RF-EMF Exposure Measurement for 5G Over Mm-Wave Base Station With MIMO Antenna

Wali, Sangin Qahtan; Sali, Aduwati; Allami, Jaafar K.; Osman, Anwar Faizd

doi:10.1109/access.2022.3143805

Cited by 31 publications

(36 citation statements)

References 37 publications

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“…The obtained results show that the maximum TER is very low compared to the ICNIRP limit, specifically it is 10.5×10 -5 for the dense area, 8.8×10 -5 for the urban area site, 6.2×10 -5 for the suburban area, and 5.6×10 -5 for the rural area. These results are in agreement with the studies published in [17,23,[29][30][31][32][33][34][35][36]. Of note, these studies were focused on assessment for one technology, and in this work, the results present the accumulated TER.…”

Section: Exposure Ratios and Ter Resultssupporting

confidence: 91%

“…The 800 MHz results include the combined power density for both 4G-FDD-LTE and NB-IoT. For the four scenarios (dense, urban, suburban, and rural), the obtained results show that the power densities from all technologies (2G/3G/4G/5G) are low compared to the reference limit, which is consistent with the results of previously published studies [17,23,[29][30][31][32][33][34][35][36] related to this work. For the dense area site, as shown in FIGURE 10, the total power densities trend with increasing distance from the site.…”

Section: B Power Density Resultssupporting

confidence: 90%

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Measurement and Simulation-Based Exposure Assessment at a Far-Field for a Multitechnology Cellular Site up to 5G NR

2022

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5G is expected to be the dominant technology for mobile networks in the coming years, but there is concern about the increase in the total electromagnetic field radiation levels due to the deployment of the 5G technology. This paper presents an exposure assessment of electromagnetic field radiation on humans from single base station of a mobile network serving in dense, urban, suburban, and rural area scenarios for single-site transmission with multi-technology, including 2G, 3G, 4G, IoT, and 5G which have recently been deployed. This assessment is performed using simulation to predict the received signal levels and to calculate the related power densities for a typical single site under operating field configurations and settings for each technology. Field measurements were performed using a drive test tool to validate and calibrate the simulation results. The results show the total exposure ratio was very low compared to the international standard exposure limits, and the results show the contribution from each technology for these spesfic sites used in this study.

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Section: Exposure Ratios and Ter Resultssupporting

confidence: 91%

Section: B Power Density Resultssupporting

confidence: 90%

Measurement and Simulation-Based Exposure Assessment at a Far-Field for a Multitechnology Cellular Site up to 5G NR

2022

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“…Focusing on commercial mm-Wave deployments, very few works [9], [10] measure the EMF from operative mm-Wave BSs, mainly due to the fact that 5G mm-Wave deployments have been installed very recently -and still not pervasively in the world. Therefore, the assessment of exposure from such deployments is a novelty in the field.…”

Section: B Exposure From 5g Mm-wave Deploymentsmentioning

confidence: 99%

“…Wali et al [10] measure the exposure from a mm-Wave BS, by exploiting a measurement chain composed of a network scanner, a down-converter and an omni-directional antenna. A code-selective methodology, based on the extrapolation of exposure from the power collected over decoded 5G signals (like the SS-RSRP), is applied.…”

Section: B Exposure From 5g Mm-wave Deploymentsmentioning

confidence: 99%

“…At a regulation level, ground-truth measurements should demonstrate that mm-Wave exposure complies with maximum limits defined by law [7]. At the research level, then, the topic is relatively in an infancy phase, as few works face the measurement of mm-Wave BS exposure in precommercial 5G deployments (see e.g., [8]), and very few in commercial ones [9], [10]. In addition, the definition of EMF measurement methodologies tailored to the mm-Wave domain is of interest for both international and national exposure standardization bodies, which define the procedures to assess the exposure compliance against the maximum EMF limits [11], [12].…”

Section: Introductionmentioning

confidence: 99%

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EMF Exposure in 5G Standalone mm-Wave Deployments: What Is the Impact of Downlink Traffic?

Chiaraviglio

Lodovisi

Franci

et al. 2022

IEEE Open J. Commun. Soc.

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The rolling-out of 5G networks is recently including 5G Base Stations (BSs) operating on millimeter-Wave (mm-Wave) frequencies. The goal of this work is to shed light on the exposure assessment from commercial 5G mm-Wave 5G BSs, by focusing on the impact of downlink traffic on the exposure levels. To this aim, we adopt an innovative measurement framework, based on hardware and software components, able to satisfy the challenging measurement requirements of mm-Wave frequencies. In addition, we design a completely softwarized algorithm, called M-WAVE, in order to measure the mm-Wave exposure with a programmable spectrum analyzer. Results, obtained from a commercial 5G scenario, reveal that the exposure from the mm-Wave BS is directly proportional to the amount of traffic injected on the wireless link. However, the electric field is always lower than 0.08 V/m, while the downlink traffic is even larger than 800 Mbps.

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Electromagnetic field exposure monitoring of commercial 28‐GHz band 5G base stations in Tokyo, Japan

Liu,

Tobita,

Onishi

et al. 2024

Bioelectromagnetics

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Fifth generation (5G) wireless communication is being rolled out around the world. In this work, the latest radio frequency electromagnetic field (EMF) exposure measurement results on commercial 28‐GHz band 5G base stations (BSs) deployed in the urban area of Tokyo, Japan, are presented. The measurements were conducted under realistic traffic conditions with a 5G smartphone and using both omnidirectional and horn antennas. First and foremost, in all cases, the electric‐field (E‐field) intensity is much lower (<−38 dB) than the exposure limits. The E‐field intensities for traffic‐off cases do not show any significant difference between the two antennas with the maximum being 3.6 dB. For traffic‐on cases, the omnidirectional antenna can undesirably capture the radio wave from the smartphone in some cases, resulting in a 7–13 dB higher E‐field intensity than that using the horn antenna. We also present comparative results between 4G long term evolution BSs and sub‐6‐GHz band and 28‐GHz band 5G BSs and provide recommendations on acquiring meaningful EMF exposure data. This work is a further step toward the standardization of the measurement method regarding quasi‐millimeter/millimeter wave 5G BSs.

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RF-EMF Exposure Measurement for 5G Over Mm-Wave Base Station With MIMO Antenna

Cited by 31 publications

References 37 publications

Measurement and Simulation-Based Exposure Assessment at a Far-Field for a Multitechnology Cellular Site up to 5G NR

Measurement and Simulation-Based Exposure Assessment at a Far-Field for a Multitechnology Cellular Site up to 5G NR

EMF Exposure in 5G Standalone mm-Wave Deployments: What Is the Impact of Downlink Traffic?

Electromagnetic field exposure monitoring of commercial 28‐GHz band 5G base stations in Tokyo, Japan

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