The problems of mobile communication electromagnetic field exposure assessment today and tomorrow

New and necessary improvements of electromagnetic exposure assessment principles and methods are considered and presented. The electromagnetic field exposure assessment is the physical basis for hygienic and biological research and needs s to consider the new technological features of emerging 5G mobile systems in addition to existing 2-4G systems. The new generation of telecommunication networks will cause significantly novel electromagnetic field exposure, in particular for time-frequency and spatial parameters. A complex exposure assessment based on refined broadband measurements seems to be the proper and necessary approach to the enhancement of Russian EMF assessment guidelines. Simple broadband EMF measurements are the common approach for present exposure assessment and cannot be used any longer as the only measure for multiple 5G sources exposure evaluation. Then again broadband measurements are the simple and practical approach for mm wave in-situ exposure assessment. Frequency-selective and code-selective measurements provide detailed EMF level distribution in separate frequency channels, telecommunication services or sources and are a promising approach for objective exposure assessment.

electromagnetic field, radiofrequency, human exposure assessment, mobile communication, 5G NR

1. Pujol F., Manero C., Carle B., Remis S. 5G Observatory Quarterly Report 7 Up to March 2020. Available at: http://5gobservatory.eu/wp-content/uploads/2020/04/90013-5G-Observatory-Quarterly-report-7-updated-16-04-2020.pdf

2. MUK 4.3.1677–03. Determination of electromagnetic field levels created by the radiating technical means of television, FM broadcasting and land mobile radiocommunications base stations: Methodical instructions. Moscow: Russian Federation Ministry of Health; 2003 (in Russian).

3. MUK 4.3.1167–02. Determination of electromagnetic field power flux density at locations of radio systems operating in the 300 MHz-300 GHz band: Methodical instructions. Moscow: Russian Federation Ministry of Health; 2002 (in Russian).

4. ETSI TS 138 104 V15.5.0. 5G; NR; Base Station (BS) radio transmission and reception (3GPP TS 38.104 version 15.5.0 Release 15, 2019-05). https://www.etsi.org/deliver/etsi_ts/138100_138199/138104/15.05.00_60/ts_138104v150500p.pdf

5. Barnes F. S., Greenebaum B. eds. Bioengineering and Biophysical Aspects of Electromagnetic Fields. 3th ed. Boca Raton: Taylor & Francis Group, LLC; 2006.

6. IEC 62232-2017. Determination of RF field strength, power density and SAR in the vicinity of radiocommunication base stations for the purpose of evaluating human exposure. Geneva: International Electrotechnical Commission; 2017.

7. TR 62669-2019. Case studies supporting IEC 62232 — determination of RF field strength, power density and SAR in the vicinity of radiocommunication base stations for the purpose of evaluating human exposure. Geneva: International Electrotechnical Commission; 2019.

8. Aerts S. et al. In-Situ Measurement Methodology forthe Assessment of 5G NR Massive MIMO Base Station Exposure at Sub-6 GHz Frequencies. IEEE Access. 2019; 7: 184658-167. https://doi.org/10.1109/ACCESS.2019.2961225

9. Keller H. On the Assessment of Human Exposure to Electromagnetic Fields Transmitted by 5G NR Base Stations. Health Phys. 2019; 117 (5): 541–5. https://doi.org/10.1097/HP.0000000000001089

10. Electromagnetic Field (EMF) measurements near 5G mobile phone base stations. Technical Report, Ofcom, 2020. https://www.ofcom.org.uk/__data/assets/pdf_file/0015/190005/emf-test-summary.pdf