Recent Advances in Large‐Scale Tactile Sensor Arrays Based on a Transistor Matrix

Huo, Zhi-Ying; Peng, Yiyao; Zhang, Yufei; Gao, Guoyun; Wan, Boshun; Wu, Wenqiang; Yang, Zheng; Wang, Xiandi; Pan, Caofeng

doi:10.1002/admi.201801061

Cited by 49 publications

(29 citation statements)

References 128 publications

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“…The sensor devices have different characteristics that are important for target applications, and can be fabricated using various principles. The forms include piezoelectric [26,27], capacitive [28][29][30], piezoresistive [31,32] and field-effect transistor types, depending on the parameters to be achieved [33][34][35][36]. Here, we present basic information about the tactile sensor array device, which is used extensively as a tool for recognizing gestures, so that readers can gain a better understanding of the fundamental mechanisms involved.…”

Section: Tactile Sensor Arraysmentioning

confidence: 99%

“…However, these devices can exhibit some disadvantages, such as a complicated process and low spatial resolution. Therefore, we introduced a transistor array in which the components that make up the transistor are affected by pressure [35]. Unlike the devices introduced above, these devices have gate dielectric materials or channel materials that are sensitive to pressure, and the drain current is modulated by pressure without external pressure-sensitive components.…”

Section: Pressure-sensitive Transistor Arraysmentioning

confidence: 99%

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Motion Detection Using Tactile Sensors Based on Pressure-Sensitive Transistor Arrays

Jang

Jun

Seo

et al. 2020

Sensors

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In recent years, to develop more spontaneous and instant interfaces between a system and users, technology has evolved toward designing efficient and simple gesture recognition (GR) techniques. As a tool for acquiring human motion, a tactile sensor system, which converts the human touch signal into a single datum and executes a command by translating a bundle of data into a text language or triggering a preset sequence as a haptic motion, has been developed. The tactile sensor aims to collect comprehensive data on various motions, from the touch of a fingertip to large body movements. The sensor devices have different characteristics that are important for target applications. Furthermore, devices can be fabricated using various principles, and include piezoelectric, capacitive, piezoresistive, and field-effect transistor types, depending on the parameters to be achieved. Here, we introduce tactile sensors consisting of field-effect transistors (FETs). GR requires a process involving the acquisition of a large amount of data in an array rather than a single sensor, suggesting the importance of fabricating a tactile sensor as an array. In this case, an FET-type pressure sensor can exploit the advantages of active-matrix sensor arrays that allow high-array uniformity, high spatial contrast, and facile integration with electrical circuitry. We envision that tactile sensors based on FETs will be beneficial for GR as well as future applications, and these sensors will provide substantial opportunities for next-generation motion sensing systems.

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Section: Tactile Sensor Arraysmentioning

confidence: 99%

Section: Pressure-sensitive Transistor Arraysmentioning

confidence: 99%

Motion Detection Using Tactile Sensors Based on Pressure-Sensitive Transistor Arrays

Jang

Jun

Seo

et al. 2020

Sensors

View full text Add to dashboard Cite

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“…This issue is commonly addressed through the use of an active matrix architecture, a technique which can reduce the number of required connections as well as mitigate crosstalk between devices. [ 41 ] The sensing mechanism of each device instance varies widely, with some examples measuring a change in resistance, capacitance, or potential, while some utilize the OTFT itself and rely upon deformation‐induced change in device characteristics.…”

Section: Introductionmentioning

confidence: 99%

Organic Thin Film Transistors in Mechanical Sensors

Lamport

Cavallari

Kam

et al. 2020

Adv Funct Materials

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The marriage of organic thin‐film transistors (OTFTs) and flexible mechanical sensors has enabled previously restricted applications to become a reality. Counterintuitively, the addition of an OTFT at each sensing element can reduce the overall complexity so that large‐area, low‐noise sensors can be fabricated. The best‐performing instance of this is the active matrix, used in display applications for many of the same reasons, and nearly any type of flexible mechanical sensor can be incorporated into these structures. In this Progress Report, some of the flexible sensor devices that have taken advantage of these mechanical properties are highlighted, examining the advantages that OTFTs offer in the hybrid integration of local amplification and switching. In particular, the current research on resistive pressure sensors, capacitive pressure sensors, resistive or piezoresistive strain sensors, and piezoelectric sensors is identified and enumerated.

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“…Thin, soft skin‐integrated electronics have attracted great attentions due to their advantages such as flexible, lightweight, and mechanical compatible with human body, thus offer unique capabilities in detecting vital information and continuous monitoring human health . Recent advances in materials development, electronics miniaturization, mechanics optimization, and system‐level integration build up the foundations for flexible and stretchable electronics which are able to be integrated together with skin. Considering power supply for this new kind of soft electronics, conversion of mechanical energy from human body activities and motions to electricity is a considerable route .…”

Section: Introductionmentioning

confidence: 99%

Skin‐Integrated Graphene‐Embedded Lead Zirconate Titanate Rubber for Energy Harvesting and Mechanical Sensing

Liu

Zhao

Wang

et al. 2019

Adv Materials Technologies

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Thin, soft, skin‐like electronics capable of transforming body mechanical motions to electrical signals have broad potential applications in biosensing and energy harvesting. Forming piezoelectric materials into flexible and stretchable formats and integrating with soft substrate would be a considerable strategy for this aspect. Here, a skin‐integrated rubbery electronic device that associates with a simple low‐cost fabrication method for a ternary piezoelectric rubber composite of graphene, lead zirconate tinanate (PZT), and polydimethylsiloxane (PDMS) is introduced. Comparing to the binary composite that blend with PZT and PDMS, the graphene‐embedded ternary composite exhibits a significant enhancement of self‐powered behavior, with a maximum power density of 972.43 µW cm−3 under human walking. Combined experimental and theoretical studies of the graphene‐embedded PZT rubber allow the skin‐integrated electronic device to exhibit excellent mechanical tolerance to bending, stretching, and twisting for thousands of cycles. Customized device geometries guided by optimized mechanical design enable a more comprehensive integration of the rubbery electronics with the human body. For instance, annulus‐shape devices can perfectly mount on the joints and ensure great power output and stability under continuous and large deformations. This work demonstrates the potential of large‐area, skin‐integrated, self‐powered electronics for energy harvesting as well as human health related mechanical sensing.

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Recent Advances in Large‐Scale Tactile Sensor Arrays Based on a Transistor Matrix

Cited by 49 publications

References 128 publications

Motion Detection Using Tactile Sensors Based on Pressure-Sensitive Transistor Arrays

Motion Detection Using Tactile Sensors Based on Pressure-Sensitive Transistor Arrays

Organic Thin Film Transistors in Mechanical Sensors

Skin‐Integrated Graphene‐Embedded Lead Zirconate Titanate Rubber for Energy Harvesting and Mechanical Sensing

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