Sensorized Skin With Biomimetic Tactility Features Based on Artificial Cross‐Talk of Bimodal Resistive Sensory Inputs

Georgopoulou, Antonia; Hardman, David; Thuruthel, Thomas George; Iida, Fumiya; Clemens, Frank

doi:10.1002/advs.202301590

Advanced Science

2023

DOI: 10.1002/advs.202301590

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Sensorized Skin With Biomimetic Tactility Features Based on Artificial Cross‐Talk of Bimodal Resistive Sensory Inputs

Antonia Georgopoulou,

David Hardman,

Thomas George Thuruthel

et al.

Abstract: Tactility in biological organisms is a faculty that relies on a variety of specialized receptors. The bimodal sensorized skin, featured in this study, combines soft resistive composites that attribute the skin with mechano‐ and thermoreceptive capabilities. Mimicking the position of the different natural receptors in different depths of the skin layers, a multi‐layer arrangement of the soft resistive composites is achieved. However, the magnitude of the signal response and the localization ability of the stimu… Show more

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Cited by 10 publications

References 69 publications

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High‐Resolution Carbon‐Based Tactile Sensor Array for Dynamic Pulse Imaging

Tian,

Cheng,

et al. 2024

Adv Funct Materials

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With the development of modern medicine, the importance of continuous and reliable pulse wave monitoring has increased significantly in physiological evaluation and disease diagnosis. Among them, the 3D reconstruction of the pulse wave is indispensable, and needs rely on ultra‐high resolution sensor arrays, that is, high spatial resolution, temporal resolution, and force resolution. Herein, a flexible high‐density 32 × 32 tactile sensor array based on pressure‐sensitive tunneling mechanism is develpoed. Conformal graphene nanowalls (GNWs) pattern arrays are deposited on micro‐pyramidal structural Si substrate via mask‐assisted plasma enhanced chemical vapor deposition (PECVD) method and are adopted as pressure‐sensitive electrode, exhibiting a spatial resolution of 64 dots/cm2, high sensitivity (222.36 kPa−1) and short response time (2 ms). More importantly, HfO2 tunneling layer can effectively suppress noise current, which made it sense weak pressure signals with 1/1000 force resolution and SNR of 36.32 dB. By leveraging its high‐resolution array, more holistic pulse signals are acquired and the 3D shape of the pulse wave are successfully replicated. This work shows high‐resolution sensors have significant promise for applications in remote intelligent diagnostics.

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High‐Resolution Carbon‐Based Tactile Sensor Array for Dynamic Pulse Imaging

Tian,

Cheng,

et al. 2024

Adv Funct Materials

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A Real‐Time Imaging Sensing System to Visualize Elastomer Surface Profile Evolution for Dynamic Tactile Recognition

Zou,

Li,

Zhou

et al. 2024

Adv Funct Materials

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Elastomer‐based interfaces provide rich functionalities for tactile sensing, particularly in making tiny differences in contact dynamics potentially detectable. However, the minimal motion‐induced changes in the elastomer's surface and their disappearance during time‐lapse limit the state recognition within the current scheme of motion recognition. In this work, a new scheme of real‐time motion mode recognition for subtle deformations is proposed, which uses an optical tactile sensing system to visualize and distinguish tiny variations in surface profile evolution encoded as images. Illustrating with a sphere, sliding‐induced asymmetric elastomer surface deformation is visualized as a “drag” in optical images. The convolutional neural network (CNN) algorithm is used to analyze the evolution of surface contour features during the interaction between the sphere and the elastic medium. Motion state recognition is achieved with 80% accuracy when a displacement of only 8.3% of the sphere diameter is produced. In addition, the system also offers the potential to analyze dynamic motion information through a single image, with an accuracy of 82.7% for velocity recognition. This dynamic real‐time recognition framework for soft media deformation paves the way for novel motion‐based input commands for tactile sensing and human‐computer interaction applications.

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Fully Additively 3D Manufactured Conductive Deformable Sensors for Pressure Sensing

Massaroni,

Vitali,

Lo Presti

et al. 2024

Advanced Intelligent Systems

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Additive manufacturing technologies increasingly revolutionize current production techniques for object manufacturing. Particularly, fused deposition modeling (FDM) strongly impacts production processes by enabling the cost‐effective and efficient creation of structures with complex designs and innovative geometries. The use of conductive filaments in FDM printing is paving the way for the advancement of entirely printed sensors and circuits, although this domain is still in its early stages. In this article, the design and production of bilayer deformable pressure sensors fabricated using conductive thermoplastic polyurethane are investigated. The potential to vary the mechanical and electrical characteristics of FDM‐printed components by adjusting printing parameters is explored. The influence of different levels of material infill (20%, 50%, and 100%) and different contact geometries between layers (domes, pyramids, and cylinders) is studied. Electromechanical tests are carried out to characterize the sensor, applying pressures up to 22 kPa. The 3D‐printed pressure sensors demonstrate tunable mechanical and electrical sensitivities at different infill values, with the highest value of −6.3 kPa−1 achieved by using a pyramid layer at 100% infill. Sensor outputs registered during cyclic tests show reproducible responses with a wide range of sensitivity, paving the way for applicability in recording both static and periodic pressure changes.

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Sensorized Skin With Biomimetic Tactility Features Based on Artificial Cross‐Talk of Bimodal Resistive Sensory Inputs

Cited by 10 publications

References 69 publications

High‐Resolution Carbon‐Based Tactile Sensor Array for Dynamic Pulse Imaging

High‐Resolution Carbon‐Based Tactile Sensor Array for Dynamic Pulse Imaging

A Real‐Time Imaging Sensing System to Visualize Elastomer Surface Profile Evolution for Dynamic Tactile Recognition

Fully Additively 3D Manufactured Conductive Deformable Sensors for Pressure Sensing

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