Stretchable Neuromorphic Transistor That Combines Multisensing and Information Processing for Epidermal Gesture Recognition

Liu, Lu; Xu, Wenlong; Ni, Youxuan; Xu, Zhipeng; Cui, Binbin; Liu, Jiaqi; Wei, Huanhuan; Xu, Wentao

doi:10.1021/acsnano.1c08482

Cited by 68 publications

(93 citation statements)

References 66 publications

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“…Higher animals actively interact with external environments through highly evolved neural systems, performing cognitive tasks such as thinking, learning, and memory. , Enormous efforts have been made to pursue intelligent robotics and electronic modules that autonomously interact with external environments in a way similar to biological neural systems. − However, it remains a huge challenge to realize feedback behaviors with advanced intelligence, i.e. learning and self-optimizing instead of monotonic and simple responses. − Although simulations based on software-programing have been used to achieve artificial intelligence through classical von Neumann digital systems, such conventional computing architectures suffer from the bottleneck of constant data shuttling between the memory and the processor, leading to speed latency, high energy consumption, and limited communication bandwidth . In addition, the conversion of analog sensor signals to digital signals leads to more energy cost, latency, and circuit complexity .…”

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confidence: 99%

Artificial Neural Pathway Based on a Memristor Synapse for Optically Mediated Motion Learning

Liu

Guo

et al. 2022

ACS Nano

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Animals execute intelligent and efficient interactions with their surroundings through neural pathways, exhibiting learning, memory, and cognition. Artificial autonomous devices that generate self-optimizing feedback mimicking biological systems are essential in pursuing future intelligent robots. Here, we report an artificial neural pathway (ANP) based on a memristor synapse to emulate neuromorphic learning behaviors. In our ANP, optical stimulations are detected and converted into electrical signals through a flexible perovskite photoreceptor. The acquired electrical signals are further processed in a zeolitic imidazolate frameworks-8 (ZIF-8)-based memristor device. By controlling the growth of the ZIF-8 nanoparticles, the conductance of the memristor can be finely modulated with electrical stimulations to mimic the modulation of synaptic plasticity. The device is employed in the ANP to implement synaptic functions of learning and memory. Subsequently, the synaptic feedbacks are used to direct a robotic arm to perform responding motions. Upon repeatedly "reviewing" the optical stimulation, the ANP is able to learn, memorize, and complete the specific motions. This work provides a promising strategy toward the design of intelligent autonomous devices and bioinspired robots through memristor-based systems.

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confidence: 99%

Artificial Neural Pathway Based on a Memristor Synapse for Optically Mediated Motion Learning

Liu

Guo

et al. 2022

ACS Nano

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“…Recently, due to the development of synaptic transistors, a tribo-nanogenerator (TENG), and smart wearable devices, − some bioinspired systems integrating sensors and neuromorphic devices have been reported to simulate biological perception and control biological behavior. ,− Various systems for motion perception have been reported, for example, an artificial vision system was mimicked with flexible memristor neural network, in which both low-level in-sensory processing (noise suppression and filtering) and high-level in-sensor computing (weight updating) have been realized . A more complex self-motion sensory system is constructed to detect muscle stretching and joint bending with the integration of a flexible TENG and synaptic transistor .…”

Section: Introductionmentioning

confidence: 99%

Bioinspired Artificial Motion Sensory System for Rotation Recognition and Rapid Self-Protection

Chen

et al. 2022

ACS Nano

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As one of the most common synergies between the exteroceptors and proprioceptors, the synergy between visual and vestibule enables the human brain to judge the state of human motion, which is essential for motion recognition and human self-protection. Hence, in this work, an artificial motion sensory system (AMSS) based on artificial vestibule and visual is developed, which consists of a tribo-nanogenerator (TENG) as a vestibule that can sense rotation and synaptic transistor array as retina. The principle of temporal congruency has been successfully realized by multisensory input. In addition, pattern recognition results show that the accuracy of multisensory integration is more than 15% higher than that of single sensory. Moreover, due to the rotation recognition and visual recognition functions of AMSS, we realized multimodal information recognition including angles and numbers in the spiking correlated neural network (SCNN), and the accuracy rate reached 89.82%. Besides, the rapid self-protection of a human was successfully realized by AMSS in the case of simulated amusement rides, and the reaction time of multiple motion sensory integration is only one-third of that of a single vestibule. The development of AMSS based on the synergy of simulated vision and vestibule will show great potential in neural robot, artificial limbs, and soft electronics.

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“…sensors with lightweight neural networks, [36] especially in the field of motion monitoring [37] and real-time interaction. [38,39] In contrast to the common visual recognition method using the standardized mass data from the camera, the distinguishing pattern features are difficult for wearable systems because the sensor number and the measured data size are limited by the cramped spaces.…”

Section: Introductionmentioning

confidence: 99%

“…However, the main challenge of rapid gesture recognition is the trade‐off between the requirement for gathering mass data and the compact design of wearable systems, in which the sensor number affects this balance considerably. Therefore, it is particularly important to combine sensors with lightweight neural networks, [ 36 ] especially in the field of motion monitoring [ 37 ] and real‐time interaction. [ 38,39 ]…”

Section: Introductionmentioning

confidence: 99%

Low‐Cost Data Glove Based on Deep‐Learning‐Enhanced Flexible Multiwalled Carbon Nanotube Sensors for Real‐Time Gesture Recognition

Yang

et al. 2022

Advanced Intelligent Systems

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With advancements in artificial intelligence, wearable motion recognition systems based on flexible nanomaterial sensors exhibit excellent potential for harmonious human–machine interaction. However, the sensing stability and demand of large‐scale arrays limit the application of flexible nanomaterial sensors. Herein, a data glove system based on simple multiwalled carbon nanotube (MWCNT) sensors and a lightweight deep‐learning algorithm to achieve accurate gesture recognition is proposed. A regional‐crack mechanism is introduced through the microspine structure to enhance the strain sensitivity. Moreover, an efficient signal processing strategy based on an adaptive wavelet threshold function to improve the robustness and anti‐interference of signals obtained from MWCNT sensors, which exhibit strong generalization and can be used in other nanomaterial strain sensor. Based on the depth‐wise separable convolution, a novel hybrid convolutional neural network (CNN) long short‐term memory (LSTM) model for gesture recognition is constructed. The proposed model achieves an average accuracy of 97.5% and recognition accuracy of 30 gestures with an average recognition time of 2.173 ms based on only five sensors. The fabricated data glove is a promising platform for low‐cost and wearable human–machine interaction that can be directly interfaced in applications such as robotic hands, smart cars, and first‐person shooting games.

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Stretchable Neuromorphic Transistor That Combines Multisensing and Information Processing for Epidermal Gesture Recognition

Cited by 68 publications

References 66 publications

Artificial Neural Pathway Based on a Memristor Synapse for Optically Mediated Motion Learning

Artificial Neural Pathway Based on a Memristor Synapse for Optically Mediated Motion Learning

Bioinspired Artificial Motion Sensory System for Rotation Recognition and Rapid Self-Protection

Low‐Cost Data Glove Based on Deep‐Learning‐Enhanced Flexible Multiwalled Carbon Nanotube Sensors for Real‐Time Gesture Recognition

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