Your search keyword '"Lim, Brian Z. H."' showing total 4 results

1. Artificial Intelligence Enables Real-Time and Intuitive Control of Prostheses via Nerve Interface

Author

Luu, Diu Khue, Nguyen, Anh Tuan, Jiang, Ming, Drealan, Markus W., Xu, Jian, Wu, Tong, Tam, Wing-kin, Zhao, Wenfeng, Lim, Brian Z. H., Overstreet, Cynthia K., Zhao, Qi, Cheng, Jonathan, Keefer, Edward W., and Yang, Zhi

Subjects

Computer Science - Robotics, Computer Science - Artificial Intelligence, Computer Science - Human-Computer Interaction, Computer Science - Machine Learning, Quantitative Biology - Neurons and Cognition

Abstract

Objective: The next generation prosthetic hand that moves and feels like a real hand requires a robust neural interconnection between the human minds and machines. Methods: Here we present a neuroprosthetic system to demonstrate that principle by employing an artificial intelligence (AI) agent to translate the amputee's movement intent through a peripheral nerve interface. The AI agent is designed based on the recurrent neural network (RNN) and could simultaneously decode six degree-of-freedom (DOF) from multichannel nerve data in real-time. The decoder's performance is characterized in motor decoding experiments with three human amputees. Results: First, we show the AI agent enables amputees to intuitively control a prosthetic hand with individual finger and wrist movements up to 97-98% accuracy. Second, we demonstrate the AI agent's real-time performance by measuring the reaction time and information throughput in a hand gesture matching task. Third, we investigate the AI agent's long-term uses and show the decoder's robust predictive performance over a 16-month implant duration. Conclusion & significance: Our study demonstrates the potential of AI-enabled nerve technology, underling the next generation of dexterous and intuitive prosthetic hands.

Published

2022

2. Near–hysteresis-free soft tactile electronic skins for wearables and reliable machine learning

Author

Yao, Haicheng, Yang, Weidong, Cheng, Wen, Tan, Yu Jun, See, Hian Hian, Li, Si, Ali, Hashina Parveen Anwar, Lim, Brian Z. H., Liu, Zhuangjian, and Tee, Benjamin C. K.

Published

2020

3. Artificial Intelligence Enables Real-Time and Intuitive Control of Prostheses via Nerve Interface

Author

Luu, Diu Khue, primary, Nguyen, Anh Tuan, additional, Jiang, Ming, additional, Drealan, Markus W., additional, Xu, Jian, additional, Wu, Tong, additional, Tam, Wing-kin, additional, Zhao, Wenfeng, additional, Lim, Brian Z. H., additional, Overstreet, Cynthia K., additional, Zhao, Qi, additional, Cheng, Jonathan, additional, Keefer, Edward W., additional, and Yang, Zhi, additional

Published

2022

4. Near-hysteresis-free soft tactile electronic skins for wearables and reliable machine learning.

Author

Haicheng Yao, Weidong Yang, Wen Cheng, Yu Jun Tan, Hian Hian See, Si Li, Anwar Ali, Hashina Parveen, Lim, Brian Z. H., Zhuangjian Liu, and Tee, Benjamin C. K.

Subjects

TACTILE sensors, MACHINE learning, SURFACE texture, DEEP learning, SKIN

Abstract

Electronic skins are essential for real-time health monitoring and tactile perception in robots. Although the use of soft elastomers and microstructures have improved the sensitivity and pressure-sensing range of tactile sensors, the intrinsic viscoelasticity of soft polymeric materials remains a long-standing challenge resulting in cyclic hysteresis. This causes sensor data variations between contact events that negatively impact the accuracy and reliability. Here, we introduce the Tactile Resistive Annularly Cracked E-Skin (TRACE) sensor to address the inherent trade-off between sensitivity and hysteresis in tactile sensors when using soft materials. We discovered that piezoresistive sensors made using an array of three-dimensional (3D) metallic annular cracks on polymeric microstructures possess high sensitivities (> 107 Ω ⋅ kPa-1), low hysteresis (2.99 ± 1.37%) over a wide pressure range (0-20 kPa), and fast response (400 Hz). We demonstrate that TRACE sensors can accurately detect and measure the pulse wave velocity (PWV) when skin mounted. Moreover, we show that these tactile sensors when arrayed enabled fast reliable one-touch surface texture classification with neuromorphic encoding and deep learning algorithms. [ABSTRACT FROM AUTHOR]

Published

2020