Yuzhu Tang scite author profile

Yuzhu Tang

3Publications

12Citation Statements Received

50Citation Statements Given

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Affiliations

Chengdu University of Information Technology, Sichuan University

Publications

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A Physical Model-Based FDTD Field-Circuit Co-Simulation Method for Schottky Diode Rectifiers

et al. 2019

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So far, plenty of microwave power circuits such as microwave diode rectifiers are mainly designed and analyzed by conventional electromagnetic (EM) co-simulation method based on the semiconductor equivalent circuit models. However, the simplified equivalent circuit model may contribute to loss of precision at high frequencies or under high power. Compared with the equivalent circuit model, the semiconductor physical model provides a means for studying the physics of electron transport, and thus, better describes the semiconductor device. This paper explores analyzing microwave diode rectifiers by employing a physical model-based field-circuit co-simulation method. This method combines the physical model-based circuit simulation to the finite-difference time-domain (FDTD)-based field-circuit co-simulation and thus, achieves accurate and effective hybrid full-wave field-circuit co-simulation. For validation, two diode rectifiers working at S-and C-band, respectively, are simulated and analyzed by the proposed method. The simulation result agrees well with measurement and shows higher accuracy than the equivalent circuit model-based simulation.INDEX TERMS Microwave rectifier, Schottky diode, physical model, filed-circuit co-simulation.

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Dual-Polarized Dipole Antenna for Wireless Data and Microwave Power Transfer

Liao

Tang

et al. 2022

Electronics

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This manuscript presents a broadband high-efficiency dual-polarized dipole antenna for wireless power and data transfer. The proposed antenna mainly consists of cross-dipole patches, matching baluns, and a ground plane. The dual-polarized radiation mode was achieved by using two linear-polarization matching baluns to feed the cross-dipole patches orthogonally. The proposed dual-polarized dipole antenna realizes a bandwidth with S11 less than −10 dB (4.28 GHz–5.92 GHz) and a high radiation efficiency of about 95%. An independent rectifying circuit was designed, and a microwave energy transmission experiment was carried out. The final measured conversion efficiency for the two polarized ports at 5.8 GHz was about 77.6% and 76.4%, respectively. Simulation and measurement results showed that the proposed antenna is suitable for both wireless power and wireless data transfer applications.

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Short-Distance Wireless Power Transfer Based on Microwave Radiation via an Electromagnetic Rectifying Surface

Duan

Zhou

et al. 2020

Antennas Wirel. Propag. Lett.

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Yuzhu Tang

A Physical Model-Based FDTD Field-Circuit Co-Simulation Method for Schottky Diode Rectifiers

Dual-Polarized Dipole Antenna for Wireless Data and Microwave Power Transfer

Short-Distance Wireless Power Transfer Based on Microwave Radiation via an Electromagnetic Rectifying Surface

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