Your search keyword '"Jung, Kyung-Young"' showing total 15 results

1. Surface boundary condition (SBC)-based FDTD formulations for lossy dispersive media

Author

Kim, Yong-Jin and Jung, Kyung-Young

Published

2024

2. Accurate and Efficient Finite-Difference Time- Domain Formulation of Dusty Plasma.

Author

Kim, Yong-Jin and Jung, Kyung-Young

Subjects

*DUSTY plasmas, *DUST

Abstract

The finite-difference time-domain (FDTD) method has been widely used for the electromagnetic analysis of complex dispersive media. The shift-operator (SO)-FDTD or auxiliary differential equation (ADE)-FDTD formulation has been mainly employed for dusty plasma. Each FDTD formulation has its pros and cons. SO-FDTD is accurate but not computationally efficient. ADE-FDTD needs fewer computational resources, but its accuracy is poor. Here, we propose an accurate and efficient FDTD formulation for dusty plasma, based on the bilinear transform (BT). We perform a comprehensive study on the numerical permittivity and the computational efficiency for three FDTD formulations. Numerical examples are employed to illustrate that the proposed BT-FDTD outperforms the previously reported FDTD formulations for dusty plasma. In addition, based on the proposed BT-FDTD simulations, the effect of dust particles on EM wave propagation is investigated in the GHz band and the THz band. [ABSTRACT FROM AUTHOR]

Published

2021

3. Numerical Stability and Accuracy of CCPR-FDTD for Dispersive Medi.

Author

Choi, Hongjin, Baek, Jae-Woo, and Jung, Kyung-Young

Subjects

FINITE difference time domain method, FINITE difference method, NUMERICAL analysis, TIME-domain analysis, MATHEMATICAL models

Abstract

The complex-conjugate pole-residue (CCPR) model has been popularly adopted because CCPR-finite-difference time domain (FDTD) can reduce the memory requirement with the help of complex conjugate property of auxiliary variables. To fully utilize CCPR-FDTD, it is of great necessity to investigate its numerical stability since the FDTD method is conditionally stable. Nonetheless, the numerical stability conditions of CCPR-FDTD have not been studied because its derivation is not straightforward. In this communication, the numerical stability conditions of CCPR-FDTD are systematically derived by combining the von Neumann method with Routh–Hurwitz criterion. It is found that the numerical stability conditions of CCPR-FDTD are the same as those of the modified Lorentz-FDTD with bilinear transform. Moreover, the numerical accuracy of CCPR-FDTD is studied, and numerical examples are employed to validate this work. [ABSTRACT FROM AUTHOR]

Published

2020

4. Numerical Study on the Feasibility of a 24 GHz ISM-Band Doppler Radar Antenna for Near-Field Sensing of Human Respiration in Electromagnetic Aspects.

Author

Park, Seungyong, Kim, Sungpeel, Kim, Dong Kyoo, Choi, Jaehoon, and Jung, Kyung-Young

Subjects

RADAR antennas, DOPPLER radar, ANTENNA radiation patterns, DOPPLER effect, RESPIRATION

Abstract

The feasibility study of a 24 GHz industrial, scientific, and medical (ISM) band Doppler radar antenna in electromagnetic aspects is numerically performed for near-field sensing of human respiration. The Doppler radar antenna consists of a transmitting (Tx) antenna and a receiving (Rx) antenna close to the human body for a wearable device. The designed slot-type Doppler radar antenna is embedded between an RO4350B superstrate and an FR-4 substrate. To obtain the higher radiation pattern of the antenna towards the human body, a ground plane reflector is placed underneath the substrate. The measured −10 dB reflection coefficient (S11) bandwidth is 23.74 to 25.56 GHz and the mutual coupling (S21) between Tx and Rx antennas is lower than −30 dB at target frequencies. The Doppler radar performance of the proposed Doppler radar antenna is performed numerically by investigating the signal returned from the human body. The Doppler effect due to human respiration is investigated through the I/Q and arctangent demodulation of the returned signal. According to the results, the phase variation of the returned signal is proportional to the displacement of the body surface, which is about 0.8 rad in accordance with 1 mm displacement. The numerical experiments indicate that the proposed Doppler radar antenna can be used for near-field sensing of human respiration in electromagnetic aspects. [ABSTRACT FROM AUTHOR]

Published

2020

5. Wideband UHF Antenna for Partial Discharge Detection.

Author

Cui, Zhen, Park, Seungyong, Choo, Hosung, and Jung, Kyung-Young

Subjects

UHF antennas, PARTIAL discharges, ANTENNA design, NEAR-fields, CURRENT transformers (Instrument transformer)

Abstract

This paper presents a ultra-high frequency (UHF) antenna for partial discharge (PD) detection and the antenna sensor can be used near a conducting ground wire. The proposed UHF antenna has advantages of easy setup and higher-frequency detection over the high-frequency current transformer (HFCT) sensor. First, a variety of loop-shaped antennas are designed to compare each near field coupling capability. Then, a new UHF antenna is designed based on the loop-shaped antenna, which has the best near field coupling capability. Finally, the proposed UHF antenna is fabricated and measured. It provides a wide impedance bandwidth of 760 MHz (740–1500 MHz). Its simple setup configuration and wide bandwidth frequency response in the UHF band can provide a more efficient means for PD detection. [ABSTRACT FROM AUTHOR]

Published

2020

6. Comprehensive Study on Numerical Aspects of Modified Lorentz Model-Based Dispersive FDTD Formulations.

Author

Choi, Hongjin, Baek, Jae-Woo, and Jung, Kyung-Young

Subjects

ELECTRIC displacement, WAVE analysis, ELECTROMAGNETIC interactions, DISPERSIVE interactions, FINITE difference method

Abstract

Finite-difference time domain (FDTD) has been widely used to analyze electromagnetic wave interaction with dispersive media. It is of great necessity to incorporate a dispersion model into FDTD formulation for electromagnetic wave analysis of dispersive media. Recently, it was reported that the modified Lorentz model can cover Debye, Drude, Lorentz, critical point, and quadratic complex rational function models. In this work, it is illustrated that the modified Lorentz model can also cover the complex-conjugate pole-residue model which is one of the most popular dispersion models. Modified Lorentz-based dispersive FDTD has not been thoroughly studied, especially for numerical aspects. In this work, we investigate auxiliary differential equation (ADE)-FDTD formulations for the modified Lorentz model based on electric flux density (D), current (J), or polarization (P). We perform a comprehensive study on memory requirement, the number of arithmetic operations, numerical stability, and numerical permittivity for the above three ADE-FDTD formulations. In addition, the bilinear transformation (BT) is incorporated into modified Lorentz-based FDTD formulations and it will be shown that the utilization of the BT can lead to better performance in terms of numerical stability and numerical accuracy. Numerical examples are used to demonstrate our work. [ABSTRACT FROM AUTHOR]

Published

2019

7. Scattering Analysis of Modulated Corrugations in a Conducting Circular Cylinder and Study of RCS Reduction.

Author

Lee, Sangsu, Jung, Kyung-Young, Choo, Hosung, and Park, Yong Bae

Subjects

*RADAR cross sections, *EIGENFUNCTION expansions, *FOURIER transforms, *SCATTERING (Mathematics), *ELECTROMAGNETIC wave scattering

Abstract

In this communication, an electromagnetic boundary-value problem of modulated transverse corrugations in an infinite conducting circular cylinder is rigorously solved based on the Fourier transform, eigenfunction expansion, and the mode matching method. Radar cross section (RCS) of the modulated transverse corrugations is represented in the series form. Computation is performed to analyze scattering characteristics while varying depth, width, and period of the corrugations and to investigate the excitation of surface waves and concomitant RCS reduction. [ABSTRACT FROM AUTHOR]

Published

2019

8. Newmark-FDTD Formulation for Modified Lorentz Dispersive Medium and Its Equivalence to Auxiliary Differential Equation-FDTD with Bilinear Transformation.

Author

Choi, Hongjin, Cho, Jeahoon, Park, Yong Bae, and Jung, Kyung-Young

Subjects

FINITE difference time domain method, MATHEMATICAL equivalence, BILINEAR forms, THEORY of wave motion, CRITICAL point (Thermodynamics), PERMITTIVITY, INVERSE scattering transform

Abstract

The finite-difference time-domain (FDTD) method has been popularly utilized to analyze the electromagnetic (EM) wave propagation in dispersive media. Various dispersion models were introduced to consider the frequency-dependent permittivity, including Debye, Drude, Lorentz, quadratic complex rational function, complex-conjugate pole-residue, and critical point models. The Newmark-FDTD method was recently proposed for the EM analysis of dispersive media and it was shown that the proposed Newmark-FDTD method can give higher stability and better accuracy compared to the conventional auxiliary differential equation- (ADE-) FDTD method. In this work, we extend the Newmark-FDTD method to modified Lorentz medium, which can simply unify aforementioned dispersion models. Moreover, it is found that the ADE-FDTD formulation based on the bilinear transformation is exactly the same as the Newmark-FDTD formulation which can have higher stability and better accuracy compared to the conventional ADE-FDTD. Numerical stability, numerical permittivity, and numerical examples are employed to validate our work. [ABSTRACT FROM AUTHOR]

Published

2019

9. High-Gain Waveguide-Fed Circularly Polarized Spidron Fractal Aperture Antenna.

Author

Trinh-Van, Son, Thi, Thuy Nguyen, Yang, Youngoo, Lee, Kang-Yoon, Jung, Kyung-Young, and Hwang, Keum Cheol

Subjects

APERTURE antennas, SUBSTRATE integrated waveguides, ANTENNA radiation patterns, CIRCULAR polarization

Abstract

A high-gain rectangular waveguide-fed aperture antenna that uses a Spidron fractal structure to produce circular polarization is proposed. The antenna consists of a Spidron fractal aperture etched onto the ground plane of a dielectric substrate that is directly excited by a WR (Waveguide Rectangular)-90 waveguide-to-coax adapter. A superstrate was implemented at an appropriate distance above the antenna to enhance the broadside gain significantly. An antenna prototype was fabricated and tested to validate the design. The measured impedance bandwidth for | S 11 | ≤ −10 dB is 9.89–11.58 GHz (15.74%). The corresponding measured 3 dB axial ratio (AR) bandwidth is 10.68–11.00 GHz (2.95%), and within the measured 3 dB AR bandwidth, a maximum realized gain of 9.59 dBic is achieved. The radiation patterns of the proposed antenna are presented and discussed. [ABSTRACT FROM AUTHOR]

Published

2019

10. Radiation from a Cavity-Backed Circular Aperture Array Antenna Enclosed by an FSS Radome.

Author

Kim, Jihyung, Lee, Sangsu, Shin, Hokeun, Jung, Kyung-Young, Choo, Hosung, and Park, Yong Bae

Subjects

CIRCULAR aperture, ANTENNA arrays, FREQUENCY selective surfaces

Abstract

Radiation from a cavity-backed circular aperture array antenna enclosed by a frequency selective surface (FSS) radome is studied using the hybrid analysis method, by combining the mode matching method, the ray tracing technique, and Huygens's principle. The equivalent magnetic surface currents on the apertures are derived from the aperture electromagnetic fields, which are calculated based on the mode matching method. The rays are generated from the equivalent magnetic surface currents and used to analyze the FSS radome based on the ray tracing technique. After being obtained from both the mode matching method and the ray tracing technique, electromagnetic fields on an outermost radome are transformed into the equivalent electric and magnetic surface currents using Huygens's principle. The radiated fields are computed from the equivalent surface currents and compared with the measured data. [ABSTRACT FROM AUTHOR]

Published

2018

11. Robust Design of 3D-Printed 6–18 GHz Double-Ridged TEM Horn Antenna.

Author

Lee, Sungwoo, Yang, Youngoo, Lee, Kang-Yoon, Jung, Kyung-Young, and Hwang, Keum Cheol

Subjects

HORN antennas, THREE-dimensional printing, TRANSMISSION electron microscopy

Abstract

A robust design of a 3D-printed 6–18 GHz double-ridged TEM horn antenna is proposed in this paper. The designed TEM horn antenna has two parts: an adaptor and a horn aperture. The adaptor is realized using a double-ridged waveguide to extend the operating bandwidth of the dominant mode (TE10 mode). Meanwhile, the horn aperture section is implemented in an exponentially tapered configuration to match the impedance of the double-ridged waveguide with the intrinsic impedance. The performance of the initially designed antenna shows that the reflection coefficient and gain levels are less than −13 dB and greater than 5.5 dBi within the 6–18 GHz band, respectively. The initial design was well done, but the noise factors that may occur during the manufacturing process were not taken into account. To design an antenna considering these noise factors, the parameters of the initial design are optimized by a novel robust design method also proposed in this paper. The robustness of the antenna optimized by the proposed method is approximately 12.4% higher than that of the initial antenna. The validity of the proposed method was tested by fabricating the antenna. A prototype of the optimized antenna with the proposed robust design method is fabricated using a 3D printer with a stereolithographic apparatus attached, and the surface of the frame is covered by a nano-silver plating. The measured results of the fabricated antenna are in good agreement with the simulation results over the operating band. The measured −10 dB reflection coefficient bandwidth of the antenna can cover 6–18 GHz. In addition, the measured gain ranges from 4.42 to 10.75 dBi within the 6–18 GHz band. [ABSTRACT FROM AUTHOR]

Published

2018

12. Numerical study of electromagnetic wave propagation characteristics in collapsed building for rescue radar applications.

Author

Kwon, Kyeol, Kim, Dong‐Kyoo, Choi, Youngwoo, Cho, Jeahoon, and Jung, Kyung‐Young

Subjects

ELECTROMAGNETIC wave propagation, RADAR, RESCUE work, EARTHQUAKE resistant design, NUMERICAL analysis

Abstract

Since the Gyeongju earthquakes in 2016, there have been increased research interests in the areas of seismic design, building collapse, and rescue radar applications in Korea. Ground penetrating radar (GPR) is a nondestructive electromagnetic method that is used for underground surveys. To properly design ground penetrating radar that detects buried victims precisely, it is important to study electromagnetic wave propagation channel characteristics in advance. This work presents an electromagnetic propagation environment analysis of a trapped victim for GPR applications. In this study, we develop a realistic collapse model composed of layered reinforced concrete and a victim positioned horizontally. In addition, the effects of rebars and the distance between the radar antenna and target are investigated. The numerical analysis presents the electromagnetic wave propagation characteristics, including amplitude loss and phase difference, in the 450‐MHz and 1,500‐MHz frequency band, and it shows the electric field distribution in the environment. [ABSTRACT FROM AUTHOR]

Published

2018

13. Mode Matching Analysis of Via-Plate Capacitance in Multilayer Structures With Finite Plate Thickness.

Author

Park, Hyun Ho, Hwang, Chulsoon, Jung, Kyung-Young, and Park, Yong Bae

Subjects

ELECTRIC capacity, MODE matching, ELECTROSTATICS, BOUNDARY value problems, INTEGRATED circuits, ELECTRIC potential

Abstract

In this paper, an analytical method for evaluation of via-plate capacitance including finite plate thickness in multilayer structures is proposed. An electrostatic boundary-value problem associated with a via in parallel plates is solved based on the Hankel transform and mode matching method, and thereby a fast-converging series-form expression for the via-plate capacitance is derived. The effect of finite plate thickness is taken into account by adopting the mode matching method instead of imposing an artificial perfect magnetic conductor boundary as in the previous works. We perform some computations to show the behaviors of the capacitance in terms of the via geometry, and they are validated through comparison with a static/quasi-static simulation, full-wave electromagnetic simulation, and the previous analytical solutions of via capacitance. [ABSTRACT FROM AUTHOR]

Published

2015

14. FDTD Dispersive Modeling With High-Order Rational Constitutive Parameters.

Author

Ha, Sang-Gyu, Cho, Jeahoon, Kim, Eun-Ki, Park, Yong Bae, and Jung, Kyung-Young

Subjects

FINITE difference time domain method, NUMERICAL analysis, CURVE fitting, COMPUTATIONAL complexity, MATHEMATICAL models

Abstract

In this work, we present a dispersive finite-difference time-domain (FDTD) algorithm using a four-pole complex rational function (CRF). For the sake of a better curve fitting of the four-pole CRF dispersion model, we use a particle swarm optimization technique. We also discuss an efficient memory storage strategy using a state-space approach. The numerical aspects of four-pole CRF-FDTD, the numerical accuracy and the numerical stability, are investigated in detail. Numerical examples are used to validate four-pole CRF-FDTD and numerical stability issues are discussed in detail. We also discuss the computational accuracy and the computational efficiency of an arbitrary $N$-pole CRF-FDTD. [ABSTRACT FROM PUBLISHER]

Published

2015

15. Numerical Stability of Modified Lorentz FDTD Unified From Various Dispersion Models.

Author

Park J and Jung KY

Abstract

The finite-difference time-domain (FDTD) method has been widely used to analyze electromagnetic wave propagation in complex dispersive media. Until now, there are many reported dispersion models including Debye, Drude, Lorentz, complex-conjugate pole-residue (CCPR), quadratic complex rational function (QCRF), and modified Lorentz (mLor). The mLor FDTD is promising since the mLor dispersion model can simply unify other dispersion models. To fully utilize the unified mLor FDTD method, it is of great importance to investigate its numerical stability in the aspects of the original dispersion model parameters. In this work, the numerical stability of the mLor FDTD formulation unified from the aforementioned dispersion models is comprehensively studied. It is found out that the numerical stability conditions of the original model-based FDTD method are equivalent to its unified mLor FDTD counterparts. However, when unifying the mLor FDTD formulation for the QCRF model, a proper Courant number should be used. Otherwise, its unified mLor FDTD simulation may suffer from numerical instability, different from other dispersion models. Numerical examples are performed to validate our investigations.

Published

2021