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1. Tuning Performance Parameters of Ge-on-Si Avalanche Photodetector–Part II: Large Bias Operation

Author

Yanning Chen, Fang Liu, Yali Shao, Yingzong Liang, Sichao Du, and Wen-Yan Yin

Subjects
Avalanche photodetector (APD), Geiger-mode, linear multiplication, vertical Ge-on-Si APD, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

The carrier multiplication phenomenon involves hot carriers, which gain kinetic energy while accelerating to equilibrium with the established avalanching electric fields, and is typically explained via the local avalanche model. This work presents two vertical Ge-on-Si avalanche photodetectors fabricated in a separate absorption, charge, and multiplication configuration. Uniformity in materials, doping densities, and device dimensions is maintained, except for the multiplication width, which is used as a control parameter to manipulate avalanching fields under identical electric biasing and illumination schemes. Nonlocal carrier multiplication model is implemented during analysis of the extracted current-voltage signatures under small and large reverse biasing arrangements. For such an APD characterized by thinner multiplication region $\left ({{W_{m}=0.1 ~\mu m}}\right)$ , reduced linear and Geiger-mode multiplication regimes are perceived to be at play, outperforming the device having thicker multiplication region in almost all related figures of merit, e.g., responsivity $(22.58 \mathrm {A/W})$ , photo-to-dark current ratio $(\sim {10}^{5})$ , normalized photo-to-dark current ratio $(2.5\times {10}^{9} \mathrm {W}^{-1})$ , specific detectivity $(7.45\times {10}^{12}\mathrm {Jones})$ , and noise equivalent power $(\sim 2.42\times {10}^{-15} \mathrm {W/}\sqrt {\mathrm {Hz}})$ . The enhanced performance characteristics are due to excessively strong avalanching fields, reduced thermal charge density, and negligible dead space compared to its counterpart characterized by thicker multiplication width.

Published
2024
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2. A 39 GHz Dual-Channel Transceiver Chipset with an Advanced LTCC Package for 5G Multi-Beam MIMO Systems

Author

Yiming Yu, Zhilin Chen, Chenxi Zhao, Huihua Liu, Yunqiu Wu, Wen-Yan Yin, and Kai Kang

Subjects
5G, Multi-beam, Multi-input multi-output, Millimeter-wave, Transceiver, Wireless communication, Engineering (General). Civil engineering (General), TA1-2040
Abstract

This article presents a 39 GHz transceiver front-end chipset for 5G multi-input multi-output (MIMO) applications. Each chip includes two variable-gain frequency-conversion channels and can support two simultaneous independent beams, and the chips also integrate a local-oscillator chain and digital module for multi-chip extension and gain-state control. To improve the radio-frequency performance, several circuit-level improvement techniques are proposed for the key building blocks in the front-end system. Furthermore, an advanced low-temperature co-fired ceramic process is developed to package the 39 GHz dual-channel transceiver chipset, and it achieves low packaging loss and high isolation between the two transmitting (TX)/receiving (RX) channels. Both the chip-level and system-in-package (SIP)-level measurements are conducted to demonstrate the performance of the transceiver chipset. The measurement characteristics show that the TX SIP provides 11 dB maximum gain and 10 dBm saturated output power, while the RX SIP achieves 52 dB maximum gain, 5.4 dB noise figure, and 7.2 dBm output 1 dB compression point. Single-channel communication link testing of the transceiver exhibits an error vector magnitude (EVM) of 3.72% and a spectral efficiency of 3.25 bit·s−1·Hz−1 for 64-quadrature amplitude modulation (QAM) modulation and an EVM of 3.76% and spectral efficiency of 3.90 bit·s−1·Hz−1 for 256-QAM modulation over a 1 m distance. Based on the chipset, a 39 GHz multi-beam prototype is also developed to perform the MIMO operation for 5G millimetre wave applications. The over-the-air communication link for one- and two-stream transmission indicates that the multi-beam prototype can cover a 5–150 m distance with comparable throughput.

Published
2023
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3. Accurate Formulation of the Skin and Proximity Effects in High-Speed Cable System

Author

Oussama Gassab, Yanning Chen, Yali Shao, Jingxiao Li, Ding-E Wen, Fang He, Zhizhen Su, Peina Zhong, Jian Wang, Dongyan Zhao, and Wen-Yan Yin

Subjects
High-speed cable, transmission line model, mixed-mode S-parameters, common-mode (CM), differential-mode (DM), shielding, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

An efficient transmission line model of high-speed cables is established, to predict its response at a high-frequency region (up to 20 GHz). Especially, an appropriate conformal mapping technique is applied to formulate the per-unit-length parameters of high-speed cables. Moreover, the skin and proximity effects of the conducting wires and the outer shield are derived in the closed form. As a result, the AC resistance/ inductance of all the conducting materials due to the skin and proximity effects are accurately incorporated for both layered and unlayered conductors. Furthermore, the mixed-mode S-parameters are precisely predicted for both balanced and unbalanced transmission line cables in the high-frequency region. In addition, the effects of the nonuniformities and cable geometry deformation on the mode conversions are also investigated. The proposed model is firstly validated with commercial software tools, COMSOL, FEKO, and HFSS; then, we further performed physical measurements to verify our new algorithm.

Published
2022
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4. Fully Coupled Electrothermal Simulation of Large RRAM Arrays in the 'Thermal-House'

Author

Da-Wei Wang, Wenchao Chen, Wen-Sheng Zhao, Guo-Dong Zhu, Kai Kang, Pingqi Gao, Jose E. Schutt-Aine, and Wen-Yan Yin

Subjects
Electrothermal simulation, low power consumption, parallel simulator, resistive-switching random access memory (RRAM), thermal-house, thermal management, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

Thermal crosstalk in a highly integrated RRAM array due to the self-heating effect is one of the most critical issues affecting device reliability. In this paper, two types of “thermal-house” structures are proposed to optimize the thermal management of the RRAM array. An in-house developed parallel simulator is employed to study the performance of the proposed thermal house structures in terms of resistance ratio and crosstalk temperature. It is demonstrated that the proposed thermal house structures can help to reduce thermal crosstalk in high-density RRAM arrays. Some suggestions are also provided for further improving the thermal management capability of the thermal houses as well.

Published
2019
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5. An Improved Algorithm for Drift Diffusion Transport and Its Application on Large Scale Parallel Simulation of Resistive Random Access Memory Arrays

Author

Da-Wei Wang, Wenchao Chen, Wen-Sheng Zhao, Guo-Dong Zhu, Zhen-Guo Zhao, Jose E. Schutt-Aine, and Wen-Yan Yin

Subjects
Domain decomposition method (DDM), drift diffusion, electrothermal modeling and simulation, finite element method (FEM), finite volume method (FVM), reliability, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

A hybrid finite volume-finite element method which can avoid overestimation of volume shared by each vertex in the meshing grid is proposed to solve the diffusive transport governed continuity equation. The simulation results demonstrate that the improved algorithm can eliminate unphysical distortions as compared to the conventional Scharfetter Gummel method. Based on the proposed algorithm, a parallel-computation simulator is developed for large-scale electrothermal simulation of resistive random access memory (RRAM) arrays, in which the domain decomposition method and J parallel adaptive unstructured mesh applications infrastructure are adopted. The validity, speedup, and scalability of the parallel simulator are investigated on the TianHe-2 supercomputer. Based on the simulated results, the electrothermal characteristics and reliability analysis of large-scale RRAM arrays are investigated in detail.

Published
2019
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6. Differential Probe Fed Liquid Crystal-Based Frequency Tunable Circular Ring Patch Antenna

Author

Guanghui Xu, Hong-Li Peng, Changli Sun, Jian-Gang Lu, Yaoping Zhang, and Wen-Yan Yin

Subjects
Circular ring patch antennas, cavity model, nematic liquid crystal, differential probe fed, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

A differential probe-fed liquid crystal (LC)-based frequency tunable circular-ring patch antenna is presented. Besides, cavity model is extended to analyze the LC-based antenna for the differential operation. According to the cavity model, the permittivity and loss tangent of the LC are extracted from the measured differential reflection coefficients. Acceptable agreements among the measurement, simulation, and calculation for differential impedances, reflection coefficients, and radiation patterns are obtained and also validate the extraction method and model. More importantly, the extended cavity model can provide a deep physical insight into the LC-based antenna.

Published
2018
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7. Analysis of Cu-Graphene Interconnects

Author

Zi-Han Cheng, Wen-Sheng Zhao, Da-Wei Wang, Jing Wang, Linxi Dong, Gaofeng Wang, and Wen-Yan Yin

Subjects
Cu-graphene interconnect, diffusion barrier layer, equivalent single-conductor (ESC) model, transfer function, time delay, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

Due to its ultrathin feature, graphene has been recently proposed as diffusion barrier layer for Cu wires. This paper is geared toward developing an equivalent single-conductor (ESC) transmission-line (TL) model for analysis of Cu-graphene interconnects, i.e., Cu wires encapsulated with graphene barriers. Based on the ESC TL model, electrical performances of Cu-graphene interconnects are examined and evaluated. It is shown that the time delay and temperature rise can be reduced by replacing the conventional diffusion barriers in the Cu/low-k interconnect with the graphene barriers.

Published
2018
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8. A Compact Passive Equalizer Design for Differential Channels in TSV-Based 3-D ICs

Author

Kai Fu, Wen-Sheng Zhao, Da-Wei Wang, Gaofeng Wang, Madhavan Swaminathan, and Wen-Yan Yin

Subjects
Passive equalizer, through-silicon vias (TSVs), on-interposer interconnects, three-dimensional integrated circuits (3-D ICs), peak distortion analysis, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

In this paper, a compact passive equalizer for differential transmission channel is designed in TSV-based three-dimensional integrated circuits (3-D ICs). The compact size of the equalizer is achieved by a square shunt metal line. Three simplified odd-mode half circuit models are proposed for ground-signal-signal-ground (G-S-S-G) type TSVs, differential on-interposer interconnects, and differential channels, respectively. Those simplified models merely consist of frequency-independent elements and can accurately predict the differential insertion losses up to 20 GHz. Moreover, the electrical parameters of the proposed serial resistance-inductance (RL) type equalizers are derived from the system transfer functions and optimized by virtue of the time-domain inter-symbol interference cancellation technique. Further, the geometrical parameters of the RL equalizers are calculated by using a genetic algorithm based multi-objective optimization method. Finally, the performance of the designed RL equalizer is validated by both frequency- and time-domain simulations for 20 Gb/s high-speed differential signaling.

Published
2018
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9. Analysis and Design of Inductorless Wideband Low-Noise Amplifier With Noise Cancellation Technique

Author

Yiming Yu, Kai Kang, Yiming Fan, Chenxi Zhao, Huihua Liu, Yunqiu Wu, Yong-Ling Ban, and Wen-Yan Yin

Subjects
Low-noise amplifier, inductorless, noise cancellation, phase mismatch, noise figure, CMOS, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

This paper deals with the fabrication of an inductorless wideband low-noise amplifier (LNA). The LNA includes two branches in parallel: a common-source (CS) path and a common-gate (CG) path. The CS path is responsible for providing enough power gain, while the CG path is used to achieve the input impedance matching. To eliminate the noise contribution of the CG path, the noise cancellation technique is applied. Therefore, the overall noise figure (NF) is improved. The phase mismatch between the two paths is also quantitatively analyzed to investigate its effect on gain and NF. The analytical results agree well with the simulation results. The LNA has been fabricated by a commercial 0.18-μm CMOS process. The measurement results show that the LNA has achieved a maximum gain of 14.5 dB with 1.7-GHz 3-dB gain bandwidth and a minimum NF of 3 dB. The tested input 1-dB gain compression point (IP1 dB) is -10.4 dBm at 1 GHz and the input third-order intercept point is 0.25 dBm. With 1.8-V supply, the LNA draws only 6-mA dc current.

Published
2017
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10. An improved multifilamentary conduction model for multiphysics analysis of reset process in resistive random access memory

Author

Hao Xie, Wenchao Chen, Shuo Zhang, Guodong Zhu, Afshan Khaliq, Jun Hu, and Wen-Yan Yin

Subjects
Physics, QC1-999
Abstract

An improved multifilamentary conduction model for the reset process in resistive random access memory (RRAM) is constructed by considering the stochastic distribution of oxygen vacancies (Vo). In this context, conduction filaments (CFs) have different Vo densities and diffusion barriers. Fully coupled multiphysics simulations of RRAM with three CFs are performed using the time domain finite difference method to self-consistently solve the current transport, heat conduction, and Vo transport equations. The simulated I-V characteristics agree well with experiment. Since the three CFs have different thermal diffusion barriers, as in previous studies, they rupture at different applied voltages. Evolution of each CF in the reset process is investigated: from when its electrical conductivity is linearly dependent to when it is exponentially dependent on Vo density.

Published
2019
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11. A dual-polarized and reconfigurable reflectarray for generation of vortex radio waves

Author

Chen-Chen Li, Lin-Sheng Wu, and Wen-Yan Yin

Subjects
Physics, QC1-999
Abstract

Electromagnetic (EM) waves with orbital angular momentum (OAM) provide a new degree of freedom for channel multiplexing to improve the capacity of wireless communication. For OAM-based systems, it is important to design specific configurations to generate vortex radios. In this paper, a reconfigurable reflectarray antenna is proposed with independent control of dual polarizations. A reflective cell is proposed by properly assigning the variable capacitances of four varactors, which are placed between metal square rings of each unit. The varactors of each unit are divided into two groups and the capacitance value of each group controls the reflection phase for a single linear polarization. By using the equivalent circuit model, the reflective units and array can be designed efficiently. Smooth phase variation and good reflection efficiency are achieved. Then, the reflectarray is set into sectors and a simple phase-shifting surface model is used to generate vortex beam. Each sector is realized with reflective units satisfying desired reflection phases for different modes. This kind of OAM-generating method can reduce the required variation range of reflection phase and provide more choices for a specific OAM mode combination with dual polarization, which is helpful to reduce mutual coupling between the two linear polarizations. Finally, full-wave simulations show that the 0, ±1, ±2 modes of vortex beam are successfully generated at 3.5 GHz with arbitrary combination in dual-polarization, which is also supported by OAM modes purity and reflection efficiency analysis. Therefore, in our design, the reconfigurable OAM and spin angular momentum (SAM), related with polarization, can be utilized simultaneously and independently for high-capacity wireless communication.

Published
2018
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12. Mini-Review: Modeling and Performance Analysis of Nanocarbon Interconnects

Author

Wen-Sheng Zhao, Kai Fu, Da-Wei Wang, Meng Li, Gaofeng Wang, and Wen-Yan Yin

Subjects
carbon nanotube (CNT), graphene nanoribbon (GNR), circuit modeling, interconnects, nanocarbon, electrothermal co-simulation, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999
Abstract

As the interconnect delay exceeds the gate delay, the integrated circuit (IC) technology has evolved from a transistor-centric era to an interconnect-centric era. Conventional metallic interconnects face several serious challenges in aspects of performance and reliability. To address these issues, nanocarbon materials, including carbon nanotube (CNT) and graphene, have been proposed as promising candidates for interconnect applications. Considering the rapid development of nanocarbon interconnects, this paper is dedicated to providing a mini-review on our previous work and on related research in this field.

Published
2019
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30. Fourier Subspace-Based Deep Learning Method for Inverse Design of Frequency Selective Surface

Author

Zhun Wei, Xing Xing Xu, Wen-Yan Yin, and Enze Zhu

Subjects
Artificial neural network, Spatial filter, Noise (signal processing), Computer science, business.industry, Deep learning, Inverse, Inverse problem, symbols.namesake, Fourier transform, symbols, Artificial intelligence, Electrical and Electronic Engineering, business, Algorithm, Subspace topology
Abstract

Frequency selective surface (FSS) is critical for electromagnetic (EM) radiation protection due to its high spatial filtering performance, especially for active FSS. Recently, artificial neural network (ANN) has shown great potential in solving EM inverse problems and rapid industrial design. In such an inverse model with ANN, it establishes the relationship between the given inputs of S-parameters and the desired structure parameters or material parameters. However, faced with applications where S-parameters vary in a large frequency range with different curve shapes, such as multi-band microwave devices, equal interval sampling may result in high dimensional inputs and will require more complicated neural network. In this work, we present a Fourier subspace-based deep learning method (FS-BDLM) for FSS inverse design, where the dimension of the input is largely reduced by using Fourier subspace to represent the most salient features of the desired S-parameter performance. Compared with existing deep learning methods, the proposed technique makes inverse neural models more compact and more stable to noise contaminations. The validation of the proposed FS-BDLM is conducted both numerically and experimentally through two dual-passband FSS design examples, where the well-designed FSS is fabricated to validate the technique.

Published
2022

34. An Adaptive High-Order Transient Algorithm to Solve Large-Scale Anisotropic Maxwell’s Equations

Author

Qiwei Zhan, Wen-Yan Yin, Yuan Fang, Qiang Ren, Qing Huo Liu, Yiyao Wang, and Shiyou Yang

Subjects
Physics, symbols.namesake, Maxwell's equations, Field (physics), Wave propagation, Discontinuous Galerkin method, symbols, Plane wave, Basis function, Electrical and Electronic Engineering, Solver, Algorithm, Riemann solver
Abstract

This paper presents a stabilized nodal discontinuous Galerkin pseudospectral time domain (DG-PSTD) algorithm for fully anisotropic electromagnetic waves. This solver permits arbitrary high-order basis functions and adaptive hexahedral elements, thus very efficient for large-scale wave propagation in complex media. Maxwell’s equations are reformulated in a unified hyperbolic form, where a localized anisotropic Riemann solver is derived to serve as a numerical flux to exchange information across adjacent elements in the DG-PSTD scheme. This local analysis method also helps impose the time-domain anisotropic plane wave incidence in the total/scattering field framework. Numerical validations and applications demonstrate the efficiency, accuracy, and capability of this new high-order solver for 3-D large-scale generally anisotropic electromagnetic media.

Published
2022

36. Optimum Design of Electron Gun for 0.22-THz Traveling Wave Tubes

Author

Wenxin Liu, Yue Ou, Kedong Zhao, Zhihao Jin, Yanyu Wei, Ziqiang Yang, and Wen-Yan Yin

Subjects
Radiation, Materials science, Terahertz radiation, business.industry, Condensed Matter Physics, Traveling-wave tube, Cathode, Thermal expansion, law.invention, Optics, law, Compression ratio, Cathode ray, Physics::Accelerator Physics, Electrical and Electronic Engineering, business, Beam (structure), Electron gun
Abstract

To improve the performance of a pencil beam electron gun for terahertz traveling wave tubes (TWT), a support vector regression (SVR) method combined with a goal attainment algorithm, which is used to optimize its structural parameters considering the periodic permanent magnetic (PPM) focusing system, is proposed in this article. Moreover, a parameter correction method to reduce the impact of the thermal expansion on the electron gun is proposed. An electron gun for 0.22-THz TWT gun is developed, in which a 30-mA/23.8-kV electron beam emitted by a curved barium-tungsten cathode with a beam loading of 4 A/cm² is achieved with the optimized parameters. To the high current density for THz beam-wave interaction, the area compression ratio of electron beam is used in beam tunnel and reaches 144. The experimental results are very similar to the simulation results, which indicate that the methods would be beneficial to the development of TWT.

Published
2022

38. A Scalable HPC-Based Domain Decomposition Method for Multiphysics Modeling of RF Devices

Author

Hai Jing Zhou, Hao-Xuan Zhang, Wei-Jie Wang, Liang Zhou, Zhenguo Zhao, Da-Wei Wang, Qiwei Zhan, Zikang Qin, Yin-Da Wang, Li Huang, Wen-Yan Yin, and Kai Kang

Subjects
Commercial software, Speedup, Preconditioner, Computer science, Multiphysics, Domain decomposition methods, Krylov subspace, Solver, Supercomputer, Computer Science::Numerical Analysis, Industrial and Manufacturing Engineering, Electronic, Optical and Magnetic Materials, Computational science, Computer Science::Mathematical Software, Electrical and Electronic Engineering
Abstract

In this paper, a large-scale electromagnetic-thermal-mechanical co-simulation solver is implemented for simulating complex radio frequency components by using a high performance computing framework. The proposed solver integrates the frequency-domain electric field simulation, with time-domain thermal and thermal induced stress simulations, via a multiphysics coupling iterative process. In order to speed up the co-simulation, a Krylov subspace method with a domain decomposition method (DDM) preconditioner is used. First, the developed multiphysics solver is verified with the commercial software COMSOL Multiphysics. Then, the parallel performance of our co-simulation solver, with different ghost mesh thicknesses, is tested on a supercomputer. Finally, some multiphysics results of filters and a real-world system-in-package (SiP) are obtained with our proposed solver.

Published
2021

39. Transmission Line Model for a Shielded TWP With Apertures and Generalization to Braided–Shielded TWP Cables

Author

Liang Zhou, Qiwei Zhan, Wen-Yan Yin, and Oussama Gassab

Subjects
Physics, Admittance, FEKO, Generalization, Transfer impedance, Mechanics, Condensed Matter Physics, Atomic and Molecular Physics, and Optics, law.invention, Twisted pair, Transmission line, law, Shielded cable, Common-mode signal, Electrical and Electronic Engineering
Abstract

An efficient multiconductor transmission line (MTL) model of a shielded twisted wire pair (TWP) with apertures on its sheath is developed for predicting common mode (CM) and differential mode (DM) currents induced in the shielded TWP cable. Its transfer impedance and admittance with one-line apertures on its sheath are derived in a closed form. Therefore, the MTL equations are formulated and solved to obtain the CM and DM currents induced in the shielded TWP. Moreover, the proposed MTL model is generalized to be applicable for the braided–shielded TWP, in which the transfer impedance and admittance are formulated analytically. Results showed that the induced DM current inside the braided–shielded TWP is suppressed dramatically due to the uniform structure of the cable. The models are validated by comparing their results with those obtained by the commercial software FEKO; good agreements are obtained.

Published
2021

42. A Hybrid Streamline Upwind Finite Volume-Finite Element Method for Semiconductor Continuity Equations

Author

Wen-Sheng Zhao, Gaofeng Wang, Wenchao Chen, Wen-Yan Yin, Zheng-Min Zhang, Qi Liu, Da-Wei Wang, and Hao Xie

Subjects
Nonlinear system, Finite volume method, Continuity equation, Discretization, Computer science, Numerical analysis, Semiconductor device modeling, Applied mathematics, Domain decomposition methods, Electrical and Electronic Engineering, Finite element method, Electronic, Optical and Magnetic Materials
Abstract

This article presents the construction and analysis of a hybrid numerical method for the discretization of the convection-dominated nonlinear carrier transport process in semiconductor devices. In the construction of the method, the edge streamline upwind (SU) current density model is employed to overcome the nonconvergence brought by the nonlinear property of the current continuity equation, and the mixed finite volume-finite element method (FVFEM) is utilized to effectively extend the edge SU current density model to multidimensional applications. The proposed method is more reliable and flexible than the finite box (FB) method and streamline upwind Petrov–Galerkin (SUPG) method. The performance of several popular SU current density models is compared to find the optimal one. The proposed method is validated by comparing the calculated results with those calculated using commercial software. Based on the streamline upwind-finite volume-finite element method (SU-FVFEM), the finite element method (FEM), and the domain decomposition method (DDM), an in-house parallel computing electrothermal simulator is developed for large-scale semiconductor devices. The performance of the in-house developed parallel simulator is evaluated through simulations of a p-n junction diode and a 3-D bipolar transistor. The results demonstrated that the developed parallel simulator possesses good accuracy, applicability, and scalability.

Published
2021

43. Lumped-Network FDTD Method for Simulating Transient Responses of RF Amplifiers Excited by Intentional Electromagnetic Interference Signals

Author

Qi-Feng Liu, Huai-Qing Zhang, Chao Ni, and Wen-Yan Yin

Subjects
Physics, Interference (communication), Amplifier, RF power amplifier, Finite-difference time-domain method, Electronic engineering, Port (circuit theory), Transient (oscillation), Radio frequency, Electrical and Electronic Engineering, Condensed Matter Physics, Atomic and Molecular Physics, and Optics, Electromagnetic interference
Abstract

Unintentional as well as intentional electromagnetic interference can cause interference and performance degradation of microwave circuits or systems. In this article, a modified multiport lumped-network finite-difference time-domain method (FDTD) method based on Y-matrix is proposed, where bilinear transform is used to incorporate the V–I relation of the lumped-network into FDTD iteration. It is further used for simulating transient responses of mesfet -based amplifiers, which are often used in many radar and communication systems. The excitation of such an RF amplifier is assumed to be an intentional electromagnetic interference (IEMI) signal but with different waveforms and magnitudes. Parametric studies are performed to show hybrid effects of waveforms and magnitudes of the IEMI signals on the transient coupled voltages at the output port of such mesfet -based amplifier, with useful information obtained for understanding the interaction process between the intentional electromagnetic interference signals and active components.

Published
2021

44. EMI Analysis of Multiscale Transmission Line Network Using a Hybrid FDTD Method

Author

Wen-Yan Yin, Lu Yao, Ying Wang, and Jian Wang

Subjects
Computer science, EMI, Transmission line, Numerical analysis, Finite-difference time-domain method, Finite difference method, Electronic engineering, Telegrapher's equations, Voltage source, Electrical and Electronic Engineering, Condensed Matter Physics, Atomic and Molecular Physics, and Optics, Electromagnetic interference
Abstract

A hybrid time-domain numerical method based on the full wave finite-difference time-domain (FDTD) method combined with a modified 1-D FDTD method has been proposed to analyze the electromagnetic interference (EMI) of multiscale transmission line networks in a metallic cabin in this article. This method is implemented through two numerical solvers for full wave and transmission line simulations, respectively, by adopting a set of reasonable physical boundary conditions between external fields and transmission line network. By using Ampere's law, the external fields can be transferred to a voltage source that can be further used as the forcing terms in the telegraph equation of the transmission line network. To overcome the challenge introduced by the multiscale size of the transmission line network, we combine 1-D explicit and implicit FDTD methods together to solve the coaxial cables and interconnects in PCB, respectively. Thus, among different subdomains, the hybrid method can be carried with the same time step without the restriction of the stability condition. Numerical examples show the accuracy as well as efficiency of the proposed method compared with the HSPICE and traditional FDTD method. In addition, the method is used successfully in analyzing the EMI effects of a complex transmission line network inside a cabin illuminated by external electromagnetic wave.

Published
2021

45. Microstrip Grid and Patch-Based Dual-Band Shared-Aperture Differentially Fed Array Antenna

Author

Zhixiang Huang, Yao-Ping Zhang, Guanghui Xu, Hong-Li Peng, Li-Xia Yang, Wei Wang, and Wen-Yan Yin

Subjects
Physics, business.industry, Aperture, Bandwidth (signal processing), 020206 networking & telecommunications, 02 engineering and technology, Microstrip, Optics, Coupling (computer programming), 0202 electrical engineering, electronic engineering, information engineering, Multi-band device, Electrical and Electronic Engineering, Reflection coefficient, Antenna (radio), business, Electrical impedance
Abstract

The design of a shared-aperture dual-band differentially fed array antenna with microstrip grid and patches is presented in this letter. The patches as high-frequency elements operating at 38 GHz are inserted into microstrip grid array antenna (MGAA) operating at the low-frequency band of 28 GHz. The impedance bandwidth of MGAA can be enhanced from 3% to 16% at 28 GHz due to the introduced resonance from its coupling with the patches. The measurement shows that the proposed antenna can achieve the impedance bandwidths of 15.65% and 16.7%, isolation of more than 20 dB, and peak gains of 14.7 and 14.5 dBi at dual bands of 28 and 38 GHz, respectively. Therefore, the design scheme will be useful for the dual-band millimeter-wave 5G applications.

Published
2021

46. A Wideband CMOS Frequency Quadrupler With Transformer-Based Tail Feedback Loop

Author

Chenxi Zhao, Kai Yi, Yiming Yu, Huihua Liu, Kai Kang, Yunqiu Wu, Wen-Yan Yin, and Pan Tang

Subjects
Physics, business.industry, Frequency multiplier, 020208 electrical & electronic engineering, Bandwidth (signal processing), Electrical engineering, dBc, 020206 networking & telecommunications, 02 engineering and technology, CMOS, Harmonics, 0202 electrical engineering, electronic engineering, information engineering, Electrical and Electronic Engineering, Wideband, business, Gain stage, Electrical impedance
Abstract

In this brief, a millimeter-wave (mm-Wave) wideband frequency quadrupler is demonstrated in a 55-nm CMOS technology. It cascades two injection-locked frequency doublers (ILFD). Each of them consists of an oscillator gain stage realized by an injection-locked oscillator (ILO) and a frequency doubler implemented by a push-push pair. A tail feedback loop is proposed and applied in the second ILFD. It effectively boosts the injection current for the second ILFD. Therefore, both the operating bandwidth and output power (Pout) of the circuit are prominently improved. In addition, transformer-based high-order resonators are used to reduce the phase variation of their impedance around 0° and hence extend the locking range of ILOs. According to the measurement results, a frequency range of 30.8 ~ 40 GHz is achieved. The maximum Pout is up to -7.1 dBm without additional buffers. The circuit also attains a wide 3-dB frequency bandwidth of Pout, which is from 32 to 38.4 GHz. The harmonic rejection ratios of the frequency quadrupler are 16.5 ~ 25.9 dBc at the second-order harmonic and 31 ~ 45 dBc at the fundamental and third-order harmonics over the entire operating bandwidth. The core area occupies only 0.24 mm2.

Published
2021

47. COMPUTATIONAL INVESTIGATION OF NANOSCALE SEMICONDUCTOR DEVICES AND OPTOELECTRONIC DEVICES FROM THE ELECTROMAGNETICS AND QUANTUM PERSPECTIVES BY THE FINITE DIFFERENCE TIME DOMAIN METHOD (INVITED REVIEW)

Author

and Wenchao Chen, Huali Duan, Erping Li, Wen-Yan Yin, and Wenxiao Fang

Subjects
Physics, Radiation, Electromagnetics, business.industry, Finite-difference time-domain method, Optoelectronics, Semiconductor device, Electrical and Electronic Engineering, Condensed Matter Physics, business, Quantum, Nanoscopic scale
Published
2021

48. Efficient Analytical Model for the Transfer Impedance and Admittance of Noncoaxial/Twinax Braided–Shielded Cables

Author

Oussama Gassab, Liang Zhou, Wen-Yan Yin, and Sara Bouguerra

Subjects
Physics, FEKO, Admittance, Acoustics, 020206 networking & telecommunications, 02 engineering and technology, Method of moments (statistics), Condensed Matter Physics, Atomic and Molecular Physics, and Optics, law.invention, Inductance, law, Transmission line, Shielded cable, 0202 electrical engineering, electronic engineering, information engineering, Electrical and Electronic Engineering, Coaxial, Electrical impedance
Abstract

An efficient analytical model for the transfer impedance and admittance of a noncoaxial/twinax braided–shielded cable with apertures on its sheath is proposed by generalizing the old Vance's and Kley's formulas, and it is derived using the complex analyses with an appropriate conformal mapping. Therefore, such a noncoaxial cable is converted into a coaxial one which can be studied using the traditional multiconductor transmission line method. It is shown that the aperture inductance is related to the position of the inner conductor and the radial position of each aperture on its sheath. In addition, the modal domain analysis is performed to obtain the common-mode (CM) and differential-mode (DM) transfer impedance/admittance of the twinax braided–shielded cable, with CM and DM currents inside the inner conductors examined. The proposed model is validated by comparing the results with that obtained by the method of moments (MoM)-based commercial software FEKO. It is found that the uniform distribution of the apertures on the sheath reduces the induced DM current significantly

Published
2020

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