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A Reconfigurable Impedance Matching Method for Magnetic-Coupling-Based Near-Field Human Body Communication Journal article
Ziliang Wei, Shuang Yang, Zhizhang Chen, Mang I Vai, Sio Hang Pun, Jiejie Yang, Yueming Gao. A Reconfigurable Impedance Matching Method for Magnetic-Coupling-Based Near-Field Human Body Communication[J]. IEEE Transactions on Antennas and Propagation, 2024.
Authors:  Ziliang Wei;  Shuang Yang;  Zhizhang Chen;  Mang I Vai;  Sio Hang Pun; et al.
Favorite | TC[Scopus]:0  IF:4.6/5.0 | Submit date:2024/08/26
Human Body Communication (Hbc)  Magnetic Resonance Coupling  Impedance Matching  Reconfigurable Method  Magnetic Quasi-static Hbc  
Self-Evolutionary Neuron Model for Fast-Response Spiking Neural Networks Journal article
Zhang, Anguo, Han, Ying, Hu, Jing, Niu, Yuzhen, Gao, Yueming, Chen, Zhizhang, Zhao, Kai. Self-Evolutionary Neuron Model for Fast-Response Spiking Neural Networks[J]. IEEE Transactions on Cognitive and Developmental Systems, 2022, 14(4), 1766-1777.
Authors:  Zhang, Anguo;  Han, Ying;  Hu, Jing;  Niu, Yuzhen;  Gao, Yueming; et al.
Favorite | TC[WOS]:11 TC[Scopus]:10  IF:5.0/4.6 | Submit date:2022/05/13
Fast Response Network  Self-evolutionary Neuron Model  Spiking Neural Network  Synaptic Plasticity.  
An Investigation on Conductive Intracardiac Communication Dynamic Channel Gain during the Cardiac Cycle for Leadless Pacemakers Journal article
Chen, Liting, Liu, Yiming, Chen, Zhizhang, Pun, Sio Hang, Vai, Mang I., Gao, Yueming. An Investigation on Conductive Intracardiac Communication Dynamic Channel Gain during the Cardiac Cycle for Leadless Pacemakers[J]. IEEE Journal of Electromagnetics, RF and Microwaves in Medicine and Biology, 2022, 7(1), 82-89.
Authors:  Chen, Liting;  Liu, Yiming;  Chen, Zhizhang;  Pun, Sio Hang;  Vai, Mang I.; et al.
Favorite | TC[WOS]:4 TC[Scopus]:5 | Submit date:2023/04/03
Blood Volume  Cardiac Cycle  Galvanic Coupling Conductive Intracardiac Communication  Pacemakers  
A Visible Human Data-Based Whole-Body Model for Investigating the Transmission Attenuation of Intrabody Communication Journal article
Ziliang Wei, Yueming Gao, Zhizhang Chen, Sio Hang Pun, Mang I Vai, Min Du. A Visible Human Data-Based Whole-Body Model for Investigating the Transmission Attenuation of Intrabody Communication[J]. IEEE TRANSACTIONS ON MICROWAVE THEORY AND TECHNIQUES, 2022, 70(8), 3827-3837.
Authors:  Ziliang Wei;  Yueming Gao;  Zhizhang Chen;  Sio Hang Pun;  Mang I Vai; et al.
Favorite | TC[WOS]:2 TC[Scopus]:4  IF:4.1/4.2 | Submit date:2022/08/06
Solid Modeling  Data Models  Biological System Modeling  Attenuation  Electrodes  Legged Locomotion  Phantoms  Field-circuit Model  Finite Element Model(Fem)  Intrabody Communication()Ibc  Transmission Attenuation  Visible Human Data(Vhd)  
An Investigation on the Influence of Blood Volume in the Cardiac Cycle on Channel Gain of Intracardiac Communication Channels Conference paper
Yiming Liu, Yueming Gao, Liting Chen, Zhizhang Chen, Sio Hang Pun, Mang I Vai. An Investigation on the Influence of Blood Volume in the Cardiac Cycle on Channel Gain of Intracardiac Communication Channels[C], 2022.
Authors:  Yiming Liu;  Yueming Gao;  Liting Chen;  Zhizhang Chen;  Sio Hang Pun; et al.
Favorite | TC[WOS]:1 TC[Scopus]:1 | Submit date:2022/08/07
An Investigation on the Influence of Blood Volume in the Cardiac Cycle on Channel Gain of Intracardiac Communication Channels Conference paper
Liu, Yiming, Gao, Yueming, Chen, Liting, Chen, Zhizhang, Pun, Sio Hang, Vai, Mang I.. An Investigation on the Influence of Blood Volume in the Cardiac Cycle on Channel Gain of Intracardiac Communication Channels[C]:IEEE Journal of Electromagnetics, RF and Microwaves in Medicine and Biology ( Volume: 7, Issue: 1, March 2023), 2022, 144-146.
Authors:  Liu, Yiming;  Gao, Yueming;  Chen, Liting;  Chen, Zhizhang;  Pun, Sio Hang; et al.
Favorite | TC[WOS]:1 TC[Scopus]:1 | Submit date:2022/08/05
Blood Volume  Cardiac Cycle  Galvanic Coupling Conductive Intracardiac Communication  Pacemakers  
A Fast Background Frequency Calibration Based on Intermittent Frequency Locked Loop for the Super-Regenerative Receive Journal article
Yin, Yadong, Huang, Yitao, Chen, Zhizhang, Pun, Sio Hang, Liao, Yipeng, Gao, Yueming, Vai, Mang I.. A Fast Background Frequency Calibration Based on Intermittent Frequency Locked Loop for the Super-Regenerative Receive[J]. IEEE Access, 2022, 10, 115624-115634.
Authors:  Yin, Yadong;  Huang, Yitao;  Chen, Zhizhang;  Pun, Sio Hang;  Liao, Yipeng; et al.
Favorite | TC[WOS]:0 TC[Scopus]:1  IF:3.4/3.7 | Submit date:2023/01/30
Average Fractional Division Scheme  Background Frequency Calibration  Frequency-locked Loop  Initial Phase Error  Phase-locked Loop  Super-regenerative Receiver  Time Register  
A Visible Human Data-Based Whole-Body Model for Investigating the Transmission Attenuation of Intrabody Communication Journal article
Wei, Ziliang, Gao, Yueming, Chen, Zhizhang, Pun, Sio Hang, Vai, Mang I., Du, Min. A Visible Human Data-Based Whole-Body Model for Investigating the Transmission Attenuation of Intrabody Communication[J]. IEEE Transactions on Microwave Theory and Techniques, 2022.
Authors:  Wei, Ziliang;  Gao, Yueming;  Chen, Zhizhang;  Pun, Sio Hang;  Vai, Mang I.; et al.
Favorite | TC[WOS]:2 TC[Scopus]:4  IF:4.1/4.2 | Submit date:2022/08/05
Attenuation  Biological System Modeling  Data Models  Electrodes  Field-circuit Model  Finite Element Model (Fem)  Intrabody Communication (Ibc)  Legged Locomotion  Phantoms  Solid Modeling  Transmission Attenuation  Visible Human Data (Vhd)  
An Intermittent Frequency Synthesizer with Accurate Frequency Detection for Fast Duty-Cycled Receivers Journal article
Yin,Yadong, El-Sankary,Kamal, Chen,Zhizhang, Gao,Yueming, Vai,Mang I., Pun,Sio Hang. An Intermittent Frequency Synthesizer with Accurate Frequency Detection for Fast Duty-Cycled Receivers[J]. IEEE Access, 2020, 8, 45148-45155.
Authors:  Yin,Yadong;  El-Sankary,Kamal;  Chen,Zhizhang;  Gao,Yueming;  Vai,Mang I.; et al.
Favorite | TC[WOS]:3 TC[Scopus]:4  IF:3.4/3.7 | Submit date:2021/03/11
Duty Cycle  Frequency Detector  Frequency Synthesizer  Initial Phase Error  Phase-locked Loop