Commercial tactile sensors for hand exoskeletons: practical considerations for ultra-low cost and very-low complexity read-out

In the last two decades, wearable robots have emerged as human-oriented devices to complement, substitute or enhance human capabilities and, more specifically, empower or replace a human limb [1], [2]. Among the most complex and interesting limbs to assist, the hand represents perhaps the biggest challenge, because of its primary role in environment exploration, stimuli sensing and object manipulation [3]. Hence, the development of wearable and rehabilitative exoskeletons is increasingly attracting attention to help finger movements in free motion and assist the user with grasping. This paper shows that a simple underpowered digital oscillator electronic interface takes advantage of the capacitive variations in commercial piezoresistive transducers to sense applied pressure. Furthermore, thanks to the analysis of the static performance, practical considerations are drawn about the use of commercial sensors and a read out circuit (ROC) to be exploited in a control system for hand exoskeletons (Fig. 1).

[1]  Bram Vanderborght,et al.  Instrumenting complex exoskeletons for improved human-robot interaction , 2015, IEEE Instrumentation & Measurement Magazine.

[2]  Pamela Abshire,et al.  High resolution capacitance sensor array for real-time monitoring of cell viability , 2014, 2014 IEEE International Symposium on Circuits and Systems (ISCAS).

[3]  Michela Borghetti,et al.  Sensorized Glove for Measuring Hand Finger Flexion for Rehabilitation Purposes , 2013, IEEE Transactions on Instrumentation and Measurement.

[4]  Fulvio Mastrogiovanni,et al.  On the Problem of the Automated Design of Large-Scale Robot Skin , 2013, IEEE Transactions on Automation Science and Engineering.

[5]  Marco Crepaldi,et al.  Wireless Multi-channel Quasi-digital Tactile Sensing Glove-Based System , 2013, 2013 Euromicro Conference on Digital System Design.

[6]  D. Demarchi,et al.  A Flexible Low-Power 130 nm CMOS Read-Out Circuit With Tunable Sensitivity for Commercial Robotic Resistive Pressure Sensors , 2015, IEEE Sensors Journal.

[7]  Marco Crepaldi,et al.  A microbial fuel cell powering an all-digital piezoresistive wireless sensor system , 2014 .

[8]  Luca De Vito,et al.  Measurements and sensors for motion tracking in motor rehabilitation , 2014, IEEE Instrumentation & Measurement Magazine.

[9]  Halit Eren,et al.  Measurement, Instrumentation, and Sensors Handbook : Spatial, Mechanical, Thermal, and Radiation Measurement , 2014 .

[10]  Bernard Bayle,et al.  Modeling and Evaluation of Low-Cost Force Sensors , 2011, IEEE Transactions on Robotics.

[11]  P. Dario,et al.  Experimental Evaluation of Two Commercial Force Sensors for Applications in Biomechanics and Motor Control , 2001 .

[12]  Jose L Pons,et al.  Wearable Robots: Biomechatronic Exoskeletons , 2008 .

[13]  Ana-Maria Cretu,et al.  Touch sensing for humanoid robots , 2015, IEEE Instrumentation & Measurement Magazine.

[14]  Marco Crepaldi,et al.  A 130 nm Event-Driven Voltage and Temperature Insensitive Capacitive ROC , 2014, 2014 17th Euromicro Conference on Digital System Design.

[15]  William S. Levine The Control Handbook, Second Edition: Control System Fundamentals, Second Edition , 2010 .

[16]  C. Scheffer,et al.  Tactile Sensing Using Force Sensing Resistors and a Super-Resolution Algorithm , 2009, IEEE Sensors Journal.

[17]  Soo-Jin Lee,et al.  Current hand exoskeleton technologies for rehabilitation and assistive engineering , 2012 .

[18]  Giulio Sandini,et al.  Tactile Sensing—From Humans to Humanoids , 2010, IEEE Transactions on Robotics.