Your search keyword '"Fifth generation (5G)"' showing total 520 results

1. Machine learning based on patch antenna design and optimization for 5 G applications at 28GHz

Author

Rana, Md․Sohel, Rabiul Islam, Sheikh Md․, and Sarker, Sanjukta

Published

2024

2. Handover decision with multi-access edge computing in 6G networks: A survey

Author

Jahandar, Saeid, Shayea, Ibraheem, Gures, Emre, El-Saleh, Ayman A., Ergen, Mustafa, and Alnakhli, Mohammad

Published

2025

3. 5G Wireless Technology Throughput Prediction Using Ensemble Machine Learning Approach

Author

Sharma, Abhilasha, Talluri, Salman Raju, Pandit, Shweta, Filipe, Joaquim, Editorial Board Member, Ghosh, Ashish, Editorial Board Member, Khurana, Meenu, editor, Thakur, Abhishek, editor, Kantha, Praveen, editor, Shieh, Chin-Shiuh, editor, and Shukla, Rajesh K., editor

Published

2025

4. Pattern Diversity mm-Wave Rectangular Ring Shaped MIMO Antenna for 5G Communication and Internet of Things Applications

Author

Nahar, Tapan, Das, Vishal, Rawat, Sanyog, Anguera, Jaume, Kacprzyk, Janusz, Series Editor, Gomide, Fernando, Advisory Editor, Kaynak, Okyay, Advisory Editor, Liu, Derong, Advisory Editor, Pedrycz, Witold, Advisory Editor, Polycarpou, Marios M., Advisory Editor, Rudas, Imre J., Advisory Editor, Wang, Jun, Advisory Editor, Rawat, Sanyog, editor, Kumar, Arvind, editor, Raman, Ashish, editor, Kumar, Sandeep, editor, and Pathak, Parul, editor

Published

2025

5. Design of H-Shaped Slotted Microstrip Patch Antenna at 28 GHz for 5G Communication

Author

Chhaule, Nupur, Mandal, Sudip, Koley, Chaitali, Kacprzyk, Janusz, Series Editor, Gomide, Fernando, Advisory Editor, Kaynak, Okyay, Advisory Editor, Liu, Derong, Advisory Editor, Pedrycz, Witold, Advisory Editor, Polycarpou, Marios M., Advisory Editor, Rudas, Imre J., Advisory Editor, Wang, Jun, Advisory Editor, Lin, Frank, editor, Pastor, David, editor, Kesswani, Nishtha, editor, Patel, Ashok, editor, Bordoloi, Sushanta, editor, and Koley, Chaitali, editor

Published

2025

6. Performance Analysis of Vertical Handover Algorithm on 5G-IEEE 802.11ah Traffic Offload with Changes in Number of Nodes and Mobility.

Author

Riza, Tengku Ahmad, Arifin, Ajib S., and Gunawan, Dadang

Subjects

*COMPUTER network traffic, *END-to-end delay, *5G networks, *QUALITY of service, *WIRELESS Internet

Abstract

Mobile data traffic is currently experiencing a significant and continuous increase, with no signs of decrease. This trend can impact the use of 5G mobile networks, which require high speeds and excellent Quality of Service (QoS). Therefore, service providers are expected to meet the growing demands of users and prevent connection or call failures. To address the issue as a contribution, this study proposed the use of traffic offloading integrated with vertical handover algorithm by transferring data flow from cellular to WiFi network. This study aimed to simulate algorithm under four different scenarios, namely distance, bandwidth, transmit power, and system loss. These scenarios were analyzed with respect to the influence of mobility and number of nodes, considering various QoS parameters, namely Received Signal Strength Indicator (RSSI), data rate, power consumption, throughput, and end-to-end delay rate. The simulation results showed an improvement in QoS, particularly in the RSSI parameter. The four scenarios showed that the RSSI value remained consistent despite mobility and number of nodes caused by multiple iterations of offloading between the 5G and WiFi networks. In terms of data rate parameter, the scenarios consistently showed that algorithm prioritized the highest data rate between the networks, even with user mobility conditions. It also consistently used the network with the lowest value as regards power consumption, while prioritizing the highest value in throughput. In terms of the end-to-end delay rate parameter, algorithm used the smallest value between the 5G and the WiFi networks. [ABSTRACT FROM AUTHOR]

Published

2025

7. Fifth‐generation fractal antenna design based on the Koch Snowflake geometry. A fractal theory application.

Author

Paun, Maria‐Alexandra, Nichita, Mihai‐Virgil, Paun, Vladimir‐Alexandru, and Paun, Viorel‐Puiu

Subjects

*ANTENNA design, *ANTENNAS (Electronics), *SNOWFLAKES, *FRACTALS, FRACTAL dimensions

Abstract

The projection of fifth‐generation (5G) fractal antennas and their advantageous geometry are examined. The fact that fractal‐shaped antennas based on Koch Snowflake geometry are suitable for higher frequencies was shown above all. By the instrumentality of this technology, which aims to serve a large number of subscribers by implementing revolutionary devices (e.g. Massive MIMO, beam‐forming, high‐performance processors, etc.), it is possible to obtain multiple facilities. Fractal geometrics forms have been made using fractalKoch function from MATLAB R2018b, having as initial characteristic the series of successful repetitions. 2D and 3D characteristics of directivity at the values of 455, 465, 755.5 and 789.5 MHz (designed antennas), for two, three respectively four iterations of Koch's Snowflake fractals have been highlighted. We mention that all the software and programs developed for the fractal antennas design obtained in this paper are new and genuine. [ABSTRACT FROM AUTHOR]

Published

2025

8. A Lower 6GHz MIMO Antenna with EBG Structure in 5G Applications.

Author

Kumutha, D., Lakshmiprabha, K. E., Jeevitha, S., Jayanthi, K., and Jeyabharathi, M.

Subjects

PLANAR antennas, ANTENNA design, ANTENNAS (Electronics), BAND gaps, PERMITTIVITY

Abstract

In modern wireless communication, the enhancement of 5G wireless applications vigorously increases the growth for gaining in MIMO (Multiple Input Multiple Output) technologies. In the conventional method, the MIMO antenna is not efficient by having 5GHz with a resulting 75 % and the interference is difficult to exclude. The proposed MIMO antenna design is modeled by four truncated circular patches of radius 9.35 mm at the top layer with a dual partial ground of 10 mm x 60 mm at the bottom to provide better performance. The FR-4 epoxy substrate is counted with the dimensions of 70 mm x 60 mm x 1.6 mm. An impedance bandwidth ranging from 1.7 GHz to 12.4 GHz with 10 dB return loss and isolation of 15 dB is observed for all four planar antennas. The defective ground sketch in the planar plane is functioned by several slots, metamaterials, etc. achieved by the band-notch. The proposed system is obtained to improvise the performance by HFSS simulated results for operating frequency by MIMO antenna as 1.7 GHz to 12.4 GHz. It provides the directivity as 4.6 with a relative permittivity of 4.4 and isolation as 15 dB. Further, the gain of 5.7 dB with an efficiency of 87.95 % has been achieved by the insertion of the Electromagnetic Band Gap (EBG) structure between the two partial ground planes at the bottom. Hence the proposed EBG is proven better than the conventional method SISO antenna in all performance aspects through the MIMO antenna in 5G applications. [ABSTRACT FROM AUTHOR]

Published

2024

9. Broadband Millimeter-Wave Front-End Module Design Considerations in FD-SOI CMOS vs. GaN HEMTs.

Author

Sweeney, Clint, Lie, Donald Y. C., Mayeda, Jill C., and Lopez, Jerry

Subjects

ANTENNA arrays, GALLIUM nitride, ANTENNAS (Electronics), POWER amplifiers, COMPLEMENTARY metal oxide semiconductors, PHASED array antennas, MODULATION-doped field-effect transistors

Abstract

Featured Application: Radio-Frequency Technologies for 5G and 6G Wireless Communications. Millimeter-wave (mm-Wave) phased array systems need to meet the transmitter (Tx) equivalent isotropic radiated power (EIRP) requirement, and that depends mainly on the design of two key sub-components: (1) the antenna array and (2) the Tx power amplifier (PA) in the front-end-modules (FEMs). Simulations using an electromagnetic (EM) solver carried out in Cadence AWR with AXIEM suggest that for two uniform square patch antenna arrays at 24 GHz, the 4 element array has ~6 dB lower antenna gain and twice the half power beam width (HPBW) compared to the 16 element array. We also present measurements and post-layout parasitic-extracted (PEX) EM simulation data taken on two broadband mm-Wave PAs designed in our lab that cover the key portions of the fifth-generation (5G) FR2-band (i.e., 24.25–52.6 GHz) that lies between the super-high-frequency (SHF, i.e., 3–30 GHz) band and the extremely-high-frequency (EHF, i.e., 30–300 GHz) band: one designed in a 22 nm fully depleted silicon on insulator (FD-SOI) CMOS process, and the other in an advanced 40 nm Gallium Nitride (GaN) high-electron-mobility transistor (HEMT) process. The FD-SOI PA achieves saturated output power (POUT,SAT) of ~14 dBm and peak power-added efficiency (PAE) of ~20% with ~14 dB of gain and 3 dB bandwidth (BW) from ~19.1 to 46.5 GHz in measurement, while the GaN PA achieves measured POUT,SAT of ~24 dBm and peak PAE of ~20% with ~20 dB gain and 3 dB BW from ~19.9 to 35.2 GHz. The PAs' measured data are in good agreement with the PEX EM simulated data, and 3rd Watt-level GaN PA design data are also presented, but with simulated PEX EM data only. Assuming each antenna element will be driven by one FEM and each phased array targets the same 65 dBm EIRP, millimeter wave (mm-Wave) antenna arrays using the Watt-level GaN PAs and FEMs are expected to achieve roughly 2× wider HPBW with 4× reduction in the array size compared with the arrays using Si FEMs, which shall alleviate the thorny mm-Wave line-of-sight (LOS)-blocking problems significantly. [ABSTRACT FROM AUTHOR]

Published

2024

10. Evaluating the performance measurement of novel octangular star shaped micromachined substrate with self-isolated 8 × 8 port MIMO antenna for dual band 28 GHz (n261) and 39 GHz (n260) millimeter-wave 5G applications.

Author

Sharma, Manish, Annadurai, C., Nelson, I., Ramkumar Raja, M., and Kaur, Parminder

Subjects

*ANTENNAS (Electronics), *PERMITTIVITY, *5G networks, *STATISTICAL correlation, *BANDWIDTHS

Abstract

Designing an electromagnetic radiating element that can enhance the capacity of a device operating with multiple frequencies simultaneously, while maintaining its compactness and compatibility with customer premise equipment, is a significant challenge. To tackle this issue, this work proposes a multiple input multiple output (MIMO) antenna with eight elements placed 45° apart on a Rogers 5880 substrate which has been micromachined from sixteen edges with a thickness of 0.252 mm. The substrate measures the area of 717.46 mm2 boasting a dielectric constant of 2.2 and loss tangent of 0.0009 with a unique star shape. The slot technique improves the return loss accompanied by defected ground structure to achieve dual-band operation at 28.1 GHz (n261) with the impedance bandwidth from 27.95 to 28.4 (0.45 GHz) and 39.5 GHz (n260) having impedance bandwidth from 38.6 to 40.4(1.8 GHz). The inter-element isolation of more than 60 dB is achieved for both bands with micromachined substrate. The measured gain at 28 GHz is 7dBi and at 39 GHz it is obtained as 7.4dBi. The 8-port MIMO is simulated for all the diversity metrics such as Diversity Gain (DG), Channel Capacity Loss (CCL), Envelope Correlation Coefficient (ECC), Mean Effective Gain, Total Active Reflection Co-efficient (TARC). The parameters evaluated for all eight ports are within the standard values with ECC of < 0.001, DG > 9.99 dB, CCL < 0.1b/s/Hz, and the TARC < − 10 dB. The MIMO has been fabricated and tested for various results which favourably aligned with the simulated results validating the applicability of the proposed mm-Wave 8-port MIMO antenna for practical 5G applications. Furthermore, the 8-port is also simulated for conformality check which showed a minor change in impedance bandwidth at 15°, 30°, and 45°. The Specific Absorption Ratio (SAR) analysis has provided values less than 1.6 W/kg for both the intended bands. The conformal and SAR analysis has added an advantage to the application of the proposed antenna for 5G as well as for wearable on-body applications. [ABSTRACT FROM AUTHOR]

Published

2024

11. Enhancing the Quality of Multimedia Streaming over Radio Resource Management and Smart Antennas of 5G Networks.

Author

Ibrahim, H. M., Khalil, A. T., and Sakr, Hesham A.

Subjects

RADIO resource management, ADAPTIVE antennas, END-to-end delay, INTERNET radio, STREAMFLOW

Abstract

According to the critical challenges for accessing streaming multimedia over wireless technologies such as lower ranges of data throughput and unacceptable rates for delay and packet losses, it was necessary to implement a system that makes some processes for these challenges, with considerations of coverage and capacity limitations that definitely will have a direct effect on the overall system quality. In this paper, we discuss the effect of applying radio resource management (RRM) technique and smart antenna modes through the fifth-generation (5G) radio link on the voice streaming packets flow in a network where many scenarios were simulated by OPNET while maintaining the quality of the network, regardless of the data load inside it. Also, we have a proposed algorithm to utilize RRM and smart antenna modes over 5G networks. On the other hand, we make a detailed eleven scenarios divided into two phases to discuss the effect of these parameters on quality as (i) RRM Coverage and system capacity, and (ii) smart antenna modes in terms of coverage and capacity. The results of simulation prove that adding RRM and smart antenna modes to the proposed networks over 5G radio link verifies a considerable evolution in the network on data flow of streaming voice packets, also including that end to end delay, packet delay variations, and throughput realize the overall requirements for quality of service (QoS) to access multimedia streaming services through a wide range of 5G bandwidth. The proposed system support monotonically response of delay all over the time of simulation for all QoS metrics. [ABSTRACT FROM AUTHOR]

Published

2024

12. Enhancing 5G Vehicular Edge Computing Efficiency with the Hungarian Algorithm for Optimal Task Offloading.

Author

Benbraika, Mohamed Kamel, Kraa, Okba, Himeur, Yassine, Telli, Khaled, Atalla, Shadi, and Mansoor, Wathiq

Subjects

EDGE computing, VIDEO surveillance, AUGMENTED reality, CITIES & towns, AUTONOMOUS vehicles

Abstract

The rapid advancements in vehicular technologies have enabled modern autonomous vehicles (AVs) to perform complex tasks, such as augmented reality, real-time video surveillance, and automated parking. However, these applications require significant computational resources, which AVs often lack. To address this limitation, Vehicular Edge Computing (VEC) has emerged as a promising solution, allowing AVs to offload computational tasks to nearby vehicles and edge servers. This offloading process, however, is complicated by factors such as high vehicle mobility and intermittent connectivity. In this paper, we propose the Hungarian Algorithm for Task Offloading (HATO), a novel approach designed to optimize the distribution of computational tasks in 5G-enabled VEC systems. HATO leverages 5G's low-latency, high-bandwidth communication to efficiently allocate tasks across edge servers and nearby vehicles, utilizing the Hungarian algorithm for optimal task assignment. By designating an edge server to gather contextual information from surrounding nodes and compute the best offloading scheme, HATO reduces computational burdens on AVs and minimizes task failures. Through extensive simulations in both urban and highway scenarios, HATO achieved a significant performance improvement, reducing execution time by up to 75.4% compared to existing methods under full 5G coverage in high-density environments. Additionally, HATO demonstrated zero energy constraint violations and achieved the highest task processing reliability, with an offloading success rate of 87.75% in high-density urban areas. These results highlight the potential of HATO to enhance the efficiency and scalability of VEC systems for autonomous vehicles. [ABSTRACT FROM AUTHOR]

Published

2024

13. A Comprehensive Analysis of 5G Dynamic Spectrum Sharing for IoT Environments

Author

Volodymyr A Labzhynskyi, Hamza Ghazwan Khalid, Zaid Ghanim Ali, Tareq Abdulrazzaq Majeed Alabdali, Basma Mohammed Khaleel, Halal Azam Sbhui, and Hind Monadhel

Subjects

dynamic spectrum sharing (dss), fifth generation (5g), internet of things (iot), spectrum utilization, network performance, latency reduction, enhanced throughput, spectral congestion, algorithm optimization, wireless communication (wc), Telecommunication, TK5101-6720

Abstract

Background: 5G technology will revolutionize wireless communications, emphasizing spectrum efficiency. Pervasive device connectivity requires unprecedented spectrum resources to allow flawless Internet of Things (IoT) communication. Thus, dynamic spectrum sharing (DSS) is essential for 5G and IoT cohabitation without spectral congestion. Objective: This study examines how DSS improves 5G network speed and efficiency, especially in an IoT-dominated context. The main goals are strategies and methods to maximize spectrum sharing among 5G and IoT devices for resilient, scalable, and uninterrupted connectivity. Methods: Using simulation and testing, this study assesses 5G DSS algorithms and models for latency, throughput, and reliability. The current study compares conventional spectrum allocation and dynamic sharing strategies in various IoT applications. Results: 5G networks with DSS have improved spectrum usage and performance. Optimized algorithms reduce latency and increase throughput even in IoT-heavy situations. Conclusion: DSS is vital to strengthening 5G networks for IoT applications. DSS supports and expands IoT ecosystems by reducing spectrum scarcity and improving network performance, laying the groundwork for the 5G era's rush of connected devices and applications. DSS algorithms need further research to meet changing technology and application needs.

Published

2024

14. Compact Elliptical Slot Millimeter-Wave MIMO Antenna for 5G Applications.

Author

Farooq, Nazia, Muzaffar, Khalid, and Malik, S. A.

Subjects

*ANTENNA design, *MIMO systems, *ANTENNAS (Electronics), *SOFTWARE measurement, *PERMITTIVITY

Abstract

This study introduces a novel, highly compact broadband millimeter-wave (mm-wave) antenna design and its Multiple-Input-Multiple-Output (MIMO) configuration proposed for 28 GHz applications targeting 5G networks. The antenna is designed over a 0.25 mm thick Rogers RT5880LZ substrate having a relative dielectric permittivity of 2 and an overall size of 16 mm × 16 mm. Its MIMO configuration utilizes polarization diversity and includes four elliptical-slot radiators integrated with microstrip-line structures, specifically optimized for 28 GHz operation. The performance of the proposed mm-wave MIMO configuration is validated through simulation of its S-parameters using CST software and measurements obtained with a vector network analyzer (VNA). The proposed antenna demonstrates excellent S-parameter performance, achieving a gain of up to 6 dBi and a radiation efficiency of 94% across the operational frequency band. Each antenna element exhibits an impressive wide operating bandwidth of 9 GHz, spanning from 22.2 to 31.4 GHz at a − 10 dB threshold. Evaluations of the MIMO system's performance indicate promising results, including an exceptionally low envelope correlation of about 10 - 5 and a diversity gain of around 10 dB throughout the operating bandwidth. The design also ensures significant isolation between MIMO elements without requiring decoupling structures. A physical prototype of the proposed antenna is fabricated and subjected to measurements, depicting a strong corelation between the measured and simulated data, with some minor variations attributed to fabrication tolerances and cable losses. Comparative analysis further emphasizes the potential viability of the proposed MIMO antenna positioning it as a viable candidate for future compact-sized mm-wave MIMO systems. [ABSTRACT FROM AUTHOR]

Published

2024

15. Four‐port dual CP MIMO antenna with enhanced isolation for 5G applications.

Author

Koçer, Mustafa and Günel, Tayfun

Subjects

*ANTENNAS (Electronics), *MICROSTRIP antennas, *5G networks, *BANDWIDTHS, *WAVELENGTHS

Abstract

Summary In this paper, a 4 × 4 MIMO (multiple‐input multiple‐output) antenna with metasurface (MS), which is composed of dual circularly polarized (CP) patch antennas, is proposed for 5G (sub‐6 GHz) applications. The MIMO antenna consists of four microstrip patch antennas. In order to improve the isolation of the MIMO antenna, parasitic elements are placed on the MS and layer of patch antennas. In addition, a substrate‐integrated waveguide (SIW) structure is used at the center of the MIMO antenna for this purpose. The proposed MIMO antenna is fabricated for validation tests. The antenna has overall dimensions of 115 mm × 115 mm × 3.2 mm (1.219 λ0$$ {\lambda}_0 $$ × 1.219 λ0$$ {\lambda}_0 $$ × 0.033 λ0$$ {\lambda}_0 $$, where λ0$$ {\lambda}_0 $$ is the free space wavelength at the lowest operating frequency in 10‐dB impedance bandwidth). The MIMO antenna has 10‐dB impedance bandwidth (IBW) from 3.3 to 3.8 GHz (14.08%), 3‐dB axial ratio bandwidth (ARBW) from 3.42 to 3.69 GHz (7.59%), and 6.36‐dBi peak gain. The isolation is greater than 28.14 dB in the n78 frequency band (3.3–3.8 GHz). [ABSTRACT FROM AUTHOR]

Published

2024

16. Wideband 2×2 antenna-in-package based on magneto-electric dipole array antenna for 5G mm Wave applications.

Author

Wai Yan Yong and Alayón Glazunov, Andrés

Subjects

DIPOLE array antennas, PHASED array antennas, ANTENNA arrays, CIRCUIT board manufacturing, PRINTED circuit manufacturing

Abstract

This paper presents an antenna-in-package (AiP) design realised with the conventional multi-layer printed circuit board manufacturing method. The design consists of a wideband 2 × 2 magneto-electric dipole array antenna operating from 24.25 − 29.5 GHz and a wideband transition from the analogue beamformer integrated into the proposed MED array antenna (IMED). The IMED array antenna has been fabricated with two distinct NXP analogue beamformer chips, i.e., MMW 9004 KC and MMW 9002 KC covering the N257 and the N258 band, respectively. The measured effective isotropic radiated power at P1dB was 35.3 dBm and 35.1 dBm for the IMED with the MMW 9004 KC and the MMW 9002 KC analogue beamformer chip, respectively. Our proposed antenna demonstrates the feasibility of designing a single wideband AiP that can be integrated with different analogue beamformers operating within the frequency band of the proposed antenna. This is true, provided the RFIC used for integration has the same footprint for RF ports, serial peripheral interface control ports, and DC power supply ports. The primary benefit of the proposed technique is the design antenna can adapt the operating frequency to different frequency standards by incorporating additional analogue chips without increasing the design complexity. This feature enables the antenna manufacturer to tailor the antenna products to different frequency standardisations depending on where the antenna will be employed. The AiP operates at 5G millimeter-wave (mmWave) frequencies, with the potential for Internet of Things applications. Furthermore, from our simulation results, the proposed IMED can potentially be extended as a phased array antenna with 2D scanning. [ABSTRACT FROM AUTHOR]

Published

2024

17. Computational Complexity for Simplified Universal Filtered Multi-Carrier (UFMC) Wireless Transmitter

Author

Manda, Rajarao, Kumar, Adesh, and Gowri, R.

Published

2024

18. Handover management procedures for future generations mobile heterogeneous networks

Author

Safak Sonmez, Kenan Furkan Kaptan, Muhammet Ali Tunç, Ibraheem Shayea, Ayman A. El-Saleh, and Bilal Saoud

Subjects

Fifth generation (5G), Heterogeneous network (HetNet), Handover, Machine learning (ML), Millimeter wave (mmWave), Engineering (General). Civil engineering (General), TA1-2040

Abstract

Handover (HO) management in Heterogeneous Networks (HetNets) poses challenges arising from network densification and dynamic environmental behaviors. Existing HO decision algorithms struggle to efficiently utilize network resources and ensure a high-quality user experience amidst the complexity of HetNets and the burgeoning growth of mobile users. This paper introduces a robust and data-driven HO decision model designed to enhance HO performance in HetNets. Initially, a conventional HO decision algorithm is developed based on users' Reference Signal Received Power (RSRP) values in MATLAB. Various simulation cases explore different HO parameters to observe their impact on handover performance. To address these challenges, a data-driven HO decision model leveraging Long Short-Term Memory (LSTM), a deep learning technique, is proposed for the regression task. The LSTM model is trained and tested using obtained RSRP values, and the future RSRP values predicted by the model are employed to trigger HO decisions in the proposed algorithm. Results from the traditional HO decision algorithm are compared with those of the proposed machine learning-based approach across various simulation runs, considering average Signal-to-Interference-plus-Noise Ratio (SINR), RSRP, user throughput values, the number of HOs and the Radio Link Failure (RLF) ratio. Different user speeds are also considered to establish a relationship between HO frequency and mobile user speed. The proposed model achieved reducing the rate of radio link failure to levels that are deemed acceptable in order to ensure a continuous connection.

Published

2024

19. Dual-band MIMO antenna design for enhanced 5G performance: simulation, implementation, and evaluation.

Author

Dhandapani, Gokila, Alsowail, Rakan A., Rajesh Kumar, D., and Aly, Moustafa H.

Subjects

*ANTENNA design, *MULTIFREQUENCY antennas, *ANTENNAS (Electronics), *5G networks, *REFLECTANCE, *OMNIDIRECTIONAL antennas

Abstract

A small MIMO antenna for use in dual bands is designed, simulated, and implemented in this work. Initially, a patch antenna was constructed and simulated, with further adjustments made to its size to achieve a dual-band performance at frequencies of 4.8 GHz and 6.8 GHz. A MIMO structure consisting of two elements is designedwith a partial ground plane. The electrical dimension of the antenna is 0.079λ × 0.0382λ at 4.8 GHz. The findings indicate that the MIMO antenna design demonstrated effective performance across intended frequency bands with 10 dB impedance bandwidth. The antenna displayed an essentially omnidirectional radiation pattern and achieved a satisfactory level of gain up to 5 dBi. The obtained findings exhibit promise, therefore establishing the suggested antenna as a viable option for 5G applications. The designed antenna is manufactured and practically tested in order to evaluate it's fundamental characteristics, including reflection coefficient and radiation pattern. These experimental findings were then compared to the outcomes obtained through simulation, resulting in a satisfactory consensus between simulated and measured results. [ABSTRACT FROM AUTHOR]

Published

2024

20. Design and Analysis of Two Element Modified Circular Shaped MIMO Antenna for 5G Application.

Author

Kumutha, D., Islam, T., Muthumari, P., Vijayalakshmi, K., Rajalakshmi, R., and Indumathi, M.

Subjects

ANTENNAS (Electronics), WIRELESS LANs, MIMO systems, TELECOMMUNICATION systems, 5G networks, DATA transmission systems, MICROSTRIP antennas

Abstract

Printed antenna technology gained has become centre of attraction for designing MIMO antenna system for future communication applications. Antenna is an essential component for 5G communication system. MIMO technology is highly preferrable due to high data rate and simultaneous data transmission establishment. In this article, a curved slot incorporated circular shaped antenna is constructed and tested for performance utilizing conventional ground planes in an eventual Fifth Generation (5G) mobile communication network. The proposed single element system is operating from 2.6 to 12.9 GHz with an 85.84% efficiency throughout the band. The substrate of the radiator is 30 mm 30 mm 1.6 mm, where a circular patch is used whose size is 9.35 mm. A partial ground structure of 30 mm 10 mm is used to obtain high efficiency and wide bandwidth. The structured antenna system has a maximum directivity of 4.8, efficiency of 89%, and maximum gain of 1.68 dB which are desired in any MIMO system to tolerate interference and maintain user bandwidth. The proposed micro strip patch two element antenna covers 10 dB return loss frequencies from 2.6 GHz to 11.8 GHz than the conventional method. The total size of the MIMO antenna system is 70 mm 60 mm 1.6 mm. The 2-element MIMO antenna simulated results are determined by the HFSS software with their performance. [ABSTRACT FROM AUTHOR]

Published

2024

21. Miniaturized T and Inverted T Slotted Ultra Wide Band Antenna with Defected Ground (DG) System for 5G Communication.

Author

Jeyabharathi, M., Kumutha, D., Geetha, P., Devi, R. D. H., Manikandan, R., and Sripriya, T.

Subjects

TELECOMMUNICATION systems, ANTENNAS (Electronics), SLOT antennas, IMPEDANCE matching, 5G networks

Abstract

A T and Inverted T slotted antenna is proposed with a very compact size of (3,00 x 1,72 x 0,08) mm³. The radiator is built over FR-4 substrate. The system operates from 15 to 35 GHz attaining a very high bandwidth of 20GHz. The impedance match is observed to be high which reflects the resonances at 18.88; 21.1; 24.7; 28.0; 30.8 and 34.1 GHz with minimum reflection as – 19.6 db to a maximum of 48db. Antenna parameters such as Gain above 3dbi as a minimum and to the maximum of 10dbi is observed throughout the operating frequency. VSWR is maintained below 2 with efficiency varying within 60%. Defected Ground Structures is implemented to obtain improved gain through the operating band. The resonance points cover the bands suggested by the International Telecommunication Union for the implementation of the 5G spectrum such as n 257 and n258 bands (26.50-29.50GHz, wheres 15GHz comes under ku,k, and Q bands. Usage of these bands improves the data rate and reduces signal distortion. Through the entire performance, the antenna becomes a good candidate for 5G applications. [ABSTRACT FROM AUTHOR]

Published

2024

22. Handover management procedures for future generations mobile heterogeneous networks.

Author

Sonmez, Safak, Kaptan, Kenan Furkan, Tunç, Muhammet Ali, Shayea, Ibraheem, El-Saleh, Ayman A., and Saoud, Bilal

Subjects

DEEP learning, USER experience, MILLIMETER waves

Abstract

Handover (HO) management in Heterogeneous Networks (HetNets) poses challenges arising from network densification and dynamic environmental behaviors. Existing HO decision algorithms struggle to efficiently utilize network resources and ensure a high-quality user experience amidst the complexity of HetNets and the burgeoning growth of mobile users. This paper introduces a robust and data-driven HO decision model designed to enhance HO performance in HetNets. Initially, a conventional HO decision algorithm is developed based on users' Reference Signal Received Power (RSRP) values in MATLAB. Various simulation cases explore different HO parameters to observe their impact on handover performance. To address these challenges, a data-driven HO decision model leveraging Long Short-Term Memory (LSTM), a deep learning technique, is proposed for the regression task. The LSTM model is trained and tested using obtained RSRP values, and the future RSRP values predicted by the model are employed to trigger HO decisions in the proposed algorithm. Results from the traditional HO decision algorithm are compared with those of the proposed machine learning-based approach across various simulation runs, considering average Signal-to-Interference-plus-Noise Ratio (SINR), RSRP, user throughput values, the number of HOs and the Radio Link Failure (RLF) ratio. Different user speeds are also considered to establish a relationship between HO frequency and mobile user speed. The proposed model achieved reducing the rate of radio link failure to levels that are deemed acceptable in order to ensure a continuous connection. • HO management in HetNets is challenging due to network densification and dynamic environmental behaviors. • Existing HO decision algorithms are unable to efficiently ensure a high-quality user experience in HetNets. • The paper introduces a robust and data-driven HO decision model aimed at improving HO performance in HetNets. • To address the limitations of the traditional approach, a data-driven HO decision model is proposed based on LSTM. • The proposed algorithm's advantages and disadvantages are assessed based on the simulation results. [ABSTRACT FROM AUTHOR]

Published

2024

23. Review on the Enhancement of 5G Communications Using LEO Satellites

Author

Singh, Neil, Kothari, Kajal, Kumar, Shiu, Assaf, Mansour, Kacprzyk, Janusz, Series Editor, Gomide, Fernando, Advisory Editor, Kaynak, Okyay, Advisory Editor, Liu, Derong, Advisory Editor, Pedrycz, Witold, Advisory Editor, Polycarpou, Marios M., Advisory Editor, Rudas, Imre J., Advisory Editor, Wang, Jun, Advisory Editor, Ranganathan, G., editor, Papakostas, George A., editor, and Shi, Yong, editor

Published

2024

24. Innovative mm-Wave Compact Dual-Port MIMO Antenna with Inherent Wideband Isolation at 28 GHz for 5G Wireless Networks

Author

Khabba, Asma, Sellak, Lahcen, Amadid, Jamal, El Ouadi, Zakaria, Ibnyaich, Saida, Zeroual, Abdelouhab, Celebi, Emre, Series Editor, Chen, Jingdong, Series Editor, Gopi, E. S., Series Editor, Neustein, Amy, Series Editor, Liotta, Antonio, Series Editor, Di Mauro, Mario, Series Editor, El Ghzaoui, Mohammed, editor, Das, Sudipta, editor, Samudrala, Varakumari, editor, and Medikondu, Nageswara Rao, editor

Published

2024

25. Design of a GaAs-FET Based Low Noise Amplifier for Sub-6 GHz 5G Applications

Author

Zarrik, Samia, Bendali, Abdelhak, ALtalqi, Fatehi, Benkhadda, Karima, Habibi, Sanae, El Kobbi, Mouad, Sahel, Zahra, Habibi, Mohamed, Kacprzyk, Janusz, Series Editor, Gomide, Fernando, Advisory Editor, Kaynak, Okyay, Advisory Editor, Liu, Derong, Advisory Editor, Pedrycz, Witold, Advisory Editor, Polycarpou, Marios M., Advisory Editor, Rudas, Imre J., Advisory Editor, Wang, Jun, Advisory Editor, Farhaoui, Yousef, editor, Hussain, Amir, editor, Saba, Tanzila, editor, Taherdoost, Hamed, editor, and Verma, Anshul, editor

Published

2024

26. User Clustering in mm Wave Quality of Service-Based Non-orthogonal Multiple Access (QNOMA) for Vehicular Network

Author

Hamedoon, Syed Muhammad, Chattha, Jawwad Nasar, Kacprzyk, Janusz, Series Editor, Gomide, Fernando, Advisory Editor, Kaynak, Okyay, Advisory Editor, Liu, Derong, Advisory Editor, Pedrycz, Witold, Advisory Editor, Polycarpou, Marios M., Advisory Editor, Rudas, Imre J., Advisory Editor, Wang, Jun, Advisory Editor, Yang, Xin-She, editor, Sherratt, R. Simon, editor, Dey, Nilanjan, editor, and Joshi, Amit, editor

Published

2024

27. Integration of 5G, 6G and IoT with Low Earth Orbit (LEO) networks: Opportunity, challenges and future trends

Author

Ibraheem Shayea, Ayman A. El-Saleh, Mustafa Ergen, Bilal Saoud, Riad Hartani, Derya Turan, and Adnan Kabbani

Subjects

Fifth generation (5G), Future mobile broadband networks, Integration, Land mobile satellite system, Satellite, Satellite challenges, Technology

Abstract

The rapid growth of the massive smart Internet of Things (IoT) with mobile connections, the enhanced Mobile Broadband (eMBB) and the high demand for building a connected and intelligent world increase the probability of mobile satellite systems to be a major network in providing internet communication services in the future. Currently, the mobile satellite systems are envisioned as a significant solution for providing mobile services in different settings and for various vital objectives. These satellite systems have special qualities in each of these situations, including extensive coverage area, robustness, and ability to broadcast/multicast. The Low Earth Orbit (LEO) systems are the best promising technology that will offer internet services among the different types of satellite systems. However, the LEO systems are still experiencing certain restrictions with respect to connectivity, stability, and mobility support; because of which communication becomes unreliable. Therefore, the aim of this paper is to broadly explain the LEO systems and services in a comprehensive manner using a variety of perspectives. The paper focus is on key aspects of mobile internet based on satellite systems. This paper illustrates the integration of LEO systems with fifth and sixth generations of mobile cellular networks as well as with the IoT networks. It discusses the problems being faced as a result of the integration between cellular with IoT and satellite systems by comprehending which future research plans are outlined.

Published

2024

28. Broadband Millimeter-Wave Front-End Module Design Considerations in FD-SOI CMOS vs. GaN HEMTs

Author

Clint Sweeney, Donald Y. C. Lie, Jill C. Mayeda, and Jerry Lopez

Subjects

fifth generation (5G), 6G, front-end module (FEM), high-electron-mobility-transistor (HEMT), half power beam width (HPBW), millimeter wave (mm-Wave), Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

Millimeter-wave (mm-Wave) phased array systems need to meet the transmitter (Tx) equivalent isotropic radiated power (EIRP) requirement, and that depends mainly on the design of two key sub-components: (1) the antenna array and (2) the Tx power amplifier (PA) in the front-end-modules (FEMs). Simulations using an electromagnetic (EM) solver carried out in Cadence AWR with AXIEM suggest that for two uniform square patch antenna arrays at 24 GHz, the 4 element array has ~6 dB lower antenna gain and twice the half power beam width (HPBW) compared to the 16 element array. We also present measurements and post-layout parasitic-extracted (PEX) EM simulation data taken on two broadband mm-Wave PAs designed in our lab that cover the key portions of the fifth-generation (5G) FR2-band (i.e., 24.25–52.6 GHz) that lies between the super-high-frequency (SHF, i.e., 3–30 GHz) band and the extremely-high-frequency (EHF, i.e., 30–300 GHz) band: one designed in a 22 nm fully depleted silicon on insulator (FD-SOI) CMOS process, and the other in an advanced 40 nm Gallium Nitride (GaN) high-electron-mobility transistor (HEMT) process. The FD-SOI PA achieves saturated output power (POUT,SAT) of ~14 dBm and peak power-added efficiency (PAE) of ~20% with ~14 dB of gain and 3 dB bandwidth (BW) from ~19.1 to 46.5 GHz in measurement, while the GaN PA achieves measured POUT,SAT of ~24 dBm and peak PAE of ~20% with ~20 dB gain and 3 dB BW from ~19.9 to 35.2 GHz. The PAs’ measured data are in good agreement with the PEX EM simulated data, and 3rd Watt-level GaN PA design data are also presented, but with simulated PEX EM data only. Assuming each antenna element will be driven by one FEM and each phased array targets the same 65 dBm EIRP, millimeter wave (mm-Wave) antenna arrays using the Watt-level GaN PAs and FEMs are expected to achieve roughly 2× wider HPBW with 4× reduction in the array size compared with the arrays using Si FEMs, which shall alleviate the thorny mm-Wave line-of-sight (LOS)-blocking problems significantly.

Published

2024

29. Towards intelligent user clustering techniques for non-orthogonal multiple access: a survey

Author

Hamedoon, Syed M., Chattha, Jawwad Nasar, and Bilal, Muhammad

Published

2024

30. A game theoretic approach for spectral and energy efficient D2D communication in 5G-IoT networks.

Author

Pandey, Krishna, Chandra, Saurabh, and Arya, Rajeev

Subjects

TELECOMMUNICATION systems, ENERGY consumption, SUPPORT vector machines, POWER resources, 5G networks, INTERNET of things, WIRELESS sensor networks

Abstract

In the context of fifth generation (5G) technology, Device-to-Device (D2D) communication plays a pivotal role, requiring swift and intelligent decision-making in mode selection and device discovery. This study addresses the challenge of rapid mode selection and device discovery within 5G communication networks, focusing specifically on enhancing spectral and energy efficiency for Internet of Things (IoT) applications. A novel self-centered game theory-based algorithm is introduced to optimize spectral efficiency and support intelligent mode selection. Additionally, the utilization of the support vector machine (SVM) expedites mode selection decisions. For D2D discovery, the Frank-Wolfe method is adopted, significantly improving the differentiation between D2D and Cellular users based on signal strength and interference, thereby enhancing spectral efficiency. The proposed approach maximizes spectral efficiency while adhering to strict power and interference constraints, intelligently partitioning bandwidth into two subparts using game theoretic principles to amplify spectral efficiency. Furthermore, the emphasis on energy efficiency is underscored through iterative calculations to achieve maximum energy-efficient spectral allocation. Numerical analyses validate the efficacy of the proposed technique, revealing substantial improvements in accurately predicted labels. As the number of devices increases, precision and recall rates experience noteworthy enhancements, ultimately leading to superior bandwidth utilization. This research presents a significant contribution to the field of 5G communication, particularly concerning energy efficiency, which is paramount for IoT applications. By accelerating D2D connectivity and optimizing energy and spectrum resources, it advances the goals of energy-efficient D2D communication within 5G-IoT networks. [ABSTRACT FROM AUTHOR]

Published

2024

31. Ka-band stacked and pseudo-differential orthogonal load-modulated balanced power amplifier in 22 nm CMOS FDSOI.

Author

Rusanen, Jere, Sethi, Alok, Tervo, Nuutti, Kiuru, Veeti, Rahkonen, Timo, Pärssinen, Aarno, and Aikio, Janne P.

Abstract

This paper presents an integrated power amplifier (PA) following the orthogonal load-modulated balanced amplifier (OLMBA) topology. The fixed-phase prototype in this paper is implemented with 22 nm complementary metal oxide semiconductor (CMOS) fully depleted silicon-on-insulator (FDSOI) process. The proposed PA operates at 26 GHz frequency range, where it achieves 19.5 dBm output power, 16.6 dB gain, 15.7% power added efficiency, and 18.3 dBm output 1-dB compression point ($P_{\rm 1\,dB}$). The PA is also tested with high dynamic range modulated signals, and it achieves, respectively, 11.4 dBm and 4.9 dBm average output power (P avg) with 100 MHz and 400 MHz 64-QAM third-generation partnership project/new radio frequency range 2 signals, and 14 dBm P avg with 0.6 Gb/s (120 MHz) single carrier 64-QAM signal, measured at 26 GHz and using −28 dBc adjacent channel leakage ratio and −21.9 dB (8%) error vector magnitude as threshold values. The proposed OLMBA is also compared to a stand-alone quadrature-balanced PA. Modulated measurements show that the stand-alone quadrature-balanced PA has better linearity in deep back-off, but the OLMBA has better efficiency. [ABSTRACT FROM AUTHOR]

Published

2024

32. Analysis and Designing of New Broadband Power Divider Using Stepped Impedance for WLAN and 5G Applications.

Author

Ennajih, Abdelhadi, Sardi, Azzeddine, and Errkik, Ahmed

Subjects

GSM communications, WIRELESS LANs, POWER dividers, 5G networks, INSERTION loss (Telecommunication), RADIO frequency, PERMITTIVITY

Abstract

The development of radio frequency circuits is currently guided mainly through two objectives, which are size reduction and performance improvement of devices. Within a reception or transmission channel, the division and/or combination of power are the most delicate stages due to their large dimensions and high insertion losses, particularly in the case of dividers/combiners based on planar technologies. In this context, this study proposes an analysis and design of a new broadband power divider and combiner using stepped impedance. The power divider/combiner developed is designed to cover a broad frequency spectrum ranging from 1 GHz to 4 GHz, including wireless applications such as Global Mobile Communications Systems (GSM), Industrial, Scientific and Medical (ISM), and Sub-6 GHz 5th Generation (5G) applications. The proposed circuit was analyzed using the stepped transmission line impedance method and designed by Advanced Design System (ADS) on an Epoxy-FR4 substrate with a dielectric constant of 4.4 and a thickness of 1.58 mm. The achieved results showed excellent characteristics in terms of transmission across the input and output terminals, mismatches at all three terminals, and isolation among output terminals. A prototype was built and the measured results showed good agreement with those obtained by simulation. [ABSTRACT FROM AUTHOR]

Published

2024

33. The Problem of Spurious Emissions in 5G FR2 Phased Arrays, and a Solution Based on an Upmixer With Embedded LO Leakage Cancellation

Author

Arun Paidimarri, Yujiro Tojo, Caglar Ozdag, Alberto Valdes-Garcia, and Bodhisatwa Sadhu

Subjects

3GPP, fifth generation (5G), ACLR, double-sideband mixer, emissions, filtering, Electric apparatus and materials. Electric circuits. Electric networks, TK452-454.4

Abstract

The wireless spectrum is a shared resource. Transmitters are expected to transmit only at their allotted frequency range and not at other frequencies. Transmitters are not perfect, and therefore, there are regulations that limit the transmitted energy outside the intended transmission frequencies. In this article, we provide an overview of the transmit mask requirements for 5G FR2, and the main factors that contribute to unwanted emissions. We then present some key radio architecture and circuit design considerations to help meet these emission requirements. Since the local oscillator (LO) leakage spur is one of the worst offenders, we also introduce an LO cancellation technique in the upmixer. We introduce two actuator circuits to control two independent LO signals at the upmixer output, one resulting from the upconversion from dc to LO, and another resulting from downconversion from 2 LO to LO. These two independent LO outputs then provide 2-D phase and amplitude control and can combine to create an equal and opposite LO signal at the output of the upmixer. The LO cancellation results in better than −57-dBc LO leakage across all candidate frequencies. Finally, we present extensive over-the-air (OTA) measurement validation of the LO suppression across frequencies, signal levels, and 64-element beam steering across a 60 beam steering range.

Published

2024

34. Optimization and Performance of Metamaterial- Based Electromagnetic Scattering Sheet for Coverage Improvement in 28 GHz Band

Author

Yasutaka Murakami, Jerdvisanop Chakarothai, Lira Hamada, and Katsumi Fujii

Subjects

Electromagnetic scattering, fifth generation (5G), metamaterial, millimeter wave, wireless communication systems, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Fifth generation (5G) mobile communication systems have been deployed in the millimeter wave (mmWave) band. Since electromagnetic (EM) waves in this band exhibit high propagation loss and antennas are highly directive, the performance of wireless communications is largely degraded in a non-line-of-sight (NLOS) area, resulting in a limited coverage area. To improve the performance and increase the coverage area, a metamaterial-based electromagnetic scattering sheet (EMSS) with broad scattering characteristics is proposed in this paper. We also introduce fast design and optimization methods using equivalent circuits of metamaterials, antenna array theory, and the genetic algorithm (GA). The diffusion coefficient is used as a fitness value to evaluate the scattering characteristics of the EMSS generated by GA. The broad scattering characteristics of the designed EMSS are experimentally confirmed. We clarified that the optimized EMSS has a higher diffusion coefficient than a metal plate of the same size. Finally, we demonstrated improved wireless communication performance in an NLOS area by diffusing the incoming EM fields using our designed EMSS.

Published

2024

35. Wideband Shared-Aperture Antenna for Full-Screen 5G Mobile Devices

Author

Harri Varheenmaa, Pasi Yla-Oijala, Anu Lehtovuori, and Ville Viikari

Subjects

Antenna array, fifth generation (5G), millimeter wave (mmWave), mobile antenna, multiple-input multiple-output (MIMO), patch antenna, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

This paper presents a novel shared-aperture smartphone antenna for sub-6 GHz and millimeter-wave (mmWave) bands. The proposed antenna module comprises a four-element mmWave patch antenna array integrated into a wideband sub-6 GHz slot antenna. The mmWave antenna covers the frequency band 26.5–29.5 GHz with isolation over 16 dB, and the sub-6 GHz antenna covers several bands on the frequency range 3.4–6.0 GHz with isolation over 15 dB. The key features in the proposed concept are that a metal part of the sub-6 GHz antenna acts as a ground plane for the mmWave antenna array, and both antennas are located solely on the metal rim enabling a full edge-to-edge screen. The antenna achieves a high total efficiency of 65–95% and −3 dB beam steering range ±40°. A prototype is manufactured, and measurements verify wideband operation and high isolation in both frequency bands. The four-element multiple-input multiple-output (MIMO) operation with the proposed shared aperture antenna is demonstrated at the sub-6 GHz band.

Published

2024

36. Evaluation of 5G techniques affecting the deployment of smart hospital infrastructure: Understanding 5G, AI and IoT role in smart hospital

Author

Arun Kumar, Aziz Nanthaamornphong, R. Selvi, J. Venkatesh, Mohammed H. Alsharif, Peerapong Uthansakul, and Monthippa Uthansakul

Subjects

Smart hospital, Fifth Generation (5G), Latency, Spectral efficiency, AI, IoT, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Smart Hospital will play a key role in improving the quality of services (QoS) related to the health sector. In the present scenario, it is impossible to accommodate an ageing population with the current infrastructure and facilities provided by conventional hospitals. However, the integration of technologies with the conventional hospital is enhancing the medical services and also making it easier for the public, who can save time and money by getting all the necessary medical facilities while sitting at home. The deployment of the fifth generation (5G) is taking place all over the world. The 5G network offers a better service that can be used in hospitals to make it a smart health service provider with online facilities such as video monitoring, suggesting a proper medical prescription based on medical data, remote surgery, and so on. High bandwidth, a fast data rate, low latency, and a low peak-to-average power ratio (PAPR) are some requirements that need to be fulfilled by the 5G radio. In this work, we focus on improving the power savings, spectral access, latency, and Bit error rate (BER) of the advanced 5G waveforms such as non-orthogonal multiple access (NOMA), filter bank multi carrier (FBMC), and orthogonal frequency division multiplexing (OFDM). In the first part of the article, we proposed a PAPR reduction algorithm to improve the power efficiency of the power amplifier (PA) for 5G waveforms. Several algorithms are applied to the 5G waveforms, and their performances are estimated in terms of PAPR curves. In the second part, we have utilised advanced detection algorithms to improve the signal detection of the 5G waveforms. The simulation results reveal that the proposed algorithms efficiently enhance the throughput of the framework. In the third part, we improve the spectral efficiency of the 5G waveforms by applying spectrum sensing (SS) algorithms. It is seen that the SS methods efficiently reduce the spectrum leakage of the multi-carrier waveforms (MCW). Finally, we examined the role and challenges of the Internet of Things (IoT) and artificial intelligence (AI) in smart hospitals. Overall, it is concluded that hospitals can become more effective, cut expenses, and provide better patient care with the aid of AI and IoT. Hospitals can improve patient outcomes and the state of the healthcare system as a whole by utilising these technologies.

Published

2023

37. Active beam-steering millimetre-wave antenna array system for 5G and beyond

Author

Bansal, Aakash

Subjects

621.3841, Antenna, Antenna Array, Beam steering, 5G, fifth generation (5G), Substrate Integrated Waveguide

Published

2022

38. Enhancing 5G Vehicular Edge Computing Efficiency with the Hungarian Algorithm for Optimal Task Offloading

Author

Mohamed Kamel Benbraika, Okba Kraa, Yassine Himeur, Khaled Telli, Shadi Atalla, and Wathiq Mansoor

Subjects

fifth generation (5G), Hungarian algorithm, task offloading, vehicular edge computing (VEC), wireless access in vehicular environments (WAVE), Electronic computers. Computer science, QA75.5-76.95

Abstract

The rapid advancements in vehicular technologies have enabled modern autonomous vehicles (AVs) to perform complex tasks, such as augmented reality, real-time video surveillance, and automated parking. However, these applications require significant computational resources, which AVs often lack. To address this limitation, Vehicular Edge Computing (VEC) has emerged as a promising solution, allowing AVs to offload computational tasks to nearby vehicles and edge servers. This offloading process, however, is complicated by factors such as high vehicle mobility and intermittent connectivity. In this paper, we propose the Hungarian Algorithm for Task Offloading (HATO), a novel approach designed to optimize the distribution of computational tasks in 5G-enabled VEC systems. HATO leverages 5G’s low-latency, high-bandwidth communication to efficiently allocate tasks across edge servers and nearby vehicles, utilizing the Hungarian algorithm for optimal task assignment. By designating an edge server to gather contextual information from surrounding nodes and compute the best offloading scheme, HATO reduces computational burdens on AVs and minimizes task failures. Through extensive simulations in both urban and highway scenarios, HATO achieved a significant performance improvement, reducing execution time by up to 75.4% compared to existing methods under full 5G coverage in high-density environments. Additionally, HATO demonstrated zero energy constraint violations and achieved the highest task processing reliability, with an offloading success rate of 87.75% in high-density urban areas. These results highlight the potential of HATO to enhance the efficiency and scalability of VEC systems for autonomous vehicles.

Published

2024

39. Per Sub-band Tone Reservation Scheme for Universal Filtered Multi-Carrier Signal

Author

Laabidi Mounira and Bouallegue Ridha

Subjects

ufmc, papr, pstr, fifth generation (5g), Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Telecommunication, TK5101-6720

Abstract

Fifth generation (5G) applications like Internet of Things (IoT), Enhanced Mobile Broadband (eMBB), Cognitive Radios (CR), Vehicle to Vehicle (V2V) and Machine to Machine (M2M) communication put new demands on the network in terms of low latency, ultra-reliable communication and efficiency when transmitting very small bursts. One new contender that makes its appearance recently is the Universal Filtered Multi- Carrier (UFMC). UFMC is a potential candidate to meet the requirements of 5G upcoming applications. This related waveform encounters the peak-to-average power ratio (PAPR) issue arising from the usage of multi-carrier transmission. In this investigation, two PAPR reduction techniques, called Per Subband Tone Reservation (PSTR) scheme to alleviate PAPR in UFMC systems are suggested. The first one is a pre-filtering PSTR scheme that uses the least squares approximation (LSA) algorithm to calculate the optimization factor(μ) and the second one is a post-filtering method. The concept of this proposal lies on the use of peaks reductions Tone to carry the correctional signal that reduces the high peaks of each sub-band individually. To shed light on UFMC as a potential waveform for 5G upcoming application, a comparison with OFDM modulation is done.

Published

2023

40. Analysis and Designing of New Broadband Power Divider Using Stepped Impedance for WLAN and 5G Applications

Author

Abdelhadi Ennajih, Azzeddine Sardi, and Ahmed Errkik

Subjects

Broadband Power Divider, Fifth Generation (5G), Planar Technologies, Stepped Impedance., Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Abstract The development of radio frequency circuits is currently guided mainly through two objectives, which are size reduction and performance improvement of devices. Within a reception or transmission channel, the division and/or combination of power are the most delicate stages due to their large dimensions and high insertion losses, particularly in the case of dividers/combiners based on planar technologies. In this context, this study proposes an analysis and design of a new broadband power divider and combiner using stepped impedance. The power divider/combiner developed is designed to cover a broad frequency spectrum ranging from 1 GHz to 4 GHz, including wireless applications such as Global Mobile Communications Systems (GSM), Industrial, Scientific and Medical (ISM), and Sub-6 GHz 5th Generation (5G) applications. The proposed circuit was analyzed using the stepped transmission line impedance method and designed by Advanced Design System (ADS) on an Epoxy-FR4 substrate with a dielectric constant of 4.4 and a thickness of 1.58 mm. The achieved results showed excellent characteristics in terms of transmission across the input and output terminals, mismatches at all three terminals, and isolation among output terminals. A prototype was built and the measured results showed good agreement with those obtained by simulation.

Published

2024

41. Design and optimization of a compact microstrip BPF for wireless communication systems based on open-loop rectangular resonators

Author

Youssef Khardioui, Ali El Alami, and Mohammed El Ghzaoui

Subjects

Bandpass filter, Open-loop resonators, Fifth generation (5G), WiMAX, Insertion loss, Wireless communication systems, Technology

Abstract

In a wireless communication chain, filters play a critical role in ensuring the efficiency, reliability, and overall performance of the system. In fact, filters are essential for selecting specific frequency bands. They can narrow or widen the bandwidth, depending on the requirements of the communication protocol. Appropriate bandwidth management is crucial for optimizing data transmission rates and accommodating multiple channels within the available spectrum. This article describes the design of a compact bandpass filter with two identical rectangular open-loop resonators. The proposed filter frequency response covers the 3.5 GHz global interoperability for microwave access (WiMAX) and fifth generation (5G) applications. The structure of this filter uses the Rogers RO6010 substrate, which has a dielectric constant of 10.2, thickness of 1.27 mm, and tangent loss of 0.0023. The proposed device is intended for wireless communication systems operating at 3.5 GHz. The filter offers a wide bandwidth of 1.21 GHz with a small size of (5.72 × 12.34) mm2, and a low insertion loss of −0.16 dB. The suggested filter offers effective utilization across various applications including fifth-generation (5G), sub-6G, and WiMAX. Simulation and optimization of the proposed design are conducted utilizing the HFSS (High Frequency Structure Simulator) software. To corroborate the results from HFSS, the ADS (Advanced Design System) software is employed. The simulation outcomes obtained from both HFSS and ADS simulators demonstrate close resemblance.

Published

2024

42. A Compact Broadside Coupled Stripline 2-D Beamforming Network and Its Application to a 2-D Beam Scanning Array Antenna Using Panasonic Megtron 6 Substrate.

Author

Temga, Jean, Shiba, Takashi, and Suematsu, Noriharu

Subjects

*ANTENNA arrays, *PHASE shifters, *BEAMFORMING, *PHASED array antennas, *ANTENNAS (Electronics), *WIRELESS LANs, *PANASONIC cameras

Abstract

This article presents a 4-way 2-D butler matrix (BM)-based beamforming network (BFN) using a multilayer substrate broadside coupled stripline (BCS). To achieve the characteristics of a compact, wide-bandwidth, high-gain phased array, a BCS coupler is implemented using the Megtron 6 substrate. The compact 2-D BFN is formed by combining planarly two horizontal BCS couplers and two vertical BCS couplers. The BFN is proposed without a crossover and without a phase shifter, generating phase responses of ±90° in the x- and y-directions, respectively. The proposed BFN exhibits a wide operating band of 66.7% (3–7 GHz) and a compact physical area of just 0.25 λ0 × 0.25 λ0 × 0.04 λ0. The planar 2-D BFN is easily integrated with the patch antenna radiation elements to construct a 2-D multibeam array antenna that generates four fixed beams, one in each quadrant, at an elevation angle of 30° from the broadside to the array axis when the element separation is 0.6 λ0. The physical area of the 2-D multibeam array antenna is just 0.8 λ0 × 0.8 λ0 × 0.04 λ0. The prototypes of the BCS coupler, the 2-D BFN, and the 2-D multibeam array antenna were fabricated and measured. The measured and simulated results were in good agreement. A gain of 9.1 to 9.9 dBi was measured. [ABSTRACT FROM AUTHOR]

Published

2024

43. Low-Noise Amplifier with Bypass for 5G New Radio Frequency n77 Band and n79 Band in Radio Frequency Silicon on Insulator Complementary Metal–Oxide Semiconductor Technology.

Author

Kim, Min-Su and Yoo, Sang-Sun

Subjects

*LOW noise amplifiers, *SEMICONDUCTOR technology, *5G networks, *SILICON

Abstract

This paper presents the design of a low-noise amplifier (LNA) with a bypass mode for the n77/79 bands in 5G New Radio (NR). The proposed LNA integrates internal matching networks for both input and output, combining two LNAs for the n77 and n79 bands into a single chip. Additionally, a bypass mode is integrated to accommodate the flexible operation of the receiving system in response to varying input signal levels. For each frequency band, we designed a low-noise amplifier for the n77 band to expand the bandwidth to 900 MHz (3.3 GHz to 4.2 GHz) using resistive–capacitance (RC) feedback and series inductive-peaking techniques. For the n79 band, only the RC feedback technique was employed to optimize the performance of the LNA for its 600 MHz bandwidth (4.4 GHz to 5.0 GHz). Because wideband techniques can lead to a trade-off between gain and noise, causing potential degradation in noise performance, appropriate bandwidth design becomes crucial. The designed n77 band low-noise amplifier achieved a simulated gain of 22.6 dB and a noise figure of 1.7 dB. Similarly, the n79 band exhibited a gain of 21.1 dB and a noise figure of 1.5 dB with a current consumption of 10 mA at a 1.2 supply voltage. The bypass mode was designed with S21 of −3.7 dB and −5.0 dB for n77 and n79, respectively. [ABSTRACT FROM AUTHOR]

Published

2024

44. A dual‐band tightly arranged multiple‐input multiple‐output antenna pair for 5G mobile terminals.

Author

Li, Bingying, Zhao, Xing, Huang, Qishen, Hu, Minghao, Zhu, Xinyu, and Ying, Haoming

Subjects

*ANTENNAS (Electronics), *MULTIFREQUENCY antennas, *PLANAR antennas, *5G networks, *CELL phones, *MIMO systems

Abstract

This paper presents a dual‐band multiple‐input multiple‐output (MIMO) antenna pair for 5G cell phones. The antenna pair consists of two planar concave antenna elements that are tightly arranged on a vertical substrate. By adding capacitors to form a resonant network, an additional operating mode is excited, resulting in dual‐band performance. The resonant frequency of the additional mode can be adjusted independently by changing the capacitance value. Moreover, a neutralization line is used to improve the isolation of the high band without affecting the low band. The antenna pair occupies a small area of 13.2 × 6.3 mm2 and operates at both 3.5 and 4.85 GHz bands. The isolations are better than 17 dB at the 3.5 GHz band and better than 19 dB at the 4.85 GHz band. The proposed dual‐band antenna pair might be a good choice for 5G terminals. [ABSTRACT FROM AUTHOR]

Published

2024

45. Reconfigurable SIW antenna at 28/38 GHz for 5G applications.

Author

Balarajuswamy, T. A. and Nakkeeran, R.

Abstract

A Substrate Integrated Waveguide (SIW) antenna has been presented here with a single element, which could be effectively tuned betwixt 28 and 38 GHz. By turning off one of the two PIN diodes, which were utilized as switches, a change is achieved in the antenna's resonant frequency as of 28–38 GHz. Additionally, two separate frequencies will be obtained whilst flipping both switches off. In the antenna design, there is sufficient gain along with efficiency to gratify 5G requirements. This could be accomplished by altering the antenna's SIW layout. An inset curvature has been featured by both the ends betwixt the tapered section and the SIW cavity, which alters the structure. As a result of the tapered section, superior impedance matching is achieved. A wide range of possible configurations has been offered by this reconfigurable SIW antenna by utilizing the Roger 5880 substrate along with a K-type connector input. The antenna responds with 7.16 dBi of gain and 94% efficiency at 28 GHz when S1 is disabled and S2 is enabled. Similarly, the antenna responds with a gain of 10 dBi and an efficiency of 88% at 38 GHz when S1 is on and S2 is off. When every PIN diode are turned off, the antenna enhances by 7.09 dBi for 28 GHz whereas it improves by 10.7 dBi for 38 GHz. To run the simulations, the CST Studio Suite was utilized; subsequently, the outcomes obtained are in good agreement with the predictions made by the program. [ABSTRACT FROM AUTHOR]

Published

2023

46. Eight-Element Dual-Band Multiple-Input Multiple-Output Mobile Phone Antenna for 5G and Wireless Local Area Network Applications.

Author

He, Tao, Huang, Jianlin, Lu, Jiaping, Shi, Xiaojing, and Liu, Gui

Subjects

WIRELESS LANs, MOBILE antennas, CELL phones, 5G networks, ANTENNAS (Electronics), MICROSTRIP transmission lines

Abstract

This paper proposes an eight-element dual-band multiple-input multiple-output (MIMO) antenna that operates in the fifth generation (5G), n78 (3400–3600 MHz), and WLAN (5275–5850 MHz) bands to accommodate the usage scenarios of 5G mobile phones. The eight antenna elements are printed on two long frames, which significantly reduce the usage of the internal space of the mobile phone. Each antenna element is printed on both surfaces of one frame, which consists of a radiator on the internal surface and a defected ground plane on the outer surface. The radiator is a rectangular ring fed by a 50 Ω microstrip line which is printed on the top surface of the system board. A parasitic unit is printed on the outer surface of each frame, which is composed of an inverted H-shaped and four L-shaped patches. Each parasitic unit is connected to the internal surface of the frames through a via, and then it is connected to a 1.5 mm wide microstrip line on the top surface of the system board, which is connected to the ground plane on the bottom surface of the system board by a via. Four L-shaped slots, four rectangular slots, and four U-shaped slots are etched onto the system board, which provides good isolation between the antenna elements. Two merged rectangular rings are printed on the center of each frame, which improves the isolation further. The return loss is better than 6 dB, and the isolation between the units is better than 15 dB in the required working frequency bands. In addition, the use of a defected ground structure not only makes the antenna element obtain better isolation but also improves the overall working efficiency. The measurement results show that the proposed MIMO antenna structure can be an ideal solution for 5G and WLAN applications. [ABSTRACT FROM AUTHOR]

Published

2023

47. ComputerModelling of Compact 28/38 GHz Dual-Band Antenna for Millimeter-Wave 5G Applications.

Author

Patel, Amit V., Desai, Arpan, Elfergani, Issa, Mewada, Hiren, Zebiri, Chemseddine, Mahant, Keyur, Rodriguez, Jonathan, and Abd-Alhameed, Raed

Abstract

A four-element compact dual-band patch antenna having a common ground plane operating at 28/38 GHz is proposed for millimeter-wave communication systems in this paper. The multiple-input-multiple-output (MIMO) antenna geometry consists of a slotted ellipse enclosed within a hollow circle which is orthogonally rotated with a connected partial ground at the back. The overall size of the four elements MIMO antenna is 2.24λ x 2.24λ (at 27.12GHz). The prototype of four-element MIMO resonator is designed and printed using Rogers RTDuroid 5880 with εr = 2.2 and loss tangent = 0.0009 and having a thickness of 0.8 mm. It covers dual-band having a fractional bandwidth of 15.7% (27.12-31.34 GHz) and 4.2% (37.21-38.81 GHz) for millimeter-wave applications with a gain of more than 4 dBi at both bands. The proposed antenna analysis in terms of MIMO diversity parameters (Envelope Correlation Coefficient (ECC) and Diversity Gain (DG)) is also carried out. The experimental result in terms of reflection coefficient, radiation pattern, gain and MIMO diversity parameter correlates very well with the simulated ones that show the potential of the proposed design for MIMO applications at millimeter-wave frequencies. [ABSTRACT FROM AUTHOR]

Published

2023

48. Modeling of disaster resilience 5G fronthaul/backhaul hybrid ring-mesh topology based PON/FSO system using 2D-modified FRS code.

Author

Kumari, Meet

Subjects

*FREE-space optical technology, *PASSIVE optical networks, *DISASTER resilience, *HYBRID systems, *BIT error rate, *SIGNAL-to-noise ratio, *5G networks

Abstract

This work presents a hybrid ring-mesh topology based passive optical network with free space optics (PON/FSO) model for bidirectional transmission at 10 × 10/10Gbps throughput to offer information to the fiber-FSO subscribers simultaneously with enhanced disaster resilience and fault protection capability. Fiber impairments, FSO link weather and turbulent conditions' tolerance can be enhanced by using a new two-dimensional modified fixed right shifting (2D-MFRS) code for upstream and downstream transmission through integrated fiber-FSO links. A PON/FSO model using 2D-MFRS code is a promising network that raises the network reliability, security and survivability, especially in rural places where the core fibre link may be damaged or destroyed. The obtained numerical and simulation results show that proposed model provides 90–130 km fiber range with fixed 100 m FSO range. FSO range of 850–1900 m with fixed 10 km fiber length can be obtained concerning weak-to-strong turbulent as well as distinct weather conditions. Also, hybrid ring-mesh topology is able to sustain −11 to −18dBm receiver sensitivities in wired-wireless transmission. The proposed model is also capable to handle 130 to 160 subscribers at symmetric 50Gbps/channel throughput. At acceptable bit error rate, low power penalty of 1 dB and −24 dB power budget are observed between back-to-back and integrated fiber-FSO link. Additionally, high signal to noise ratio of 95 dB can be maintained effectively by the system supporting 10 optical units per remote node and it also shows successful transmission upto 1:64 split ratio. Finally, the comparative literature work reveals that the proposed model offers security, long-reach, high transmission rate, and cost-effectiveness for fifth generation fronthaul/backhaul networks. [ABSTRACT FROM AUTHOR]

Published

2023

49. Evaluation of 5G techniques affecting the deployment of smart hospital infrastructure: Understanding 5G, AI and IoT role in smart hospital.

Author

Kumar, Arun, Nanthaamornphong, Aziz, Selvi, R., Venkatesh, J., Alsharif, Mohammed H., Uthansakul, Peerapong, and Uthansakul, Monthippa

Subjects

PUBLIC hospitals, 5G networks, ORTHOGONAL frequency division multiplexing, VIDEO monitors, ARTIFICIAL intelligence, INTERNET of things, HEALTH facilities, STREAMING video & television

Abstract

Smart Hospital will play a key role in improving the quality of services (QoS) related to the health sector. In the present scenario, it is impossible to accommodate an ageing population with the current infrastructure and facilities provided by conventional hospitals. However, the integration of technologies with the conventional hospital is enhancing the medical services and also making it easier for the public, who can save time and money by getting all the necessary medical facilities while sitting at home. The deployment of the fifth generation (5G) is taking place all over the world. The 5G network offers a better service that can be used in hospitals to make it a smart health service provider with online facilities such as video monitoring, suggesting a proper medical prescription based on medical data, remote surgery, and so on. High bandwidth, a fast data rate, low latency, and a low peak-to-average power ratio (PAPR) are some requirements that need to be fulfilled by the 5G radio. In this work, we focus on improving the power savings, spectral access, latency, and Bit error rate (BER) of the advanced 5G waveforms such as non-orthogonal multiple access (NOMA), filter bank multi carrier (FBMC), and orthogonal frequency division multiplexing (OFDM). In the first part of the article, we proposed a PAPR reduction algorithm to improve the power efficiency of the power amplifier (PA) for 5G waveforms. Several algorithms are applied to the 5G waveforms, and their performances are estimated in terms of PAPR curves. In the second part, we have utilised advanced detection algorithms to improve the signal detection of the 5G waveforms. The simulation results reveal that the proposed algorithms efficiently enhance the throughput of the framework. In the third part, we improve the spectral efficiency of the 5G waveforms by applying spectrum sensing (SS) algorithms. It is seen that the SS methods efficiently reduce the spectrum leakage of the multi-carrier waveforms (MCW). Finally, we examined the role and challenges of the Internet of Things (IoT) and artificial intelligence (AI) in smart hospitals. Overall, it is concluded that hospitals can become more effective, cut expenses, and provide better patient care with the aid of AI and IoT. Hospitals can improve patient outcomes and the state of the healthcare system as a whole by utilising these technologies. [ABSTRACT FROM AUTHOR]

Published

2023

50. 5G NR, Wi-Fi 6, and Bluetooth LE 5 Introduction

Author

Morais, Douglas H. and Morais, Douglas H

Published

2023