2008
DOI: 10.1002/anie.200703693
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Tactile Devices To Sense Touch on a Par with a Human Finger

Abstract: Our sense of touch enables us to recognize texture and shape and to grasp objects. The challenge in making an electronic skin which can emulate touch for applications such as a humanoid robot or minimally invasive and remote surgery is both in mimicking the (passive) mechanical properties of the dermis and the characteristics of the sensing mechanism, especially the intrinsic digital nature of neurons. Significant progress has been made towards developing an electronic skin by using a variety of materials and … Show more

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Cited by 184 publications
(121 citation statements)
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“…The skin is the largest organ in the human body. It is mechanically self-healing, but if such behavior can be developed in artificial skin, then it shall prove to be the future for robots used by humans in daily life for numerous applications [48][49][50]. Due to unprecedented stretching or bending, rupture of this electronic artificial skin can occur in robots.…”
Section: Potential Application Of Self Healing Phenomena Of Graphenementioning
confidence: 99%
“…The skin is the largest organ in the human body. It is mechanically self-healing, but if such behavior can be developed in artificial skin, then it shall prove to be the future for robots used by humans in daily life for numerous applications [48][49][50]. Due to unprecedented stretching or bending, rupture of this electronic artificial skin can occur in robots.…”
Section: Potential Application Of Self Healing Phenomena Of Graphenementioning
confidence: 99%
“…Piezoresistive sensors transduce mechanical strain into an impedance change and are widely used due to their simple read-out mechanism, sensitivity to both pressure and flexion 19 and potentially high pixel density 20 . Very recently, a resistive-type pressure sensor made of self-healing materials was demonstrated, showing that the self-healing capability of natural skin could be mimicked in artificial electronic skins 21 .…”
mentioning
confidence: 99%
“…[12][13][14] Many of resistive sensors use nanomaterial-embedded composites and exploit changes in contact resistance between the nanomaterials in the composite matrix (such as elastomer) under pressure loading, showing improved pressure sensitivity and mechanical flexibility compared to silicon-or metal-based piezoresistive sensors. [15] However, resistive tactile sensors suffer from signal drift due to temperature changes and require high power consumption. In addition, complicated circuit arrangement for multipoint recognition is regarded as a drawback to be addressed.…”
mentioning
confidence: 99%