一种新型触觉探针在生物医学机器人中的应用

J. Dargahi, S. Najarian, M. Changizi
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引用次数: 1

摘要

本文对一种新型触觉探针的灵敏度进行了实验和理论研究。这些探针由三个不同的部分组成,一个是作为支撑的刚性有机玻璃,另一个是两种不同的可压缩材料。探头中加入两层PVDF压电薄膜作为传感元件,输出电压的组合与物体柔软度有关。根据被测物体的柔软度,输出电压之间有明显的差异。在测试开始时,较硬的物体往往表现出峰值较高、上升幅度较大的波形。我们利用了这些重要的特征,并进行了一些测试,以分析所设计探针的灵敏度。建立了基于触觉探头中各元件特性的数学模型,可以合理地预测系统的总体性能。实验测试了探针两个可压缩部分的柔软度、厚度和相应的面积比等参数的影响。利用所建立的模型,对实验结果进行了较好的预测,误差在可接受的范围内。该原型机在常规临床检查和手术过程中用于确定生物组织/物体的柔软度
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A Novel Tactile Probe with Applications in Biomedical Robotics
In this research, sensitivity of a novel tactile probe was investigated experimentally and theoretically. These probes are made from three different parts, a rigid Plexiglas as support and two different compressible materials. As the sensing elements, two piezoelectric films of PVDF are incorporated into the probe and the combination of the resulting output voltages is related to the object softness. Depending on the softness of the sensed objects, there is a distinct difference between the output voltages. Harder objects tend to manifest waveforms with higher peaks and with steeper rises at the start of the tests. We made use of these important features and conducted a number of tests in order to analyze the sensitivity of the designed probe. A mathematical model based on the properties of various elements in the tactile probe is developed, which could reasonably predict the general performance of the system. The effects of different parameters such as, softness of the two compressible sections of the probe, their thickness, and their corresponding area ratios are tested experimentally. Using the developed model, the experimental results are predicted with good accuracy and the discrepancy is found to be within the acceptable range. This prototype has applications in determining the softness of biological tissues/objects both in routine clinical examinations and during surgeries
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