The design of underwater tactile force sensor with differential pressure structure and backpropagation neural network calibration

Jianjun Zhang, Pengyang Han, Qunpo Liu, Shasha Li, Bin Li
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Abstract

The underwater tactile force measurement was prone to cross-sensitivity, causing the difficulty in distinguishing tactile force signal with the underwater complex environment of water pressure influence. For this problem, an underwater tactile force sensor whose sensing core was based on Microelectromechanical Systems (MEMS) was designed with differential pressure typed structure. The hollow hemispherical flexible contacts located at the upper and lower end, and the hollow cylindrical shell in the middle part composed the structure of the capsule-shaped sensor. The upper flexible contact could sense the compound signal composed of water pressure and tactile force, at the same time, the lower flexible contact could measure the water pressure information. The deformation signal of the upper and lower flexible contacts could be transformed to the force sensor core’s upper and lower surfaces with silicon oil filled in the inner hollow part of the sensor. The tactile force signal could be obtained with water pressure eliminated through vector superposition method under the influence of static pressure of water. The structure and manufacture technology were introduced, and the Backpropagation (BP) neural network data regression algorithm was designed for the cross sensitivity. The experiments are conducted to demonstrate the effectiveness of the differential pressure structure in eliminating the influence of water static pressure. The results indicated that the BP neural network data regression algorithm successfully produced real tactile force signals, which is highly beneficial for the intelligent operation of underwater dexterous hand. Additionally, the sensor has an accuracy of 5%.
基于差压结构的水下触觉力传感器设计及反向传播神经网络标定
水下触觉力测量容易产生交叉灵敏度,在水压影响的水下复杂环境下难以识别触觉力信号。针对这一问题,设计了一种基于微机电系统(MEMS)的水下触觉力传感器,其传感核心为差压式结构。位于上下端的空心半球形柔性触点和中部的空心圆柱壳构成了胶囊型传感器的结构。上挠性触点可以感知水压和触觉力组成的复合信号,同时下挠性触点可以测量水压信息。通过在传感器内空心部分填充硅油,将上下柔性触点的变形信号转化为力传感器芯的上下表面。在静水压的影响下,通过矢量叠加法可以得到去除水压后的触觉力信号。介绍了传感器的结构和制造工艺,设计了反向传播(BP)神经网络数据回归算法。通过实验验证了压差结构在消除水静压影响方面的有效性。结果表明,BP神经网络数据回归算法成功生成了真实的触觉力信号,为水下灵巧手的智能操作提供了有利条件。此外,该传感器的精度为5%。
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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