Bomson Lee scite author profile

Bomson Lee

5Publications

182Citation Statements Received

51Citation Statements Given

How they've been cited

239

178

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Affiliations

Kyung Hee University

Publications

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Dual-Band Circularly Polarized Microstrip RFID Reader Antenna Using Metamaterial Branch-Line Coupler

Jung

Lee

2012

IEEE Trans. Antennas Propagat.

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A dual-band circularly polarized aperture coupled microstrip RFID reader antenna using a metamaterial (MTM) branch-line coupler has been designed, fabricated, and measured. The proposed antenna is fabricated on a FR-4 substrate with relative permittivity of 4.6 and thickness of 1.6 mm. The MTM coupler is designed employing the provided explicit closed-form formulas. The dual-band (UHF and ISM) circularly-polarized RFID reader antenna with separate Tx and Rx ports is connected to the designed metamaterial (MTM) branch-line coupler. The maximum measured LHCP antenna gain is 6.6 dBic at 920 MHz (UHF) and RHCP gain is 7.9 dBic at 2.45 GHz (ISM). The cross-polar CP gains near broadside of the RFID reader antenna are approximately less than compared with the mentioned co-polar CP gains in both bands. The isolations between the two ports are about 25 dB and 38 dB, at 920 MHz and 2.45 GHz, respectively. The measured axial ratios are less than 0.7 dB in the UHF band (917-923 MHz) and 1.5 dB in the ISM band (2.4-2.48 GHz).

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Development of Long-Range UHF-band RFID Tag chip Using Schottky Diodes in Standard CMOS Technology

Tran

Lee

2007

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Inductively Coupled Compact RFID Tag Antenna at 910 MHz With Near-Isotropic Radar Cross-Section (RCS) Patterns

Ahn

Jang

Moon

et al. 2007

Antennas Wirel. Propag. Lett.

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In this article, a novel wideband wavelength conversion is demonstrated using a highly nonlinear fiber consisting of a fluorinedoped fiber that has a high delta core and surrounded by a deeply depressed ring as opposed to the use of photonic crystal fibers. The wavelength conversion range is from 1460 to 1640 nm, which covers the S-, C-and L-bands of the optical network. The interacting waves consist of an arrayed waveguide grating tuned dual-wavelength fiber laser output together with a tunable laser source signal. A four-wave-mixing conversion of efficiency of À20 dB is achieved within a 70 nm tuning range within a 3.9 dB fluctuation. An optical signal to noise ratio of 30 dB is also realized within the same tuning range.

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Design of Thin RC Absorbers Using a Silver Nanowire Resistive Screen

Lee¹,

Lee²

2016

Journal of electromagnetic engineering and science

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A resistive and capacitive (RC) microwave absorber with a layer thickness less than a quarter of a wavelength is investigated based on closed-form design equations, which are derived from the equivalent circuit of the RC absorber. The RC absorber is shown to have a theoretical 90% absorption bandwidth of 93% when the electrical layer thickness is 57 o (about λ 0/6). The trade-offs between the layer thickness and the absorption bandwidth are also elucidated. The presented formulation is validated by a design example at 3 GHz. The RC absorber is realized using a silver nanowire resistive rectangular structure with surrounding gaps. The measured 90% absorption bandwidth with a layer thickness of λ 0/8 is 76% from 2.3 GHz to 5.1 GHz in accordance with the theory and EM simulations. The presented design methodology is scalable to other frequencies. This is an Open-Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/ by-nc/3.0) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited. ⓒ

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Analysis of Magnetically Coupled Wireless Power Transmission for Maximum Efficiency

Kim

Lee²

2011

Journal of electromagnetic engineering and science

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We have proposed and analyzed an equivalent circuit for a magnetically coupled wireless power transmission (WPT) system between two loop resonators by considering its coupling coefficient and radiation-related parameters. A complete formulation is provided for all the necessary circuit parameters. The mechanism of radiation loss is sufficiently explained. The circuit and electromagnetic (EM) simulation results have been shown to be in good agreement. Based on the proposed circuit formulation, a specific load impedance for maximum WPT efficiency was found to exist. The proposed modeling of the WPT in terms of circuit characterizations provides sufficient insight into the problems associated with WPT. Ⅰ. IntroductionWe live in a world of wireless communication. A huge amount of information is wirelessly communicated between mobile terminals. Now, the increasing requirement for the wireless transfer of electric power is making wireless power transmission (WPT) technology increasingly important. Based on the analysis, they successfully lit a 60 W bulb at a distance of 7 feet (more than 2 meters) by using helical coils of high Q. The efficiency was reported to be 60 % at 9.9 MHz. Most of the papers related to WPT focus on the power transmission efficiency. The mechanism of radiation loss and the coupling coefficient have rarely been explained in detail. The radiation loss is surely the most crucial limiting factor in WPT and it warrants an in-depth analysis.In this paper, in order to investigate the mechanism of WPT in a more detail, we focus on the analysis of a WPT system using an equivalent circuit. Based on the equivalent circuit, key parameters-such as WPT efficiency and the radiation loss rate are properly defined and derived.Furthemore, a method for extracting both from electromagnetic (EM) simulations or measurements is proposed. Finally, the proposed modeling for WPT is validated by comparing the circuit and the EM simulations. Ⅱ. Analysis of an Equivalent Circuit for WPT using Two LoopsCommonly, WPT using magnetic coupling is realized using two resonant loops facing each other. One loop is connected to an AC power source and the other loop is connected to the load. Power is wirelessly transmitted from one loop to the other as a result of magnetic coupling between the two resonant structures with the same resonant frequency. Fig. 1 shows the equivalent circuit for a magnetically coupled WPT that considers radiation effects. V1 is the voltage source for the WPT system. R1 and R2 are the conductor loss resistances, R r1 and R r2 are the resistances accounting for radiation loss, and RL is the load resistance.L 1 and L 2 are the inductances, and C 1 and C 2 are the capacitances, for the first and second loops, respectively. M is the mutual inductance between the two loops. I1 and I 2 are the currents flowing on each loop.Using KVL's, we obtain

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Bomson Lee

Dual-Band Circularly Polarized Microstrip RFID Reader Antenna Using Metamaterial Branch-Line Coupler

Development of Long-Range UHF-band RFID Tag chip Using Schottky Diodes in Standard CMOS Technology

Inductively Coupled Compact RFID Tag Antenna at 910 MHz With Near-Isotropic Radar Cross-Section (RCS) Patterns

Design of Thin RC Absorbers Using a Silver Nanowire Resistive Screen

Analysis of Magnetically Coupled Wireless Power Transmission for Maximum Efficiency

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