Static Tactile Sensing for a Robotic Electronic Skin via an Electromechanical Impedance-Based Approach

Liu, Cheng; Zhuang, Yitao; Nasrollahi, Amir; Lu, Lingling; Haider, Mohammad Faisal; Chang, Fu‐Kuo

doi:10.3390/s20102830

Cited by 14 publications

(12 citation statements)

References 22 publications

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“…Since this type of sensor is not affected by leakage current, it can be effectively used for both dynamic and static measurements without the signal drift. Static force can be measured by using the change in the resonance frequency of the piezoelectric sensor [25][26][27][31][32][33]. The resonance frequency is determined by the effective stiffness (or spring constant) and mass of the sensor structure.…”

Section: Static Force Measurement Using Piezoelectric Sensorsmentioning

confidence: 99%

“…Liu et al have developed a static force sensing technique using an electromechanical impedance measurement with the piezoelectric resonator for smart skin applications [33]. A prototyped sensor was made of a PZT plate with a resonance frequency of 900 kHz and embedded in the skin-like soft silicon rubber material as shown in Figure 2(c).…”

Section: Static Force Measurement Using Piezoelectric Sensorsmentioning

confidence: 99%

“…Numerous designs of piezoelectric sensors have been suggested for static force sensing using various measurement parameters including the resonance frequency, decay time constant, and capacitance [25][26][27][28][29][30]. Recent studies also demonstrated that the electrical impedance or admittance amplitude at resonance (or antiresonance) varies by applied force-induced acoustic load variation with feasible sensitivity and linearity which can be effectively used for static force sensing [31][32][33]. Despite increasing attention for taking full advantage of piezoelectricity in static force sensing, a collective resource that provides a comprehensive review of each measurement mechanism is hardly available to date.…”

Section: Introductionmentioning

confidence: 99%

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Static Force Measurement Using Piezoelectric Sensors

Kim

Jiang

et al. 2021

Journal of Sensors

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In force measurement applications, a piezoelectric force sensor is one of the most popular sensors due to its advantages of low cost, linear response, and high sensitivity. Piezoelectric sensors effectively convert dynamic forces to electrical signals by the direct piezoelectric effect, but their use has been limited in measuring static forces due to the easily neutralized surface charge. To overcome this shortcoming, several static (either pure static or quasistatic) force sensing techniques using piezoelectric materials have been developed utilizing several unique parameters rather than just the surface charge produced by an applied force. The parameters for static force measurement include the resonance frequency, electrical impedance, decay time constant, and capacitance. In this review, we discuss the detailed mechanism of these piezoelectric-type, static force sensing methods that use more than the direct piezoelectric effect. We also highlight the challenges and potentials of each method for static force sensing applications.

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Section: Static Force Measurement Using Piezoelectric Sensorsmentioning

confidence: 99%

Section: Static Force Measurement Using Piezoelectric Sensorsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Static Force Measurement Using Piezoelectric Sensors

Kim

Jiang

et al. 2021

Journal of Sensors

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“…The latter are more frequently used to measure contact force intensity or magnitude. Both sensor principles may be supported by different transduction technologies, e.g., resistive [ 1 , 2 , 3 ], capacitive [ 4 , 5 ] and magnetic [ 6 , 7 , 8 ], which can be selected depending on the costs, weight, integration level, dimensions and specific task to perform. The number of papers on this subject is very large and here are reported only some among the most recent.…”

Section: Introductionmentioning

confidence: 99%

“…The bubbles, in contact with the object surface, allow for the detection of the object texture through sliding and slipping operations during manipulation tasks. Differently from the previous solution, Klimaszewski et al [ 2 ] and Liu et al [ 3 ] developed a distributed tactile sensor, i.e., a robotic skin, for contact pressure detection that uses a matrix of resistive or piezoelectric sensing elements integrated into a flexible and soft material. Suen et al [ 4 ] presented a new concept of capacitive tactile sensor to detect three axial force via five independent concentric-shape sensing electrodes, aimed to decouple the normal and shear forces and to measure torsion around the sensor axes.…”

Section: Introductionmentioning

confidence: 99%

Tactile Sensors for Parallel Grippers: Design and Characterization

Cirillo

Costanzo

Laudante

et al. 2021

Sensors

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Tactile data perception is of paramount importance in today’s robotics applications. This paper describes the latest design of the tactile sensor developed in our laboratory. Both the hardware and firmware concepts are reported in detail in order to allow the research community the sensor reproduction, also according to their needs. The sensor is based on optoelectronic technology and the pad shape can be adapted to various robotics applications. A flat surface, as the one proposed in this paper, can be well exploited if the object sizes are smaller than the pad and/or the shape recognition is needed, while a domed pad can be used to manipulate bigger objects. Compared to the previous version, the novel tactile sensor has a larger sensing area and a more robust electronic, mechanical and software design that yields less noise and higher flexibility. The proposed design exploits standard PCB manufacturing processes and advanced but now commercial 3D printing processes for the realization of all components. A GitHub repository has been prepared with all files needed to allow the reproduction of the sensor for the interested reader. The whole sensor has been tested with a maximum load equal to 15N, by showing a sensitivity equal to 0.018V/N. Moreover, a complete and detailed characterization for the single taxel and the whole pad is reported to show the potentialities of the sensor also in terms of response time, repeatability, hysteresis and signal to noise ratio.

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A tactile sensor based on piezoresistive effect and electromagnetic induction

Han

Liu

et al. 2022

Sensors and Actuators A: Physical

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Static Tactile Sensing for a Robotic Electronic Skin via an Electromechanical Impedance-Based Approach

Cited by 14 publications

References 22 publications

Static Force Measurement Using Piezoelectric Sensors

Static Force Measurement Using Piezoelectric Sensors

Tactile Sensors for Parallel Grippers: Design and Characterization

A tactile sensor based on piezoresistive effect and electromagnetic induction

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