Hardness recognition using a fiber Bragg grating flexible tactile sensor

IF 5 2区物理与天体物理 Q1 OPTICS

Optics and Laser Technology Pub Date : 2025-08-14 DOI:10.1016/j.optlastec.2025.113714

Muyun Qian , Yaohui Dong , Wanying Wang , Dan Li , Taiyang Sun , Qiang Zhang

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引用次数: 0

Abstract

Accurate hardness recognition is crucial for reliable robotic precision assembly. Traditional tactile sensors, constrained by electromagnetic sensitivity and poor flexibility, cannot achieve reliable hardness detection. Fiber Bragg grating (FBG) sensors offer an innovative solution for robotic hardness recognition, leveraging their anti-interference capability, high sensitivity, and flexibility. In this study, an object hardness recognition method based on FBG sensors was proposed using the force–longitudinal deformation mapping relationship. First, the force–longitudinal deformation mapping relationship of objects with different hardnesses in contact with encapsulated materials was established by theoretically analyzing the force and deformation of two objects in contact and optimizing the sensor structure using finite element modeling. Subsequently, the FBG flexible tactile sensor was fabricated and an experimental system for hardness detection was developed. The performance of the sensor was verified using pressure calibration experiments, and horizontal comparison experiments were conducted for objects comprising different materials. Longitudinal comparison experiments were also conducted for objects of the same material but different hardnesses. The experimental findings reveal significant differences in the rate of central wavelength shift over time for the FBG tactile sensor when in contact with different materials (iron: 144.86 pm/s; soap: 87.66 pm/s; eraser: 60.03 pm/s; foam: 35.34 pm/s) and across a range of hardness levels for the same material (A10–A80 silicone rubber: 32.27, 60.06, 68.71, 76.32, 96.05, 108, 115.92, and 135.9 pm/s). The results highlight the potential of FBG tactile sensors for hardness recognition, offering new approaches for advancing electronic skin and intelligent robotics technologies.

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采用光纤布拉格光栅柔性触觉传感器进行硬度识别

准确的硬度识别是机器人精密装配的关键。传统的触觉传感器受电磁灵敏度和灵活性差的限制，无法实现可靠的硬度检测。光纤布拉格光栅（FBG）传感器为机器人硬度识别提供了一种创新的解决方案，利用其抗干扰能力，高灵敏度和灵活性。本文提出了一种基于光纤光栅传感器的物体硬度识别方法。首先，通过理论分析两物体接触时的受力和变形，利用有限元建模方法对传感器结构进行优化，建立不同硬度物体与封装材料接触时的受力-纵向变形映射关系；随后，制作了FBG柔性触觉传感器，并开发了硬度检测实验系统。通过压力标定实验验证了传感器的性能，并对不同材料组成的物体进行了横向对比实验。并对同一材料不同硬度的物体进行了纵向对比试验。实验结果表明，当与不同材料接触时，FBG触觉传感器的中心波长随时间的变化速率有显著差异(铁：144.86 pm/s；肥皂：87.66 pm/s；橡皮：60.03 pm/s；泡沫：35.34 pm/s)和相同材料的硬度范围（A10-A80硅橡胶：32.27,60.06,68.71,76.32,96.05,108,115.92和135.9 pm/s）。结果突出了FBG触觉传感器在硬度识别方面的潜力，为推进电子皮肤和智能机器人技术提供了新的途径。

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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来源期刊

Optics and Laser Technology 物理-光学

CiteScore

8.50

自引率

10.00%

发文量

1060

审稿时长

3.4 months

期刊介绍： Optics & Laser Technology aims to provide a vehicle for the publication of a broad range of high quality research and review papers in those fields of scientific and engineering research appertaining to the development and application of the technology of optics and lasers. Papers describing original work in these areas are submitted to rigorous refereeing prior to acceptance for publication. The scope of Optics & Laser Technology encompasses, but is not restricted to, the following areas: •development in all types of lasers •developments in optoelectronic devices and photonics •developments in new photonics and optical concepts •developments in conventional optics, optical instruments and components •techniques of optical metrology, including interferometry and optical fibre sensors •LIDAR and other non-contact optical measurement techniques, including optical methods in heat and fluid flow •applications of lasers to materials processing, optical NDT display (including holography) and optical communication •research and development in the field of laser safety including studies of hazards resulting from the applications of lasers (laser safety, hazards of laser fume) •developments in optical computing and optical information processing •developments in new optical materials •developments in new optical characterization methods and techniques •developments in quantum optics •developments in light assisted micro and nanofabrication methods and techniques •developments in nanophotonics and biophotonics •developments in imaging processing and systems