Design, Characterization, and Modeling of Barometric Tactile Sensors for Underwater Applications

2023 IEEE International Conference on Soft Robotics (RoboSoft) Pub Date : 2023-04-03 DOI:10.1109/RoboSoft55895.2023.10121983

Aiden Shaevitz, M. Johnston, J. Davidson

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Abstract

In this paper we present the design and experimental characterization of a tactile sensor for underwater manipulation. Water turbidity in energetic underwater environments can degrade the performance of perception sensors, making the execution of already difficult manipulation tasks even more challenging. Tactile sensing can provide useful information in these environments. One popular type of tactile sensor for terrestrial applications uses barometric pressure sensors encased in a soft elastomer. However, the performance of these sensors in changing ambient pressures has not been investigated. We designed a custom testbed to characterize high-pressure MEMS barometers embedded in two types of silicone up to 50 PSIG ambient pressure. Using characterization results from a single barometer, we then designed two 2 × 4 tactile grids. Datasets of differential pressures (against a control sensor) for varying contact locations were used to train feedforward neural networks for point load estimation. Results show that for the grid encased in softer silicone, the model performance improved as the ambient pressure increased (average RMSE of 0.33 mm).

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水下应用气压触觉传感器的设计、表征和建模

本文介绍了一种用于水下操作的触觉传感器的设计和实验表征。在充满活力的水下环境中，水的浑浊度会降低感知传感器的性能，使本已困难的操作任务的执行变得更加具有挑战性。触觉感知可以在这些环境中提供有用的信息。一种流行的地面触觉传感器是用软弹性体包裹的气压传感器。然而，这些传感器在变化环境压力下的性能尚未得到研究。我们设计了一个定制的测试平台来测试嵌入在两种硅胶中的高压MEMS气压计，环境压力高达50 PSIG。利用单个气压计的表征结果，我们设计了两个2 × 4的触觉网格。不同接触位置的压差数据集(对控制传感器)用于训练前馈神经网络以进行点负载估计。结果表明，对于软硅树脂包裹的网格，模型性能随着环境压力的增加而提高(平均RMSE为0.33 mm)。

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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2023 IEEE International Conference on Soft Robotics (RoboSoft)

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