Recent Progress in Flexible Tactile Sensors for Human‐Interactive Systems: From Sensors to Advanced Applications

Pyo, Soonjae; Lee, Jae Yong; Bae, Kyubin; Sim, Sangjun; Kim, Jongbaeg

doi:10.1002/adma.202005902

Cited by 326 publications

(185 citation statements)

References 183 publications

(308 reference statements)

Supporting

Mentioning

184

Contrasting

Unclassified

Order By: Relevance

“…human-machine interaction, architectural intelligence, information communication, etc. [1][2][3][4][5][6] Existing flexible tactile sensors can be mainly classified as piezoresistive, capacitive, triboelectric, and piezoelectric according to the working mechanism. [7][8][9][10][11] Among these types, capacitive sensors using a dielectric layer sandwiched between two flexible electrodes possess the comprehensive advantages of simple structure, facile fabrication, low-energy consumption, static/dynamic detection, and precise modification of the device design by analysis of the simple governing equation, etc., and therefore are attractive.…”

Section: Doi: 101002/smll202103312mentioning

confidence: 99%

Gradient Architecture‐Enabled Capacitive Tactile Sensor with High Sensitivity and Ultrabroad Linearity Range

Zhou

Lei

et al. 2021

Small

114

View full text Add to dashboard Cite

The sensitivity and linearity are critical parameters that can preserve the high pressure‐resolution across a wide range and simplify the signal processing process of flexible tactile sensors. Although extensive micro‐structured dielectrics have been explored to improve the sensitivity of capacitive sensors, the attenuation of sensitivity with increasing pressure is yet to be fully resolved. Herein, a novel dielectric layer based on the gradient micro‐dome architecture (GDA) is presented to simultaneously realize the high sensitivity and ultrabroad linearity range of capacitive sensors. The gradient micro‐dome pixels with rationally collocated amount and height can effectively regulate the contact area and hence enable the linear variation in effective dielectric constant of the GDA dielectric layer under varying pressures. With systematical optimization, the sensor exhibits the high sensitivity of 0.065 kPa−1 in an ultrabroad linearity range up to 1700 kPa, which is first reported. Based on the excellent sensitivity and linearity, the high pressure‐resolution can be preserved across the full scale of pressure spectrum. Therefore, potential applications such as all‐round physiological signal detection in diverse scenarios, control instruction transmission with combinatorial force inputs, and convenient Morse code communication with non‐overlapping capacitance signals are successfully demonstrated through a single sensor device.

show abstract

Section: Doi: 101002/smll202103312mentioning

confidence: 99%

Gradient Architecture‐Enabled Capacitive Tactile Sensor with High Sensitivity and Ultrabroad Linearity Range

Zhou

Lei

et al. 2021

Small

114

View full text Add to dashboard Cite

show abstract

“…Human skin is considered the most e cient and powerful tactile sensor 1,2 , and hence many studies have been conducted to develop exible electronic skin that emulate the properties of human skin and provide various tactile information, such as force feedback and texture classi cation, which would allow a robot to perform precise and delicate motions [3][4][5][6][7][8][9] . Advances in skin-mimicking tactile sensing technology could provide diverse human-machine interfaces in virtual/augmented reality and the metaverse 10,11 .…”

Section: Introductionmentioning

confidence: 99%

A cutaneous receptors-mimicking system for real-time and multimodal detection of tactile stimuli

Lee¹,

Kim²,

Oh³

et al. 2022

Preprint

View full text Add to dashboard Cite

A human can intuitively perceive and comprehend complicated tactile information, when interacting with objects, owing to the different cutaneous receptors distributed in the fingertip skin. Many research groups have attempted to mimic the structure and receptors of the skin to develop next-generation tactile sensors that can precisely and seamlessly deliver the overall tactile sensation. In this study, we propose a real-time multimodal tactile system that mimics the sensing qualities of cutaneous receptors entirely by simultaneously acquiring four types of decoupled tactile information in real time using multiple sensors integrated into three dimensions (3D), a signal-processing module, and a transmission module. The interconnections between 3D-integrated sensors and the signal-processing module were manufactured by 3D printing methods to have an adaptable shape. Furthermore, the proposed system can differentiate between various tactile stimuli, texture characteristics, and consecutive complex motions depending on the decoupled tactile sensing signals of pressure, shear force, vibration, and temperature. We believe that the results of this study can provide a novel design for a skin-like, perceivable, tactile sensing system for application in soft robotics, human-machine interfaces, health monitoring systems, and biomedical devices.

show abstract

“…The wearable intelligent system has attracted increasing research interest due to its capabilities of facile interaction with and continuous monitoring of the human body. It has shown great potential in various fields such as personalized health care, electronic skins, human–machine interfaces, humanoid robots, and so forth. − As a necessary perception component, flexible pressure sensors with simple manufacturing steps, efficient integration, and high sensing performances are required in the wearable intelligent system. − Piezoresistive sensors show great advantages over other types of pressure sensors, including a simple working mechanism, easy processing, and relatively low power consumption. − Until now, extensive efforts have been devoted to improving the sensing performances, ranging from designing microstructures to choosing advanced functional and substrate materials. − For flexible piezoresistive pressure sensors, reversible deformation of the contact area or sites arises under pressure, which in turn induces electrical resistance changes. − Although piezoresistive pressure sensors based on film materials and template transfer methods have made significant progress, their unsatisfying breathability and comfortability for prolonged wearing prohibit their extensive application. The inherent characteristics of textile materials, such as comfort, outstanding breathability, cost-effectiveness, brilliant three-dimensional (3D) conformability, and hierarchical microstructures, , make them an attractive candidate for constructing flexible piezoresistive pressure sensors.…”

Section: Introductionmentioning

confidence: 99%

Full-Textile Human Motion Detection Systems Integrated by Facile Weaving with Hierarchical Core–Shell Piezoresistive Yarns

Zhong

Ming

Jiang

et al. 2021

ACS Appl. Mater. Interfaces

View full text Add to dashboard Cite

The tremendous progress of the wearable intelligent system has brought an urgent demand for flexible pressure sensors, especially for those possessing high sensing performances, simple manufacture technology, and efficient integration. In this work, hierarchical core−shell piezoresistive yarns (HCPYs), which contain internal silver-plated nylon electrodes and surface microporous structured carbon nanotubes (CNTs)/thermoplastic polyurethane (TPU) sensing layer, are designed and manufactured via facile wet-spinning accompanied by a water vapor coagulating bath. The obtained HCPY can either be inserted into traditional textiles to assemble a single-pressure sensor, or be woven into a textile-based flexible pressure sensors array with expected size and resolution, without compromising their comfort, breathability, and three-dimensional (3D) conformability. Simultaneously, to further enhance the sensing performance, the surface microporous structures of HCPYs are optimized by altering the treatment humidity and exposure time during the process of water vapor-induced phase separation. The wearable pressure sensors assembled by the optimal HCPY achieved a high sensitivity up to 84.5 N −1 , a good durability over 5000-cycle tests, a fast response time of 2.1 ms, and a recovery time of 2.4 ms. Moreover, the wearable pressure sensors have been successfully used to monitor physical signals and human motions. The textile-based flexible pressure sensors array has also been seamlessly integrated with sportswear to detect movements of the elbow joint and map spatial pressure distribution, which makes HCPY a promising candidate for constructing next-generation wearable electronics.

show abstract

Recent Progress in Flexible Tactile Sensors for Human‐Interactive Systems: From Sensors to Advanced Applications

Cited by 326 publications

References 183 publications

Gradient Architecture‐Enabled Capacitive Tactile Sensor with High Sensitivity and Ultrabroad Linearity Range

Gradient Architecture‐Enabled Capacitive Tactile Sensor with High Sensitivity and Ultrabroad Linearity Range

A cutaneous receptors-mimicking system for real-time and multimodal detection of tactile stimuli

Full-Textile Human Motion Detection Systems Integrated by Facile Weaving with Hierarchical Core–Shell Piezoresistive Yarns

Contact Info

Product

Resources

About