Bimodal Tactile Sensor without Signal Fusion for User-Interactive Applications

Ma, Xiaole; Wang, Chunfeng; Wei, Ruilai; He, Jiaqi; Li, Jing; Liu, Xianhu; Huang, Fengchang; Ge, Shuping; Tao, Juan; Yuan, Zuqing; Chen, Ping; Peng, Dengfeng; Pan, Caofeng

doi:10.1021/acsnano.1c09779

Cited by 61 publications

(51 citation statements)

References 56 publications

(67 reference statements)

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“…[5][6][7][8] Recently, with rapid advances in wearable electronics, the Internet of Things, and human-machine interaction, the critical performance of wearable devices has been remarkably improved in terms of the sensing range, sensitivity, and multiparametric and interference-free detection. [9][10][11][12] Nevertheless, most reported works have only focused on optimizing electronic readouts of wearable devices, which require bulky equipment or wired connections to convert them into humanidentifiable forms of data and waveforms. The inability to respond instantly to direct stimuli restricts their application in specific scenarios, such as miniaturized, portable, and real-time detection, and results in difficulties processing and transmitting in harsh external environments.…”

Section: Introductionmentioning

confidence: 99%

Wearable Hybrid Device Capable of Interactive Perception with Pressure Sensing and Visualization

Guo

et al. 2022

Adv Funct Materials

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A wearable interactive device that can synchronously detect and visualize pressure, stimuli will supplement easily identifiable in situ signals with conventional sensing that outputs only electronic signals. Currently, most interactive devices are composed of physically connected separate pressure sensors and display elements, which do not conform to the development of miniaturization and high integration. The realization of combining these two functions in one device with a simplified configuration is still only beginning to be explored. Inspired by the two-in-one response of the octopus, which can both sense and visualize stimuli, an integrated hybrid device based on ionic sensing and electrochromic display is proposed for interactive pressure perception. By efficiently reusing the electrodes and ionic gel, the device enables quantitative sensing and direct color changing in response to pressure. Benefiting from its excellent comprehensive performance, the applications are explored and verified, including the interactive perception of pressure information, hiding and display of visual information under pressure regulation, and repeated writing and erasing on flexible boards. Notably, multiple customized systems with improved design flexibility are implemented to provide remote monitoring and visual warning of behavioral states and physiological parameters. This study diversifies solutions to realize a direct link between pressure detection and visualization.

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Section: Introductionmentioning

confidence: 99%

Wearable Hybrid Device Capable of Interactive Perception with Pressure Sensing and Visualization

Guo

et al. 2022

Adv Funct Materials

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“…Natural skin sensory systems equipped with thermoreceptors and mechanoreceptors can detect and differentiate complex stimuli from the surrounding environment, such as strain, vibration, pressure, and temperature. [ 1–4 ] Artificial electronic skins (e‐skins) that can mimic human skin sensory functions have attracted tremendous attention for their revolutionary applications in the emerging fields of biomimetic prosthetics, [ 5,6 ] humanoid robotics, [ 7,8 ] human–machine interface, and artificial intelligence. [ 9 — 12 ] E‐skins are designed to translate external mechanical and thermal stimuli into detectable resistance, capacitance, or voltage signals.…”

Section: Introductionmentioning

confidence: 99%

Bioinspired Chromotropic Ionic Skin with In‐Plane Strain/Temperature/Pressure Multimodal Sensing and Ultrahigh Stimuli Discriminability

Zhang

Chen

Lee

et al. 2022

Adv Funct Materials

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Electronic skins (e-skins) mimic multimodal sensing capabilities of various tactile receptors in natural skin. Herein, a stretchable chromotropic ionic skin is rationally designed to simultaneously detect and decouple multiple stimuli, including in-plane strain, temperature, and pressure. The mutually discriminating trimodal ionic skin consists of mechanochromic, thermoresistive and triboelectric layers that individually function as strain, temperature and pressure sensors, respectively. These three distinct capabilities are integrated into the ionic skin which demonstrates highly sensitive responses to selective external stimuli while upholding high insensitivity to unwanted ones. The structural colors derived from mechanochromic photonic crystals of magnetic ferroferric oxide-carbon nanoparticles respond to strains by color-switching in the full visible spectrum, exhibiting appealing potential in interactive stress visualization. The temperature detection with an exceptional sensitivity of 20.44% per °C is enabled by the thermoresistive effect of ionic hydrogel, while oriented polymer chains embedded in the hydrogel decouple temperature from extraneous stimuli. The multilayer structure consisting of an ionic hydrogel film, a wrinkle-patterned polydimethylsiloxane (PDMS) film with gradient modulus design and a carbon nanotubes/PDMS electrode displays an extraordinary triboelectric effect with a strain-and temperature-insensitive pressure sensing capability. The chromotropic ionic skin facilitates simultaneously accurate measurements, high discriminability and quantitative mapping of complex stimuli, offering new insights into emerging E-skins.

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“…10 If multiple stimuli are identified using different perceptual mechanisms based on the same sensitive material, it is possible to differentiate stimuli directly by different signals. 11,12 Therefore, the design of multifunctional flexible sensors with multimodal outputs is an effective way to achieve accurate differentiation and sense different stimuli.…”

Section: ■ Introductionmentioning

confidence: 99%

“…Even though someone has analyzed multiple stimuli by distinguishing the change in amplitude and response speed brought about by different stimuli, the complex decoupling principle is subsequently needed to assist . If multiple stimuli are identified using different perceptual mechanisms based on the same sensitive material, it is possible to differentiate stimuli directly by different signals. , Therefore, the design of multifunctional flexible sensors with multimodal outputs is an effective way to achieve accurate differentiation and sense different stimuli.…”

Section: Introductionmentioning

confidence: 99%

Multifunctional Flexible Ionic Skin with Dual-Modal Output Based on Fibrous Structure

Zhao

Jia

Wang

et al. 2022

ACS Appl. Mater. Interfaces

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Flexible wearable electronic devices with multiple sensing functions that simulate human skin in all aspects have become a popular research topic. However, the current expensive and time-consuming means of integration and the complex decoupling process are hampering the further development of multifunctional sensors. Here, an ultraflexible ionic fiber membrane (IFM) prepared by a simple electrospinning technique is reported, which exhibits pressure and humidity sensing properties. With the help of different electrode structures, the IFM-based multifunctional sensor achieved pressure and humidity detection with different sensing mechanisms. Pressure sensing with high sensitivity (49.7 kPa–1 at 0–30 kPa) and wide detection range (0–220 kPa) was indicated by the capacitive signal. Humidity sensing with high linearity (1.086% per percent relative humidity (RH)) in the range 15%–90% RH was indicated by the resistance signal. In particular, the multimodal output of capacitance/resistance corresponding to pressure/humidity in this study directly addresses the problem of accurately distinguishing the two stimuli. Furthermore, we have demonstrated that the impact between pressure and humidity is negligible when measured simultaneously and independently. Because of the excellent pressure/humidity sensing performance, we have fabricated a smart bracelet and mask for pulse, skin moisture, and breathe monitoring, which indicates the promising future of multifunctional flexible sensors based on IFM in the healthcare field.

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Bimodal Tactile Sensor without Signal Fusion for User-Interactive Applications

Cited by 61 publications

References 56 publications

Wearable Hybrid Device Capable of Interactive Perception with Pressure Sensing and Visualization

Wearable Hybrid Device Capable of Interactive Perception with Pressure Sensing and Visualization

Bioinspired Chromotropic Ionic Skin with In‐Plane Strain/Temperature/Pressure Multimodal Sensing and Ultrahigh Stimuli Discriminability

Multifunctional Flexible Ionic Skin with Dual-Modal Output Based on Fibrous Structure

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