电阻抗断层成像
软机器人
触觉传感器
叠加原理
计算机科学
电阻抗
有限元法
人工智能
材料科学
计算机视觉
导电体
触觉知觉
声学
生物医学工程
机器人
感知
物理
工程类
复合材料
结构工程
电气工程
神经科学
生物
量子力学
作者
David Hardman,Thomas George Thuruthel,Fumiya Iida
出处
期刊:Materials today electronics
日期:2023-04-03
卷期号:4: 100032-100032
被引量:22
标识
DOI:10.1016/j.mtelec.2023.100032
摘要
Combining functional soft materials with electrical impedance tomography is a promising method for developing continuum sensorized soft robotic skins with high resolutions. However, reconstructing the tactile stimuli from surface electrode measurements is a challenging ill-posed modelling problem, with FEM and analytic models facing a reality gap. To counter this, we propose and demonstrate a model-free superposition method which uses small amounts of real-world data to develop deformation maps of a soft robotic skin made from a self-healing ionically conductive hydrogel, the properties of which are affected by temperature, humidity, and damage. We demonstrate how this method outperforms a traditional neural network for small datasets, obtaining an average resolution of 12.1 mm over a 170 mm circular skin. Additionally, we explore how this resolution varies over a series of 15,000 consecutive presses, during which damages are continuously propagated. Finally, we demonstrate applications for functional robotic skins: damage detection/localization, environmental monitoring, and multi-touch recognition - all using the same sensing material.
科研通智能强力驱动
Strongly Powered by AbleSci AI