Cheol Yoon scite author profile

Choi

Lee

et al. 2007

covers the required bandwidth . Figure 3 studies the effects of the strip length L 2 of the C-shaped strip on the impedance matching of the proposed antenna. Measured results of the return loss for the case with various strip lengths of L 2 ϭ 5 to 7 mm are presented. It is seen that, by increasing the strip length L2, the antenna's lower band can be excited at lower frequencies. For the upper band, however, smaller effects of the strip length L 2 are seen. From the results obtained, the strip length L 2 for the printed meander antenna is selected to be 7 mm.The radiation patterns in the orthogonal x-y, y-z planes at 2.45, 5.25, and 5.8 GHz are shown in Figure 4, respectively. The measured results show good similar omnidirectional radiation in the azimuth plane (x-y plane), especially in the higher band, and conical radiation in the elevation plane (y-z plane). Figure 5 presents the measured peak gains of the proposed compact monopole antenna across two operating bands. The measured peak antenna gains for the operating frequencies across 2.4/5-GHz bands are measured to be 2.7 and 3.1 dBi, respectively. Gain variations of 2.2-2.7 dBi in the 2.4-GHz band and 2.0 -3.0 dBi in 5-GHz band are obtained. CONCLUSIONA novel multiband printed monopole antenna for WLAN communication has been proposed. By using a simple configuration, the prototype of the antenna has achieved satisfactory multiband performances, which obtains impedance bandwidths of 2.39 -2.52 and 5.12-7.12 GHz, the measured gains of 2.0 and 3.1 dBi, respectively. Also good similar omnidirectional radiation patterns in the azimuth plane in higher band are achieved. It is of low cost, light weight, and has a compact size of only 11.5 ϫ 8.5 mm 2 . These features are very suitable for multiband wireless applications. ABSTRACT: This article presents the design and fabrication of a short-pin dual-band E-shaped microstrip patch antenna for applicationin a 2.630 -2.655 GHz band satellite-DMB with a 5.725-5.825 GHz band wireless LAN. The prototype consist of a short-pin and E-shaped patch. To obtain sufficient bandwidth in VSWR Ͻ 2, an air layer is inserted between the ground plane and the substrate. A small short-pin patch that has a dual-band characteristic is used. Important design parameters are the slot's existence, length, the air-gap's height, the feed point's position, and the short-pin's existence and point position. From these optimized parameters, an E-shaped antenna is fabricated and measured. The measured results of the fabricated antenna are obtained individually at 200 and 700 MHz bandwidths in VSWR Ͻ 2 referenced to the center frequency, and the individual gain at 8.79 and 10.26 dBi. The experimental 3 dB beam width is shown to be broad across the passFigure 5 Measured antenna gains for the proposed antenna: (a) 2.4-GHz band; (b) 5-GHz band. [Color figure can be viewed in the online issue, which is available at www.interscience.wiley.com]

A reconfigurable antenna using varactor diode for LTE MIMO applications

Yoon¹,

Hwang²,

Lee³

et al. 2013

In this article, a mobile embedded antenna having tunable capacitance is proposed and the validity of the proposed solution was proved through design, fabrication, and measurement.The antenna can be applied to long‐term evolution (LTE) as well as DCS/PCS/WCDMA bands being currently used. Antennas for the 4G mobile service are required to expand its bandwidth so that it includes both LTE band and other service bands. However, it is hard to obtain low‐band characteristic due to the limited space for antenna in terminals. The proposed antenna consists of two planar inverted F antennas that are orthogonally arranged. Two radiators should be designed to have equal or enhanced isolation (S21) of lower than −15 dB. To meet this requirement, a varactor diode SMV2109 (skyworks corp.) was used to make the operation frequency of low‐band tunable. With the optimized parameters, the antenna was fabricated and measured and the results have been compared with the simulated result. The antenna satisfied with operation frequency and performance for both low‐band and high‐band, and measured performance of the antenna fabricated with optimized parameters is compared and analyzed with the simulation results. © 2013 Wiley Periodicals, Inc. Microwave Opt Technol Lett 55:1141–1145, 2013; View this article online at wileyonlinelibrary.com. DOI 10.1002/mop.27479

Broadband planar antenna with T‐shaped strip and capacitively coupled shorted strip

Kim

et al. 2011

This letter describes a broadband planar antenna embedded in LTE700/GSM handheld terminals. The antenna consists of a T‐shaped strip fed by a 50‐Ω coaxial cable and a shorted strip excited by capacitive coupling. The capacitively coupled shorted strip shows the resonance at the lower frequency band, and the T‐shaped strip presents good matching at the higher frequency band, because the characteristics of input impedance are affected by the capacitive coupling. The proposed antenna was simulated and fabricated. The measured bandwidth based on 3:1 VSWR was 0.62–1.53 GHz, which covers the frequencies used for LTE700, GSM800/850/900 mobile communications as well as the military applications. This antenna would be also useful for broadband wireless communications using the technique such as software‐defined radio or cognitive radio. © 2011 Wiley Periodicals, Inc. Microwave Opt Technol Lett, 2011; View this article online at wileyonlinelibrary.com. DOI 10.1002/mop.26211

A planar CPW‐fed slot antenna on thin substrate for dual‐band operation of WLAN applications

Lee

Kang³

et al. 2009

A compact five-pole UWB bandpass filter at P-band has been presented in this letter. The filter is designed with five shunt short-circuited stubs separated by connecting lines. The stubs and the connecting lines are folded to realize a compact size. Their physical dimensions are precisely determined by EM simulations. The filter is accurately designed and fabricated. Excellent agreements between the theoretical, simulated, and experimental responses are obtained and demonstrated.

A spiral‐shaped monopole antenna for quad‐band operation of mobile handsets

Park

Kang

et al. 2008

This article presents the design and fabrication of a quad‐band spiral‐shaped monopole antenna for application in a GPS (1575 ± 10 MHz)/DCS (1710–1880 MHz)/PCS (1850–1990 MHz) with a UMTS (1920–2170 MHz) band. To obtain sufficient bandwidth in VSWR < 2, an air layer is inserted between the ground plane and the substrate. A spiral‐shaped monopole antenna that has a quad‐band characteristic is used. Important design parameters are the spiral radiator gap's width and length, the air‐gap's height, and the feed point's position. From these optimized parameters, a spiral‐shaped monopole antenna is fabricated and measured. The measured results of the fabricated antenna are obtained from all bands at 940 MHz bandwidths in VSWR < 2 referenced to the center frequency, and the individual gain at 2.2 dBi, 2.5 dBi, 2.6 dBi, and 2.6 dBi. The experimental 3 dB beam width is shown to be broad across the pass band in the E‐plane, and 74°, 68°, 64°, and 60°, respectively. © 2008 Wiley Periodicals, Inc. Microwave Opt Technol Lett 50: 2860–2863, 2008; Published online in Wiley InterScience (www.interscience.wiley.com). DOI 10.1002/mop.23810