Design of 28/38 GHz Dual-Band Triangular-Shaped Slot Microstrip Antenna Array for 5G Applications

Rahayu, Yusnita; Hidayat, Muhammad Ibnu

doi:10.1109/tafgen.2018.8580487

Cited by 45 publications

(10 citation statements)

References 13 publications

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“…are desirable for 5G applications. Several works of literature have proposed dual-band 28/38 GHz antennas for mobile phones through several techniques [13][14][15][16][17][18][19][20][21][22]. The aim of this article is to design a dual band patch array antenna, for 5G mobile phone communication, with: high gain, radiation pattern beams characteristics, wide bandwidth, and a simple geometry which is formed by using the "Inverted-F" element.…”

Section: Antenna Geometrymentioning

confidence: 99%

Dual-Band 28/38 GHz Inverted-F Array Antenna for Fifth Generation Mobile Applications

Halaoui

Canale

Asselman

et al. 2020

The 14th International Conference on Interdisciplinarity in Engineering—INTER-Eng 2020

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The development of 5G (fifth generation) mobile communication systems was initiated to meet the expected need for higher data rates. In this article, a new 28/38 GHz dual-band “inverted-F” array antenna for 5G applications is proposed. This antenna can be integrated in OLEDs (Organic Light Emitting Diodes) panels which can be used both for lighting or display. This 5G antenna, composed of 32 elements, has the advantage of a dual-band and compact structure. Each element of the array antenna has the shape of an “inverted-F” antenna. This array antenna can cover the 28 GHz band (27.94–28.83 GHz) and the 38 GHz band (37.97–38.96 GHz) with mutual coupling between the elements less than −35 dB. The characteristics of the end fire radiation beams were obtained by employing an array of 32 “inverted-F” antenna elements on the upper and lower portions of the PCB (Printed Circuit Board). The suggested design has a gain of approximately 16.52 dB at 28.38 GHz and 15.35 dB at 38.49 GHz, which is suitable for 5G mobile communications.

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Section: Antenna Geometrymentioning

confidence: 99%

Dual-Band 28/38 GHz Inverted-F Array Antenna for Fifth Generation Mobile Applications

Halaoui

Canale

Asselman

et al. 2020

The 14th International Conference on Interdisciplinarity in Engineering—INTER-Eng 2020

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“…They have also been studied in several research categories [24]. The 28 GHz and 38 GHz are currently the most recommended band for the 5G system [25][26][27][28][29][30][31][32]. Meanwhile, other higher mm-wave bands of up to 120 GHz are recommended for the 6G system [13][14][15].…”

Section: Introductionmentioning

confidence: 99%

Key Challenges, Drivers and Solutions for Mobility Management in 5G Networks: A Survey

et al. 2020

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Ensuring a seamless connection during the mobility of various User Equipment (UE) will be one of the major challenges facing the practical implementation of the Fifth Generation (5G) networks and beyond. Several key determinants will significantly contribute to numerous mobility challenges. One of the most important determinants is the use of millimeter waves (mm-waves) as it is characterized by high path loss. The inclusion of various types of small coverage Base Stations (BSs), such as Picocell, Femtocell and drone-based BSs is another challenge. Other issues include the use of Dual Connectivity (DC), Carrier Aggregation (CA), the massive growth of mobiles connections, network diversity, the emergence of connected drones (as BS or UE), ultra-dense network, inefficient optimization processes, central optimization operation, partial optimization, complex relation in optimization operations, and the use of inefficient handover decision algorithms. The relationship between these processes and diverse wireless technologies can cause growing concerns in relation to handover associated with mobility. The risk becomes critical with high mobility speed scenarios. Therefore, mobility issues and their determinants must be efficiently addressed. This paper aims to provide an overview of mobility management in 5G networks. The work examines key factors that will significantly contribute to the increase of mobility issues. Furthermore, the innovative, advanced, efficient, and smart handover techniques that have been introduced in 5G networks are discussed. The study also highlights the main challenges facing UEs' mobility as well as future research directions on mobility management in 5G networks and beyond.

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“…From the need for 5G technology, it can be concluded that an antenna that has a wide bandwidth and high gain is needed. Previous research was carried out by [24]. Based on the simulation, the designed antenna has a thickness of 1.575 mm, with Duroid 5880 Rogers Substrate material with a dielectric constant εr = 2.2 and a tangent loss (tan δ) of 0,0009.…”

Section: Introductionmentioning

confidence: 99%

Design of A Dual-Band Microstrip Antenna for 5G Communication

Firdausi

Damayanti

Hakim

et al. 2021

JIAE

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The necessity for mobile communication devices is increased rapidly. Users expect to get very fast information access and data access without delay. The fifth-generation (5G) development in wireless mobile telecommunication technology promises capacity enhancement, ease connectivity, high efficiency, and high data rate transmission. The appropriate device should support this improvement of the technology. The antenna is one of the main devices to support the high data rate transmission. This paper proposed designing a dual-band rectangular patch antenna in 29 GHz and 38 GHz that supports 5G technology. This microstrip antenna is composed of 4 patch array elements to obtain higher gain. The material used for this microstrip antenna is RT Duroid 5880 with a dielectric constant of 2.2 and a thickness of 1.575 mm. Both measurement and simulation are confirmed that the 2×2 array microstrip antenna in 29 GHz and 38 GHz frequency have a return loss value of -12.5 dB and -16 dB, respectively. The bandwidth for both frequencies has a value of 4.5 GHz and 3.75 GHz.

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Design of 28/38 GHz Dual-Band Triangular-Shaped Slot Microstrip Antenna Array for 5G Applications

Cited by 45 publications

References 13 publications

Dual-Band 28/38 GHz Inverted-F Array Antenna for Fifth Generation Mobile Applications

Dual-Band 28/38 GHz Inverted-F Array Antenna for Fifth Generation Mobile Applications

Key Challenges, Drivers and Solutions for Mobility Management in 5G Networks: A Survey

Design of A Dual-Band Microstrip Antenna for 5G Communication

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