A 24/60GHz dual-band millimeter-wave on-chip monopole antenna fabricated with a 0.13-&amp;#x03BC;m CMOS technology

Huang, Jie‐Huang; Wu, Jin‐Wei; Chiou, Yi-Lin; Jou, Christina F.

doi:10.1109/iwat.2009.4906869

Cited by 11 publications

(3 citation statements)

References 6 publications

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“…However, the dual-band antenna at the MMW frequency is still very less explored. Few of the reported works are: 58/77 GHz antenna using flip-chip assembly [8], fractal bowtie antenna using movable plate for 60/77 GHz [9], 40/60 GHz SRR-based antenna [10], and 24/60 GHz antenna using the 0.1 µm standard complementary metal-oxide semiconductor (CMOS) process [11]. Most of these reported MMW dual-band antenna techniques require sophisticated fabrication techniques/equipment and high level of precision which makes them complex and cost inefficient.…”

Section: Introductionmentioning

confidence: 99%

CPW-fed concurrent, dual band planar antenna for millimeter wave applications

Agarwal

Singh

2018

Int. J. Microw. Wireless Technol.

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In recent years, millimeter wave (MMW) has received tremendous interest among researchers, which offers systems with high data rate communication, portability, and finer resolution. The design of the antenna at MMWs is challenging as it suffers from fabrication and measurement complexities due to associated smaller dimensions. Current state-of-the-art MMW dual-band antenna techniques demand high precision fabrication, which increases the overall cost of the system. Henceforth, the design of an MMW antenna with fabrication and measurement simplicity is quite challenging. In this paper, a simple coplanar waveguide (CPW) fed single-band MMW antenna operating at 94 GHz (W band) and a dual-band MMW antenna operating concurrently at 60 GHz (V band) and 86 GHz (E band) have been designed, fabricated, and measured. A 50 Ω CPW-to-microstrip transition has also been designed to facilitate probe measurement compatibility and to provide proper feeding to the antenna. The fabricated single frequency 94 GHz antenna shows a fractional bandwidth of 11.2% andE-plane (H-plane) gain 6.17 dBi (6.2 dBi). Furthermore, the designed MMW dual-band antenna shows fractional bandwidth: 2/6.4%, andE-plane (H-plane) gain: 7.29 dBi (7.36 dBi)/8.73 dBi (8.68 dBi) at 60/86 GHz, respectively. The proposed antenna provides a simple and cost-effective solution for different MMW applications.

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Section: Introductionmentioning

confidence: 99%

CPW-fed concurrent, dual band planar antenna for millimeter wave applications

Agarwal

Singh

2018

Int. J. Microw. Wireless Technol.

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“…Multiband antennas have massive applications in millimeter band applications. A various techniques in the literature have been developed for multiband microstrip antennas as in [4][5][6][7][8][9][10][11][12]. For instance, a multilayer GaAs is described in [4] to achieve a multiband antenna operating at 35 GHz.…”

Section: Introductionmentioning

confidence: 99%

“…For instance, a multilayer GaAs is described in [4] to achieve a multiband antenna operating at 35 GHz. In [5], two bands with less than 1.2% bandwidth with gains of -9 dBi and 1 dBi at 24 GHz band and 60 GHz band respectively is presented. A dual band antenna at 41 GHz / 52.2 GHz using a meta-resonator with pair of split ring resonators is introduced in [6] with bandwidth of 2 %, gain of 3.76 dBi, and efficiency of 71%.…”

Section: Introductionmentioning

confidence: 99%

Omni-directional Dual-Band Patch Antenna for the LMDS and WiGig Wireless Applications

Ibrahim¹

2018

Adv. sci. technol. eng. syst. j.

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In this paper an omnidirectional dual band monopole antenna at 28 GHz and 60 GHz which is fit for indoor and outdoor wireless applications is developed. The proposed antenna consists of two rectangular patches with a T folded patch. The design, analysis, and optimization processes through this article are executed by the numerical method, Finite Element Method (FEM) and verified with another numerical method, Finite integration Technique (FIT). Good agreement between the results by these two simulators is obtained. The proposed antenna has achieved dual bands with omnidirectional patterns. The first band at 28 GHz is extended from 27.5 GHz to 28.958 GHz with 5.1 % bandwidth and total efficiency of more than 93% along the entire band which serves the LMDS band. The second band at 60 GHz is extended from 45.2 GHz to 84.4 GHz which serves the WiGig band with bandwidth of 60.6% and total efficiency of 85.5% along the entire band. The proposed antenna performance makes it a good candidate for the fifth generation (5G) applications.

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Design and implementation of A 24‐/60‐GHz dual‐band monopole meander‐line planar CMOS antenna

Lin

et al. 2012

Micro & Optical Tech Letters

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This article describes the design and implementation of a monolithic 24/60‐GHz dual‐band millimeter‐ wave planar CMOS antenna.A finite element method‐based 3D full‐wave electromagnetic solver, high‐frequency structure simulator, is used to simulate and optimize the performance of the antenna. The feeding network adopts the coplanar waveguide (CPW) structure, so the on‐chip antenna can be flip‐chip‐bonded to a CPW RO4003 conversion board for complete radiation‐pattern measurement. The main structure uses meander‐line to save chip area. Dual‐band operation is achieved by providing two major current paths for radiation. The measured input voltage standing wave ratio of the on‐chip dual‐band antenna is smaller than 2 for frequencies 10–25.7 and 58.4–66.6 GHz. The measured maximum power gain is −7 dB at 60 GHz, one of the highest power gains ever reported for a CMOS antenna at 60 GHz. The chip area is only 1 × 0.75 mm2, i.e., 0.75 mm2, excluding the periphery conductor and the dummy metals for metal density requirement. © 2012 Wiley Periodicals, Inc. Microwave Opt Technol Lett 54:1731–1737, 2012; View this article online at wileyonlinelibrary.com. DOI 10.1002/mop.26916

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A 24/60GHz dual-band millimeter-wave on-chip monopole antenna fabricated with a 0.13-μm CMOS technology

Cited by 11 publications

References 6 publications

CPW-fed concurrent, dual band planar antenna for millimeter wave applications

CPW-fed concurrent, dual band planar antenna for millimeter wave applications

Omni-directional Dual-Band Patch Antenna for the LMDS and WiGig Wireless Applications

Design and implementation of A 24‐/60‐GHz dual‐band monopole meander‐line planar CMOS antenna

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