Abstract
Tactile sensors have been incorporated into robots to help in many tasks, such as preventing damage to humans in collaborative works or assistance or in dexterous manipulation. Proximity sensors are also common in robotics and are proposed to implement pretouch in multimodal realizations. Many tactile sensors are based on off-the-shelf force-sensing resistors (FSRs). The parasitic capacitance associated with the electrodes of the FSR can be exploited to measure proximity. Moreover, it is possible to implement both force and proximity signal acquisition with a single chip. This article presents a multimodal proximity and tactile patch based on commercial FSR plus a programmable system on chip (PSoC). The ability to measure proximity is achieved without adding any extra element. Discussions about key design issues as well as results that show the performance of the sensor patch are presented. As proximity sensing array, the range is in the order of the size of the electrodes, and it depends on the properties of the object nearby, as expected. The best performance is observed for conductive objects. Therefore, this approach is especially interesting in human-robot interaction tasks, such as shaping robotic hands or grippers around the human body. Furthermore, dielectric objects are also detected, so it can also be used to implement pretouch in manipulation tasks.
Highlights
P ROXIMITY sensors are used to avoid collision in robotics
A set of measurements were taken to observe the response of the prototype when the aluminum prism was placed at different heights with respect to the sensor surface, and with the center of its biggest side aligned with the center of the sensor under test
It was observed that the elastomer modifies slightly the distance range, and the sensitivity and output range are smaller if the elastomer is used
Summary
P ROXIMITY sensors are used to avoid collision in robotics. Sensitive skins that integrate many proximity sensors have been proposed in human–robot cooperation or assistive robotics to prevent damage to humans or objects [1], [2]. Tactile sensors are aimed at achieving the same goal, but the need to establish contact to detect objects means a cautious and somewhat slow operation of the robot. A multimodal approach is proposed by many authors where proximity sensing is exploited to detect the objects before making contact. Manuscript received February 12, 2019; revised September 10, 2019; accepted September 16, 2019. Date of publication September 30, 2019; date of current version June 9, 2020. The Associate Editor coordinating the review process was Bruno Ando. (Corresponding author: Julián Castellanos-Ramos.)
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