, B., Wang, Y., Ling, Y., et al. (2020) A Soft Resistive Acoustic Sensor Based on Suspended Standing Nanowire Membranes with Point Crack Design. Advanced Functional Materials, 30, Article ID: 1910717. [Google Scholar] [CrossRef
[6] Kang, D., Pikhitsa, P.V., Choi, Y.W., Lee, C., Shin, S.S., Piao, L., et al. (2014) Ultrasensitive Mechanical Crack-Based Sensor Inspired by the Spider Sensory System. Nature, 516, 222-226. [Google Scholar] [CrossRef] [PubMed]
[7] Wang, H.S., Hong, S.K., Han, J.H., Jung, Y.H., Jeong, H.K., Im, T.H., et al. (2021) Biomimetic and Flexible Piezoelectric Mobile Acoustic Sensors with Multiresonant Ultrathin Structures for Machine Learning Biometrics. Science Advances, 7, eabe5683. [Google Scholar] [CrossRef] [PubMed]
[8] Swansborough-Aston, W.A., Soltan, A., Coulson, B., Pratt, A., Chechik, V. and Douthwaite, R.E. (2023) Efficient Photoelectrochemical Kolbe C-C Coupling at BiVO4 Electrodes under Visible Light Irradiation. Green Chemistry, 25, 1067-1077. [Google Scholar] [CrossRef
[9] Xu, C., Chen, J., Zhu, Z., Liu, M., Lan, R., Chen, X., et al. (2024) Flexible Pressure Sensors in Human-Machine Interface Applications. Small, 20, Article ID: 2306655. [Google Scholar] [CrossRef] [PubMed]
[10] Zhang, L., Zhen, Y. and Tong, L. (2024) Optical Micro/Nanofiber Enabled Tactile Sensors and Soft Actuators: A Review. Opto-Electronic Science, 3, Article ID: 240005. [Google Scholar] [CrossRef
[11] 童利民. 微纳光纤技术: 近期研究进展[J]. 光学学报, 2022, 42(17): 108-120.
[12] 范成磊, 罗彬彬, 吴德操, 邹雪, 饶洪承, 周富, 黄玲, 石胜辉, 胡新宇. 基于微纳光纤的柔性仿生微结构触觉传感器研究[J]. 光学学报, 2023, 43(21): 67-77.
[13] Jha, R., Mishra, P. and Kumar, S. (2024) Advancements in Optical Fiber-Based Wearable Sensors for Smart Health Monitoring. Biosensors and Bioelectronics, 254, Article ID: 116232. [Google Scholar] [CrossRef] [PubMed]
[14] Guan, B.-O., Tam, H.-Y., Lau, S.-T. and Chan, H.L.W. (2005) Ultrasonic Hydrophone Based on Distributed Bragg Reflector Fiber Laser. IEEE Photonics Technology Letters, 17, 169-171. [Google Scholar] [CrossRef
[15] Qiao, X.-G., Shao, Z.-H., Bao, W.-J. and Rong, Q.-Z. (2017) Fiber-Optic Ultrasonic Sensors and Applications. Acta Physica Sinica, 66, Article ID: 074205. [Google Scholar] [CrossRef
[16] Wu, X. and Tong, L. (2013) Optical Microfibers and Nanofibers. Nanophotonics, 2, 407-428. [Google Scholar] [CrossRef
[17] Jiang, C., Zhang, Z., Pan, J., Wang, Y., Zhang, L. and Tong, L. (2021) Finger‐Skin‐Inspired Flexible Optical Sensor for Force Sensing and Slip Detection in Robotic Grasping. Advanced Materials Technologies, 6, Article ID: 2100285. [Google Scholar] [CrossRef
[18] Yu, W., Yao, N., Pan, J., Fang, W., Li, X., Tong, L., et al. (2022) Highly Sensitive and Fast Response Strain Sensor Based on Evanescently Coupled Micro/Nanofibers. Opto-Electronic Advances, 5, Article ID: 210101. [Google Scholar] [CrossRef
[19] Li, J., Chen, J. and Xu, F. (2018) Sensitive and Wearable Optical Microfiber Sensor for Human Health Monitoring. Advanced Materials Technologies, 3, Article ID: 1800296. [Google Scholar] [CrossRef
[20] Mishra, P., Kumar, H., Sahu, S. and Jha, R. (2023) Flexible and Wearable Optical System Based on U‐Shaped Cascaded Microfiber Interferometer. Advanced Materials Technologies, 8, Article ID: 2200661. [Google Scholar] [CrossRef
[21] Wang, X., Zhou, H., Chen, M., He, Y., Zhang, Z., Gan, J., et al. (2023) Highly Sensitive Strain Sensor Based on Microfiber Coupler for Wearable Photonics Healthcare. Advanced Intelligent Systems, 5, Article ID: 2200344. [Google Scholar] [CrossRef
[22] Song, X., Wang, Q., Liu, Q., Yu, L., Wang, S., Yao, N., et al. (2023) Twisted Optical Micro/Nanofibers Enabled Detection of Subtle Temperature Variation. ACS Applied Materials & Interfaces, 15, 47177-47183. [Google Scholar] [CrossRef] [PubMed]
[23] Ge, Q., Zhou, T., Gong, T., Liang, Y., Augustine Ngiejungbwen, L. and Chen, M. (2023) Highly Sensitive Measurement of Finger Joint Angle Based on a Double-U Tapered POF Embedded in PDMS Film. Optical Fiber Technology, 76, Article ID: 103236. [Google Scholar] [CrossRef
[24] Yuan, Z., Fang, H., Xie, Y., Zhang, J., Liu, K., Guo, X., et al. (2024) Variable Optical Attenuator Based on a PDMS-Embedded Microfiber Coupler. IEEE Photonics Technology Letters, 36, 449-452. [Google Scholar] [CrossRef
[25] Yu, W., Zhu, J., Xu, Y., Tu, X., Tong, Y., Xie, Y., et al. (2024) Optical Nanofiber-Enabled Self-Detection Picobalance. ACS Photonics, 11, 2316-2323. [Google Scholar] [CrossRef
[26] Zhang, L., Pan, J., Zhang, Z., Wu, H., Yao, N., Cai, D., et al. (2020) Ultrasensitive Skin-Like Wearable Optical Sensors Based on Glass Micro/nanofibers. Opto-Electronic Advances, 3, Article ID: 190022. [Google Scholar] [CrossRef
[27] Tang, Y., Liu, H., Pan, J., Zhang, Z., Xu, Y., Yao, N., et al. (2021) Optical Micro/Nanofiber-Enabled Compact Tactile Sensor for Hardness Discrimination. ACS Applied Materials & Interfaces, 13, 4560-4566. [Google Scholar] [CrossRef] [PubMed]
[28] Xie, Y., Pan, J., Yu, L., Fang, H., Yu, S., Zhou, N., et al. (2024) Optical Micro/Nanofiber Enabled Multiaxial Force Sensor for Tactile Visualization and Human-Machine Interface. Advanced Science, 11, Article ID: 2404343. [Google Scholar] [CrossRef] [PubMed]
[29] Tang, Y., Yu, L., Pan, J., Yao, N., Geng, W., Li, X., et al. (2023) Optical Nanofiber Skins for Multifunctional Humanoid Tactility. Advanced Intelligent Systems, 5, Article ID: 2200203. [Google Scholar] [CrossRef
[30] Wang, Z., Chen, Z., Ma, L., Wang, Q., Wang, H., Leal-Junior, A., et al. (2024) Optical Microfiber Intelligent Sensor: Wearable Cardiorespiratory and Behavior Monitoring with a Flexible Wave-Shaped Polymer Optical Microfiber. ACS Applied Materials & Interfaces, 16, 8333-8345. [Google Scholar] [CrossRef] [PubMed]
[31] Liu, H., Song, X., Wang, X., Wang, S., Yao, N., Li, X., et al. (2022) Optical Microfibers for Sensing Proximity and Contact in Human-Machine Interfaces. ACS Applied Materials & Interfaces, 14, 14447-14454. [Google Scholar] [CrossRef] [PubMed]
[32] Pan, J., Zhang, Z., Jiang, C., Zhang, L. and Tong, L. (2020) A Multifunctional Skin-Like Wearable Optical Sensor Based on an Optical Micro-/Nanofibre. Nanoscale, 12, 17538-17544. [Google Scholar] [CrossRef] [PubMed]
[33] Zhu, H., Zhan, L., Dai, Q., Xu, B., Chen, Y., Lu, Y., et al. (2021) Self‐Assembled Wavy Optical Microfiber for Stretchable Wearable Sensor. Advanced Optical Materials, 9, Article ID: 2002206. [Google Scholar] [CrossRef
[34] Guo, Y., Wang, W., Shi, G., Wu, J., Sun, D. and Ma, J. (2025) Optical Smart Wearable Sensor: Pulse Waveform and Pulse Rate Monitoring with a Flexible Loop Optic-Microfiber. Journal of Lightwave Technology, 43, 1462-1468. [Google Scholar] [CrossRef
[35] Yao, N., Wang, X., Ma, S., Song, X., Wang, S., Shi, Z., et al. (2022) Single Optical Microfiber Enabled Tactile Sensor for Simultaneous Temperature and Pressure Measurement. Photonics Research, 10, Article No. 2040. [Google Scholar] [CrossRef
[36] Yang, L., Li, Y., Fang, F., Li, L., Yan, Z., Zhang, L., et al. (2022) Highly Sensitive and Miniature Microfiber-Based Ultrasound Sensor for Photoacoustic Tomography. Opto-Electronic Advances, 5, Article ID: 200076. [Google Scholar] [CrossRef
[37] Chen, R., Fernando, G.F., Butler, T. and Badcock, R.A. (2004) A Novel Ultrasound Fibre Optic Sensor Based on a Fused-Tapered Optical Fibre Coupler. Measurement Science and Technology, 15, 1490-1495. [Google Scholar] [CrossRef
[38] Tu, X., Qian, C., Feng, T., Zhen, Y., Cui, B., Li, T., et al. (2025) Insect-Inspired Micro-Optical Antenna Enables Ultrasensitive Multisensory Perception. Science Advances, 11, eaec4252. [Google Scholar] [CrossRef
[39] Yu, Y., Tian, N., Wang, Z., Gan, X., Luo, J. and Xiao, T. (2025) Ultrasensitive Fiber-Optic Sensor for AI-Enhanced Voice Recognition and 360˚ Acoustic Detection. IEEE Sensors Journal, 25, 19302-19307. [Google Scholar] [CrossRef
[40] 王智君, 黄嵊, 李昆, 杨杨, 陈复旦, 罗彬彬, 吴德操, 邹雪. 基于S型微纳光纤的声带振动传感器及语音智能识别研究[J]. 光子学报, 2025, 54(5): 28-39.
[41] Zhang, Z., Kang, Y., Yao, N., Pan, J., Yu, W., Tang, Y., et al. (2021) A Multifunctional Airflow Sensor Enabled by Optical Micro/Nanofiber. Advanced Fiber Materials, 3, 359-367. [Google Scholar] [CrossRef
[42] Liu, T., Zhang, M., Li, Z., Dou, H., Zhang, W., Yang, J., et al. (2025) Machine Learning-Assisted Wearable Sensing Systems for Speech Recognition and Interaction. Nature Communications, 16, Article No. 2363. [Google Scholar] [CrossRef] [PubMed]
[43] Dinh Le, T., An, J., Huang, Y., Vo, Q., Boonruangkan, J., Tran, T., et al. (2019) Ultrasensitive Anti-Interference Voice Recognition by Bio-Inspired Skin-Attachable Self-Cleaning Acoustic Sensors. ACS Nano, 13, 13293-13303. [Google Scholar] [CrossRef] [PubMed]
[44] Jin, B., Cao, H., Sheng, T., Gong, Z., Dong, Z., Gai, Y., et al. (2025) Flexible Hair‐Like Piezoelectric Acoustic Particle Velocity Sensor with Enhanced Sensitivity for Speaker Recognition. Advanced Functional Materials, 35, Article ID: 2417164. [Google Scholar] [CrossRef
[45] Chen, J., Li, L., Ran, W., Chen, D., Wang, L. and Shen, G. (2023) An Intelligent MXene/MoS2 Acoustic Sensor with High Accuracy for Mechano-Acoustic Recognition. Nano Research, 16, 3180-3187. [Google Scholar] [CrossRef

为你推荐