Nowadays, the world is turning into technology, fast internet and high signal quality. To ensure high signal quality, the network planners have to predict the pathloss and signal strength of the transmitted signal at specific distances in the design stage. The aim of this research is to provide a generalized pathloss model to suit the urban area in Muscat Governorate in the Sultanate of Oman. The research covers 5G network pathloss in the Muttrah Business District (MBD) area. It includes Close In (CI) model and Alpha Beta Gamma (ABG) model with 3.45GHz. The results of 5G models were compared with real experimental data in MBD by calculating Root Mean Square Error RMSE. Other cells at MBD area were used for reverification.  To validate the modified pathloss models of 5G, they were applied at different cells in Alkhoud area. Furthermore, this paper also deals the effect of Specific Absorption Rate (SAR) on the human brain for ensuring safety due to close proximity to cell towers. The SAR values were calculated indirectly from the electric field strength of different antennas. Calculated results were compared with the international standards defined limits on the human brain.

G. Barb and M. Otesteanu, "4G/5G: A Comparative Study and Overview on What to Expect from 5G," in 2020 43rd International Conference on Telecommunications and Signal Processing (TSP), 2020, pp. 37-40.

W. Jiang, B. Han, M. A. Habibi, and H. D. Schotten, "The Road Towards 6G: A Comprehensive Survey," IEEE Open Journal of the Communications Society, vol. 2, pp. 334-366, 2021.

Z. Nadir, H. A. Lawati, and M. A. Rashdi, "Propagation Measurements and Pertinency of Models for Communications Systems in Oman " American Journal of Science & Engineering (AJSE), vol. 1, p. xxxxx, 2020.

M. H. Mahmud, K. Khaleduzzaman, S. Sarker, and L. C. Paul, "Effect of Path Loss Models on Performance of 5G Compatible MIMO WINDOW-OFDM Systems," in 2020 International Conference on Smart Technologies in Computing, Electrical and Electronics (ICSTCEE), 2020, pp. 257-262.

A. Zreikat and M. Djordjevic, "Performance Analysis of Path loss Prediction Models in Wireless Mobile Networks in Different Propagation Environments," in Proceedings of the 3rd World Congress on Electrical Engineering and Computer Systems and Science (EECSS'17), Rome, Italy, 2017, pp. 103-1-103-11.

F. Qamar, T. Abbas, M. N. Hindia, K. B. Dimyati, K. A. B. Noordin, and I. Ahmed, "Characterization of MIMO propagation channel at 15 GHz for the 5G spectrum," in 2017 IEEE 13th Malaysia International Conference on Communications (MICC), 2017, pp. 265-270.

Z. Nadir and H. A. Lawati, "LTE path-loss prediction models' comparative study for outdoor wireless communications," in 7th Brunei International Conference on Engineering and Technology 2018 (BICET 2018), 2018, pp. 1-4.

Z. Nadir and M. Bait-Suwailam, "Pathloss Analysis at 900 MHz for Outdoor Environment," presented at the International Conference on Communications, Signal Processing and Computers, 2014.

Y. Li and M. Lu, "Study on SAR Distribution of Electromagnetic Exposure of 5G Mobile Antenna in Human Brain," 2020.

J. Michalowska, A. Wac-Włodarczyk, and J. Kozieł, "Monitoring of the Specific Absorption Rate in Terms of Electromagnetic Hazards," Journal of Ecological Engineering, vol. 21, pp. 224-230, 2020.

A. D. Sonawane and D. S. Bormane, "A Specific Absorption Rate in Human Head due to Mobile Phone Radiations: Review," in 2020 International Conference on Electronics and Sustainable Communication Systems (ICESC), 2020, pp. 703-707.

A. Karunarathna, C. A. Fernando, and P. Samarasekara, "Effect of shape, size and electrical properties on specific absorption rate (SAR)," International Journal of Research and Engineering, vol. 6, 06/01 2019.

Y. Zhang, S. Jyoti, C. R. Anderson, D. J. Love, N. Michelusi, A. Sprintson, et al., "28-GHz Channel Measurements and Modeling for Suburban Environments," in 2018 IEEE International Conference on Communications (ICC), 2018, pp. 1-6.

M. Hamid, "Measurement Based Statistical Model for Path Loss Prediction for Relaying Systems Operating in 1900 MHz Band," Doctorate, Semantic Scholar, 2014.

T. S. Rappaport, Wireless Communications Principles and Practice: Prentice Hall, 2002.

ITU, "Propagation data and prediction methods for the planning of short-range outdoor radiocommunication systems and radio local area networks in the frequency range 300 MHz to 100 GHz," ed. USA: Internatinal Telecommunication Union, 2017, pp. 1-54.

A. Rashid O. Mumi, R. Alias, J. Abdullah, S. Haimi Dahlan, and J. Ali, "Assessment of Electromagnetic Absorption towards Human Head Using Specific Absorption Rate," 2018, vol. 7, p. 8, 2018-12-01 2018.

I. C. Society., "IEEE Standard for Safety Levels with Respect to Human Exposure to Electric, Magnetic, and Electromagnetic Fields, 0 Hz to 300 GHz," IEEE Std C95.1-2019 (Revision of IEEE Std C95.1-2005/ Incorporates IEEE Std C95.1-2019/Cor 1-2019), pp. 1-312, 2019.

ICNIRP, "Guidelines for limiting exposure to time-varying electric, magnetic, and electromagnetic fields (up to 300 GHz). International Commission on Non-Ionizing Radiation Protection," Health Phys, vol. 74, pp. 494-522, Apr 1998.

I. A. Maawali, "Assessment of Electromagnetic Fields Exposure of Telecom Sites," T. R. A. Oman, Ed., ed, 2020.

MASCHEK, "SAR meter ESM 120," ed. Germany, 2007.

H. A. Jalal Baayer, "Invention of an Original Tetra-Generations Patch Antenna for the New Generation of Mobile Telephony and the Study of the Thermal Effect of GSM on the Human Head and Hand," presented at the Proceedings of the Third International Conference on Computing and Wireless Communication Systems, ICCWCS 2019, Faculty of Sciences, Ibn Tofaïl University -Kénitra- Morocco, 2019.

Giangrandi. (2012, 20 February 2021). Field generated by a transmitter at a given distance. Available: https://www.giangrandi.ch/electronics/anttool/tx-field.shtml

T. B. Rashid and H. H. Song, "Analysis of biological effects of cell phone radiation on human body using specific absorption rate and thermoregulatory response," Microwave and Optical Technology Letters, vol. 61, pp. 1482-1490, 2019/06/01 2019.

N. Carrara. (28 Januyary 2021). Dielectric Properties of Body Tissues in the frequency range 10 Hz - 100 GHz. Available: http://niremf.ifac.cnr.it/tissprop/#over