Your search keyword '"human−machine interactions"' showing total 4 results

1. Low-Power-Consumption Electronic Skins Based on Carbon Nanotube/Graphene Hybrid Films for Human–Machine Interactions and Wearable Devices.

Author

Zhang, Rui, Lv, Shaoguang, Li, Zili, Dong, Yin, Zhao, Yige, Gong, Weiping, Sun, Yueli, Zou, Xingli, Lu, Xionggang, and Yuan, Guangjie

Abstract

Due to their excellent electrical and mechanical properties, carbon nanotubes (CNTs) and graphene (G) have attracted increasing attention for the application of electronic skins (E-skins). In this paper, based on CNT/G hybrid films with a resistivity of 4.98 × 10–4 Ω·m, we prepared two kinds of E-skins with low power consumption and successfully realized the perception of multiple signals, including stretching, bending, temperature, and pressure. With a G mass fraction of 20%, the stretch/flexion/temperature-sensitive E-skin has an ultrahigh gauge factor (GF) of 1429 with a strain range of 0 to 10%, a GF of 0.92 rad–1 with a bending angle range of 0 to 90°, and a GF of 1.1 × 10–3 °C–1 with a temperature range of 25 to 85 °C; the pressure-sensitive E-skin has a GF of 7.45 kPa–1 with a pressure range of 15 to 10,015 Pa. In addition, we applied the prepared E-skins in human–machine interactions and wearable devices and confirmed their low power consumption below 74.20 nW in wearable applications. [ABSTRACT FROM AUTHOR]

Published

2023

2. Flexible Strain Sensors for Wearable Hand Gesture Recognition: From Devices to Systems.

Author

Si, Yuying, Chen, Sujie, Li, Ming, Li, Siying, Pei, Yisen, and Guo, Xiaojun

Subjects

HUMAN-machine systems, STRAIN sensors, WEARABLE technology, ALGORITHMS, DATA analysis

Abstract

Hand gesture recognition has attracted extensive research interest, as an essential approach for human−machine interaction. The development of flexible strain sensors offers the possibility of directly measuring the finger motion behaviors for accurate and cost‐effective hand gesture recognition, by placing the sensors on the fingers or integrating them on data gloves. Herein, the operation mechanisms of various flexible strain sensor designs are introduced first. Progresses on related materials and device structures to achieve the demanded figure of merits for flexible strain sensors are then reviewed. In addition to continuous performance optimization of the flexible strain sensor devices, the development of system‐level algorithms is shown to be important for not only recognition functions but also for suppression of nonidealities of the sensor devices, which are difficult to be addressed at device and material level. [ABSTRACT FROM AUTHOR]

Published

2022

3. Flexible Strain Sensors for Wearable Hand Gesture Recognition: From Devices to Systems

Author

Yuying Si, Sujie Chen, Ming Li, Siying Li, Yisen Pei, and Xiaojun Guo

Subjects

hand gesture recognitions, human−machine interactions, strain sensors, wearable systems, Computer engineering. Computer hardware, TK7885-7895, Control engineering systems. Automatic machinery (General), TJ212-225

Abstract

Hand gesture recognition has attracted extensive research interest, as an essential approach for human−machine interaction. The development of flexible strain sensors offers the possibility of directly measuring the finger motion behaviors for accurate and cost‐effective hand gesture recognition, by placing the sensors on the fingers or integrating them on data gloves. Herein, the operation mechanisms of various flexible strain sensor designs are introduced first. Progresses on related materials and device structures to achieve the demanded figure of merits for flexible strain sensors are then reviewed. In addition to continuous performance optimization of the flexible strain sensor devices, the development of system‐level algorithms is shown to be important for not only recognition functions but also for suppression of nonidealities of the sensor devices, which are difficult to be addressed at device and material level.

Published

2022

4. A Flexible Self-Powered Noncontact Sensor with an Ultrawide Sensing Range for Human-Machine Interactions in Harsh Environments.

Author

Dai N, Guan X, Lu C, Zhang K, Xu S, Lei IM, Li G, Zhong Q, Fang P, and Zhong J

Subjects

Humans, Humidity, Electricity

Abstract

Noncontact human-machine interactions (HMIs) provide a hygienic and intelligent approach to communicate between humans and machines. However, current noncontact HMIs are generally hampered by the interaction distance, and they lack the adaptability to environmental interference such as high humidity conditions. Here, we explore a self-powered electret-based noncontact sensor (ENS) with moisture-resisting ability and ultrawide sensing range exceeding 2.5 m. A megascopic air-bubble structure is designed to enhance charge-storage stability and charge-recovery ability of the ENS based on the heterocharge-synergy effect in electrets. Besides, multilayer electret films are introduced to strengthen the electric field by utilizing the electrostatic field superposition effect. Thanks to the above improved performances of the ENS, we demonstrate various noncontact HMI applications in harsh environments, including noncontact appliances, a moving trajectory and accidental fall tracking system, and a real-time machine learning-assisted gesture recognition system with accuracy as high as 99.21%. This research expands the way for noncontact sensor design and may further broaden applications in noncontact HMIs.

Published

2023