Performance Analysis of Path Loss Prediction Models on Very High Frequency Spectrum

Omenka E.  Jackson; Muhammad Uthman; Sadiq Umar

doi:10.24018/ejeng.2022.7.2.2783

Research Article

Omenka E. Jackson

Federal Radio Corporation of Nigeria (FRCN), Nigeria

* Corresponding author

Muhammad Uthman

University of Abuja, Nigeria

Sadiq Umar

Nigeria Airspace Development Agency, Nigeria

10.24018/ejeng.2022.7.2.2783

Read Counter
825

Downloads
593

Citations

Share

Submitted 2022-03-16
Published 2022-04-06

Read counter = 825 times

Abstract

Implementations of Radio frequency wave propagation models are necessary to determine propagation characteristics through a medium. Its study provides an estimation of signal characteristics and the effect of environment and the medium over which it travels. This paper performs some analysis on few empirical Propagation models the mechanisms, their path loss behavior suitable for path loss prediction techniques in broadcast communication. Experimental measurements of received signal strength indication for the 92.9 MHz Radio broadcasting Station were made in urban areas of Federal Capital Territory Abuja, Nigeria. Measured data were compared with those obtained by three prediction models: COST-231, ECC-33 and OKUMURA-HATA models, the results show that in general the ECC-33 Model over-predicted the path loss in all environments with Root Means Square error (RMSE) of 166.46, while the COST-231 model has 18.33 having the best results. Okumura-Hata predicted well in the near field with 16.50 and deviated from measured data at the far field. The prediction analysis also accessed the Received Signal Strength Indication of Kapital FM in twenty (20) locations in Abuja; hence, it identifies Route A to be less susceptible to signal attenuation as compared to Route B.

Keywords: Path Loss; Radio Broadcast Station; Signal.

References

Electronics-notes.com. Radio Signal Path loss. Incorporating Radio-Electronics.com, [Online]. Available: https://www.electronics-notes.com/articles/antennas-propagation/propagation-overview/radio-signal-path-loss.php. [Accessed 18 July 2019].
Google Scholar

Parasad M., Sain M., and Reddy B. M. Effect of Obstacles on VH TV Signal Propagation. IEEE Transactions on Broadcasting, 1990;36(3): 234-241.
Google Scholar

FCMCVlab and iitkjp. Understand The Pathloss Prediction Fomular. [Online]. Available: http://fcmcvlab.iitkgp.ac.in/Exp1/Theory/expt1-theory.pdf. [Accessed 18 July 2019].
Google Scholar

Ai Yun, Anderson Jorgen Bach, Cheffena Micheal. Path Loss Prediction for an Industrial Indoor Environment Based on Room Electromagnetics. IEEE, 2017:1-2.
Google Scholar

CK-12. CK-12. [Online]. Available: https://www.ck12.org/book/ck-12-physical-science-for-middle-school/section/19.3/. [Accessed 17 September 2019].
Google Scholar

Albregtsen F. Reflection, Rfraction, Differaction and Scattering. 2008. [Online]. Available: https://www.uio.no/studier/emner/matnat/ifi/INF-GEO4310/h09/undervisningsmateriale/imaging-kap2.pdf. [Accessed 27 September 2019].
Google Scholar

Wikipedia. Attenuation. Wikipedia Organization, 17 February 2022. [Online]. Available: https://en.wikipedia.org/wiki/Attenuation. [Accessed 04 March 2022].
Google Scholar

Dieter J. Cichon 1, Ibp Pietzsch GmbH, Thomas Kürner 1, E-Plus Mobilfunk GmbH, "COST 231 Final Report," in Propagation Prediction Models, Germany.
Google Scholar

Vuran M. C. and Silva A. R. Communication Through Wireless Underground Sensor Networks- Theory and Practical. Soilscape, 2010; M. Can Vuran and Agnelo R. Silva: 314.
Google Scholar

Nupur, "idconline," [Online]. Available: http://www.idc-online.com/technical_references/pdfs/electronic_engineering/Free_Space_Loss.pdf. [Accessed 25 July 2019].
Google Scholar

Collins. The free dictionary. Harpercollins Publishers, 2014. [Online]. Available: www.thefreedictionary.com/multipath. [Accessed 25 July 2019].
Google Scholar

Gomes Igor Ruiz, Gomes Cristiane Ruiz, Gomes Herminio, Gavalcante Gervasio Protasio dos Santos. Emperical Radio Propagation Model for DTV Applied to non Homogenious Paths and Different Climates Using Machine Learning Techniques. peer review, 2018.
Google Scholar

Nwalozie G. C., Ufoaroh S. U., Ezeagwu C. O. and Ejiofor A. C. Path Loss Prediction for GSM Mobile Network for urban Region of Aba, South - East Nigeria. International Journal of science and mobile computing, 2014;3(2):267-281.
Google Scholar

Most read articles by the same author(s)

Abubakar Bawa, Muhammad Uthman, Farouq E. Shaibu, Koledowo Saliu Oyewale,
Optimal Sizing and Sitting of Distributed Generation for Power Quality Improvement of Distribution Network , European Journal of Engineering and Technology Research: Vol. 4 No. 10: OCTOBER 2019

Downloads

PDF

How to Cite

[1]

2022. Performance Analysis of Path Loss Prediction Models on Very High Frequency Spectrum. European Journal of Engineering and Technology Research. 7, 2 (Apr. 2022), 87–91. DOI:https://doi.org/10.24018/ejeng.2022.7.2.2783.

Issue

Vol. 7 No. 2 (2022)

License

This work is licensed under a Creative Commons Attribution 4.0 International License.

[1] Electronics-notes.com. Radio Signal Path loss. Incorporating Radio-Electronics.com, [Online]. Available: https://www.electronics-notes.com/articles/antennas-propagation/propagation-overview/radio-signal-path-loss.php. [Accessed 18 July 2019].
Google Scholar

[2] Parasad M., Sain M., and Reddy B. M. Effect of Obstacles on VH TV Signal Propagation. IEEE Transactions on Broadcasting, 1990;36(3): 234-241.
Google Scholar

[3] FCMCVlab and iitkjp. Understand The Pathloss Prediction Fomular. [Online]. Available: http://fcmcvlab.iitkgp.ac.in/Exp1/Theory/expt1-theory.pdf. [Accessed 18 July 2019].
Google Scholar

[4] Ai Yun, Anderson Jorgen Bach, Cheffena Micheal. Path Loss Prediction for an Industrial Indoor Environment Based on Room Electromagnetics. IEEE, 2017:1-2.
Google Scholar

[5] CK-12. CK-12. [Online]. Available: https://www.ck12.org/book/ck-12-physical-science-for-middle-school/section/19.3/. [Accessed 17 September 2019].
Google Scholar

[6] Albregtsen F. Reflection, Rfraction, Differaction and Scattering. 2008. [Online]. Available: https://www.uio.no/studier/emner/matnat/ifi/INF-GEO4310/h09/undervisningsmateriale/imaging-kap2.pdf. [Accessed 27 September 2019].
Google Scholar

[7] Wikipedia. Attenuation. Wikipedia Organization, 17 February 2022. [Online]. Available: https://en.wikipedia.org/wiki/Attenuation. [Accessed 04 March 2022].
Google Scholar

[8] Dieter J. Cichon 1, Ibp Pietzsch GmbH, Thomas Kürner 1, E-Plus Mobilfunk GmbH, "COST 231 Final Report," in Propagation Prediction Models, Germany.
Google Scholar

[9] Vuran M. C. and Silva A. R. Communication Through Wireless Underground Sensor Networks- Theory and Practical. Soilscape, 2010; M. Can Vuran and Agnelo R. Silva: 314.
Google Scholar

[10] Nupur, "idconline," [Online]. Available: http://www.idc-online.com/technical_references/pdfs/electronic_engineering/Free_Space_Loss.pdf. [Accessed 25 July 2019].
Google Scholar

[11] Collins. The free dictionary. Harpercollins Publishers, 2014. [Online]. Available: www.thefreedictionary.com/multipath. [Accessed 25 July 2019].
Google Scholar

[12] Gomes Igor Ruiz, Gomes Cristiane Ruiz, Gomes Herminio, Gavalcante Gervasio Protasio dos Santos. Emperical Radio Propagation Model for DTV Applied to non Homogenious Paths and Different Climates Using Machine Learning Techniques. peer review, 2018.
Google Scholar

[13] Nwalozie G. C., Ufoaroh S. U., Ezeagwu C. O. and Ejiofor A. C. Path Loss Prediction for GSM Mobile Network for urban Region of Aba, South - East Nigeria. International Journal of science and mobile computing, 2014;3(2):267-281.
Google Scholar

Performance Analysis of Path Loss Prediction Models on Very High Frequency Spectrum

Article Sidebar

Article Main Content

References

Most read articles by the same author(s)