Normal and Shear Force Measurement Using a Flexible Polymer Tactile Sensor With Embedded Multiple Capacitors

Lee, Hyung-Kew; Chung, Jaehoon; Chang, Sun-Il; Yoon, Euisik

doi:10.1109/jmems.2008.921727

Cited by 295 publications

(69 citation statements)

References 11 publications

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“…Some researchers have studied three dimension sensor arrays that can detect shear forces [8]. Other sensors of different types have been reported so far: piezo-resistor [9,10], capacitive [11,12], optical [13][14][15] and piezoelectric [16][17][18][19] ones. Furthermore unique ideas for the sensors have been reported such as conducting fluid [20], organic transistors [21,22], electron tunneling [23,24], ultrasonic [25,26], magneto-resistive [27,28] and field emission [29] applications.…”

Section: Introductionmentioning

confidence: 99%

Electrode for Force Sensor of Conductive Rubber

Ohmukai¹,

Kami²,

Matsuura³

2012

JST

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Tactile sensors are believed to be a key element in order to realize robotic fingers to catch a fragile object without damage. Force sensitive conductive rubber is a low-cost material and then attractive for the application to tactile sensors. We have studied the effect of electrodes attached to the rubber sheets. We have tried four kinds of electrodes: vacuum deposited Al, adhesive Cu tape, Al thin film sheet and silver paste. It can be concluded that vacuum deposited Al has the highest potential from the practical point of view; it has the widest dynamic range and good precision at the same time

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Section: Introductionmentioning

confidence: 99%

Electrode for Force Sensor of Conductive Rubber

Ohmukai¹,

Kami²,

Matsuura³

2012

JST

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“…The sensor performance of the proposed sensor chip with surface trenches has been compared with flat sensor chip reported in [22]. Results presented in Figure 27 suggest that the signal output has been improved by introducing surface trenches on the sensor chip.…”

Section: Microfabrication Process Flowmentioning

confidence: 97%

“…Comparison of signal output from the proposed sensor and the sensor in [22] for measuring out-of-plane normal stress

σ_{33}

( a ) and shear stresses

σ_{23}

( b ) and

σ_{13}

( c ).…”

Section: Figurementioning

confidence: 99%

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Modelling and Design of MEMS Piezoresistive Out-of-Plane Shear and Normal Stress Sensors

Zhang

2018

Sensors

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In this paper, the design of MEMS piezoresistive out-of-plane shear and normal stress sensor is described. To improve the sensor sensitivity, a methodology by the incorporation of stress concentration regions, namely surface trenches in the proximity of sensing elements was explored in detail. The finite element (FE) model, verified by a five-layer analytical model was developed as a tool to model the performance of the sensor and guide the geometric optimization of the surface trenches. Optimum location and dimensions of the surface trenches have been obtained through a comprehensive FE analysis. The microfabrication and packing scheme was introduced to prototype the sensor with optimum geometric characteristics of surface trenches. Signal output from the prototyped sensor was tested and compared with those from FE simulation. Good agreement has been achieved between the simulation and experimental results. Moreover, the results suggest the incorporation of surface trenches can help improve the sensor sensitivity. More specifically, the sum of signal output from the sensor chip with surface trenches are 4.52, 5.06 and 5.72 times higher compared to flat sensor chip for center sensing area, edge sensing areas 1 and 2, respectively.

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“…An ideal sensor should meet the following significant criteria: i) operation at room temperature in an ambient environment; ii) fast response and recovery times without an external stimulus (e.g. UV lamp); iii) high sensitivity with a low detection limit; iv) high reproducibility with repeatable responses; v) cost effective and easy‐to‐fabricate; vi) low‐voltage (<5 V) power design; and vii) biocompatible and eco‐friendly …”

Section: Nanomaterial‐based Flexible Sensors For Volatolomic Applicatmentioning

confidence: 99%

Nanoscale Sensor Technologies for Disease Detection via Volatolomics

Vishinkin

Haick

2015

Small

172

209

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The detection of many diseases is missed because of delayed diagnoses or the low efficacy of some treatments. This emphasizes the urgent need for inexpensive and minimally invasive technologies that would allow efficient early detection, stratifying the population for personalized therapy, and improving the efficacy of rapid bed-side assessment of treatment. An emerging approach that has a high potential to fulfill these needs is based on so-called "volatolomics", namely, chemical processes involving profiles of highly volatile organic compounds (VOCs) emitted from body fluids, including breath, skin, urine and blood. This article presents a didactic review of some of the main advances related to the use of nanomaterial-based solid-state and flexible sensors, and related artificially intelligent sensing arrays for the detection and monitoring of disease with volatolomics. The article attempts to review the technological gaps and confounding factors related to VOC testing. Different ways to choose nanomaterial-based sensors are discussed, while considering the profiles of targeted volatile markers and possible limitations of applying the sensing approach. Perspectives for taking volatolomics to a new level in the field of diagnostics are highlighted.

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Normal and Shear Force Measurement Using a Flexible Polymer Tactile Sensor With Embedded Multiple Capacitors

Cited by 295 publications

References 11 publications

Electrode for Force Sensor of Conductive Rubber

Electrode for Force Sensor of Conductive Rubber

Modelling and Design of MEMS Piezoresistive Out-of-Plane Shear and Normal Stress Sensors

Nanoscale Sensor Technologies for Disease Detection via Volatolomics

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