A Fully Printed Flexible Sensor Sheet for Simultaneous Proximity–Pressure–Temperature Detection

Luo, Huayu; Pang, Gaoyang; Xu, Kaichen; Ye, Zhiqiu; Yang, Huayong; Yang, Geng

doi:10.1002/admt.202100616

Cited by 26 publications

(24 citation statements)

References 35 publications

(55 reference statements)

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“…[22,61,183] For instance, multipixel and serpentine interconnection have been printed on PET and PI films as electrode layers for a capacitive trimodal flexible sensor illustrated in Figure 16C. [257] Such an interesting electrode and circuit design enable the fabrication of wearable and stretchable devices, while it increases the sensing unit size and volume to some extent if without careful control of the micro-/nano-structure printing accuracy. Therefore, only a small amount of delicately designed sensing circuits, such as flexible/stretchable electrodes and printed circuits, have been seen to improve the compactness and wearability of flexible sensing devices.…”

Section: Circuit Design Of Multiresponsive Flexible Sensorsmentioning

confidence: 99%

Section: Circuit Design Of Multiresponsive Flexible Sensorsmentioning

confidence: 99%

mentioning

confidence: 99%

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Recent Advances in Multiresponsive Flexible Sensors towards E‐skin: A Delicate Design for Versatile Sensing

Jia

et al. 2021

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101

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As we know, human skin is natural barrier for human being to protect the body from external substance invasion, and also biological multifunctional sensors perceiving pressure, temperature, proximity, pain, smell, friction, texture of objects, etc. [4,12,13] Admittedly, human skin also has its intrinsic drawbacks like inaccurate and indirect discernment of relative humidity which needs to be perceived by the cooperation of mechanoreceptor and thermoreceptor. [14,15] Thus, e-skin should be not only limited to imitating the structure and multifunctional sensing capabilities of human skin, but also be able to develop more excellent traits beyond the human skin. [14,16] Considering the exploitation and employment of numerous materials, versatile structures and the integration of various mechanisms and manufacturing methods, the real future e-skins would surpass human skin in most aspects and show new characteristics such as transduction of other stimuli like light, sound, and even magnetism. [17][18][19] The delicate design and integration of multifunctional flexible sensors may overcome the current shortcomings and offer new insight into the forthcoming era of omnipotent stretchable and bendable electronics.Basically, flexibility is a trait for contours with zero-Gaussian curvature, while stretchability is necessary for conformal and entire covering surfaces with non-zero Gaussian curvature when the flexible sensors are attached to irregular 3-dimensionally curvilinear human skin. [20] Thus, stretchable sensors are supposed to be flexible. In the beginning of flexible sensors, most of the elemental sensing parts were created by combining inherently inorganic and rigid active materials (e.g., Si and Au) with soft substrates via special shape designs which are partly flexible to some extent. [20][21][22][23] Nonetheless, it is far from perfect for practical use if attaching these electronic devices on arbitrarily curved human skin and robot surfaces. Actually, commercial wearables are supposed to gradually take the sense of human scale and aesthetic into consideration, i.e., they are expected to be mechanically conformal, user-comfortable, environment-friendly, biocompatible, transparent, etc. [24,25] Consequently, all-flexible/stretchable sensors mainly consisting of organic active materials and/or metal nanowires are springing up. [26] Among various signals existing in nature, forces, temperature, and humidity play essential and vital roles in our normal Multiresponsive flexile sensors with strain, temperature, humidity, and other sensing abilities serving as real electronic skin (e-skin) have manifested great application potential in flexible electronics, artificial intelligence (AI), and Internet of Things (IoT). Although numerous flexible sensors with sole sensing function have already been reported since the concept of e-skin, that mimics the sensing features of human skin, was proposed about a decade ago, the ones with more sensing capacities as new emergences are urgently demanded. However, highly integrated a...

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Section: Circuit Design Of Multiresponsive Flexible Sensorsmentioning

confidence: 99%

Section: Circuit Design Of Multiresponsive Flexible Sensorsmentioning

confidence: 99%

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Recent Advances in Multiresponsive Flexible Sensors towards E‐skin: A Delicate Design for Versatile Sensing

Jia

et al. 2021

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101

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“…To bridge the gap between single‐unit sensing and large‐area sensing, significant efforts have been devoted to developing array‐type bionic sensors, with sensing mechanisms ranging from capacitance, [ 12,13 ] and piezoresistance, [ 14 ] to optics, [ 15 ] and magnetism. [ 16 ] Their lattice arrangements of small‐sized sensing elements on a deformable substrate are proposed to acquire large‐area scalability and distributed sensing capability without losing mechanical compliance.…”

Section: Introductionmentioning

confidence: 99%

“…[9,10] However, deploying bionic skins onto a large-area surface of the robot is challenging due to the calibrations of numerous sensor units and the lack of algorithm-sensor co-design for intelligent tactile sensing. [11] To bridge the gap between single-unit sensing and large-area sensing, significant efforts have been devoted to developing array-type bionic sensors, with sensing mechanisms ranging from capacitance, [12,13] and piezoresistance, [14] to optics, [15] and magnetism. [16] Their lattice arrangements of small-sized sensing Robots equipped with bionic skins for enhancing the robot perception capability are increasingly deployed in wide applications ranging from healthcare to industry.…”

Section: Introductionmentioning

confidence: 99%

Bioinspired Co‐Design of Tactile Sensor and Deep Learning Algorithm for Human–Robot Interaction

Kong

Yang

Pang

et al. 2022

Advanced Intelligent Systems

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Robots equipped with bionic skins for enhancing the robot perception capability are increasingly deployed in wide applications ranging from healthcare to industry. Artificial intelligence algorithms that can provide bionic skins with efficient signal processing functions further accelerate the development of this trend. Inspired by the somatosensory processing hierarchy of humans, the bioinspired co‐design of a tactile sensor and a deep learning‐based algorithm is proposed herein, simplifying the sensor structure while providing computation‐enhanced tactile sensing performance. The soft piezoresistive sensor, based on the carbon black‐coated polyurethane sponge, offers a continuous sensing area. By utilizing a customized deep neural network (DNN), it can detect external tactile stimulus spatially continuously. Besides, a novel data augmentation method is developed based on the sensor's hexagonal structure that has a sixfold rotation symmetry. It can significantly enhance the generalization ability of the DNN model by enriching the collected training data with generated pseudo‐data. The functionality of the sensor and the robustness of the proposed data augmentation strategy are verified by precisely recognizing five touch modalities, illustrating a well‐generalized performance, and providing a promising application prospect in human–robot interaction.

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Handwriting Character Recognition Based on Conductor/Insulator‐Identifiable E‐Tattoo Proximity Sensors for Blinds

Liu,

Tong,

Xian

et al. 2023

Adv Funct Materials

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Easy and convenient reading for blinds is of great significance for lowering their learning, entertainment, and communication barrier, and improving their living quality. The general solution is to learn braille, far from satisfying the meet of the blinds’ daily learning and communication. Here, a new‐type conductor/insulator‐identifiable e‐tattoo proximity sensor is developed by simply depositing the circular interdigitated electrodes on organic semiconductor. The discriminable recognition toward conductors and insulators is realized only based on a single e‐tattoo device. The sensors not only enable recognition of the protruding characters like braille based on distance difference, but also enable recognition of the handwriting ink‐brush and pencil graphite characters based on the unique advantage of the sensors in distinguishing conduct and insulator. These results open a new route to realize the material category recognition, provide a user‐friendly way to help the visual impaired effectively reintegrate into society, and broaden the application field of proximity sensors.

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A Fully Printed Flexible Sensor Sheet for Simultaneous Proximity–Pressure–Temperature Detection

Cited by 26 publications

References 35 publications

Recent Advances in Multiresponsive Flexible Sensors towards E‐skin: A Delicate Design for Versatile Sensing

Recent Advances in Multiresponsive Flexible Sensors towards E‐skin: A Delicate Design for Versatile Sensing

Bioinspired Co‐Design of Tactile Sensor and Deep Learning Algorithm for Human–Robot Interaction

Handwriting Character Recognition Based on Conductor/Insulator‐Identifiable E‐Tattoo Proximity Sensors for Blinds

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