In this paper, Recommendation ITU-R P.526-13 rounded edge diffraction loss method is used to determine the diffraction loss over a double edged hilltop in the path of 6 GHz C-band microwave signal. The computation is based on the path profile with path length of 6188.665 m. The path profile has maximum elevation of 412.75 m and it occurred at a distance of 2877.3 m from the transmitter. The line of sight clearance height is 35.393521m and occultation distance is 532.203m. The diffraction loss computed for the double edged hilltop using the Recommendation ITU-R P.526-13 model is 42.563065 dB.
| Published in | American Journal of Software Engineering and Applications (Volume 6, Issue 2) |
| DOI | 10.11648/j.ajsea.20170602.18 |
| Page(s) | 56-60 |
| Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
| Copyright |
Copyright © The Author(s), 2017. Published by Science Publishing Group |
Diffraction Loss, Diffraction Parameter, Doubled Edged Hill, ITU-R P.526-13 Method, Rounded Edge Diffraction
| [1] | Mahafza, B. R. (2016). Radar signal analysis and processing using MATLAB. CRC Press. |
| [2] | Bai, T., & Heath, R. W. (2015). Coverage and rate analysis for millimeter-wave cellular networks. IEEE Transactions on Wireless Communications, 14 (2), 1100-1114. |
| [3] | Pyattaev, A., Johnsson, K., Andreev, S., & Koucheryavy, Y. (2015). Communication challenges in high-density deployments of wearable wireless devices. IEEE Wireless Communications, 22 (1), 12-18. |
| [4] | Sachdeva, N., & Sharma, D. (2012). Diversity: A fading reduction technique. International Journal of Advanced Research in Computer Science and Software Engineering, ISSN. |
| [5] | Patwari, N. ECE 5325/6325: Wireless Communication Systems Lecture Notes, Spring 2010. |
| [6] | Gunnarsson, F., Amirijoo, M., & Moe, J. (2016). U. S. Patent No. 9,264,919. Washington, DC: U. S. Patent and Trademark Office. |
| [7] | Pradhan, C., & Murthy, G. R. (2015). Analysis of Path Loss mitigation through Dynamic Spectrum Access: Software Defined Radio. arXiv preprint arXiv: 1510.04772. |
| [8] | Sai Sanath Kumar, K., Reddy, K. N. K., Pushpavathy, V., Reddy, P. R., Sharma, D., Sharma, P. K., & Krishna, B. V. (2016). Calculation of Path Losses at CM3 for Wireless Body Area Networks (WBAN) by using Different Types of Antennas. International Journal of Applied Engineering Research, 11 (7), 5210-5217. |
| [9] | Agrawal, S., Gupta, N., & Shrivastava, M. (2016). Impact of GSM Spectrum Auction in 900 & 1800 MHz Band. International Transactions on Electronics and Communication Engineering, 1 (1), 18-27. |
| [10] | Malila, B., Falowo, O., & Ventura, N. (2015, September). Millimeter wave small cell backhaul: An analysis of diffraction loss in NLOS links in urban canyons. In AFRICON, 2015 (pp. 1-5). IEEE. |
| [11] | Saman, M. A., Ismail, A. F., Badron, K., Ramli, H. A. M., Hashim, W., & Fakrullah, A. N. A. (2015). Development of Spectrum Management Tool for Malaysia Using Open-Source GIS Software. In Theory and Applications of Applied Electromagnetics (pp. 127-135). Springer International Publishing. |
| [12] | Vargas, T. A. A., Peña, J. E. A., Medina, J. G. B., Pulido, J. D. Z., & Peñaloza, M. L. S. (2015, October). Configuration of propagation models for computational simulation of different telecommunications services. In Engineering Applications-International Congress on Engineering (WEA), 2015 Workshop on (pp. 1-6). IEEE. |
| [13] | Jude, O. O., Jimoh, A. J., & Eunice, A. B. (2016). Software for Fresnel-Kirchoff Single Knife-Edge Diffraction Loss Model. Mathematical and Software Engineering, 2 (2), 76-84. |
| [14] | Adebayo, T. L., & Edeko, F. O. (2007). Investigation and Modeling of Diffraction Loss at 1.8 GHZ in a Mountainous Terrain: A Case Study of Olumo Rock, Abeokuta, Nigeria. Research Journal of Applied Sciences, 2 (1), 60-64. |
| [15] | Baldassaro, P. M. (2001). RF and GIS: Field Strength Prediction for Frequencies between 900 MHz and 28 GHz. |
| [16] | Parsons, J. D., & Parsons, P. J. D. (2000). The mobile radio propagation channel. Second edition. John Wiley & Sons. |
| [17] | Hacking, K. U. H. F. (1968). Propagation over rounded hills. BBC Research Department. Research Report No. RA-21, 30. |
| [18] | Rice, P. L., Longley, A. G., Norton, K. A., & Barsis, A. P. (1967). Transmission Loss Predictions For Tropospheric Communication Circuits, Volume 1. Institute For Telecommunication Sciences And Aeronomy Boulder Co |
| [19] | Wait JR Conda AM (1959) Diffraction of electromagnetic waves by smooth obstacles for grazing angles. Journal of Research of the N. B. S. vol 63D |
| [20] | ITU-R P.526-13 (11/2013) Propagation by Diffraction. Available online at: http://www.itu.int/rec/RREC-P.526-13-201311-I |
| [21] | Barué, G. (2008). Microwave engineering: land & space radiocommunications (Vol. 9). John Wiley & Sons. |
| [22] | De Assis, M. (1971). A simplified solution to the problem of multiple diffraction over rounded obstacles. IEEE Transactions on Antennas and Propagation, 19 (2), 292-295. |
APA Style
Ogungbemi Emmanuel Oluropo, Ikechukwu H. Ezeh, Chibuzo Promise Nkwocha. (2017). Determination of Diffraction Loss over Isolated Doubled Edged Hill Using the ITU-R P.526-13 Method for Rounded Edge Diffraction. American Journal of Software Engineering and Applications, 6(2), 56-60. https://doi.org/10.11648/j.ajsea.20170602.18
ACS Style
Ogungbemi Emmanuel Oluropo; Ikechukwu H. Ezeh; Chibuzo Promise Nkwocha. Determination of Diffraction Loss over Isolated Doubled Edged Hill Using the ITU-R P.526-13 Method for Rounded Edge Diffraction. Am. J. Softw. Eng. Appl. 2017, 6(2), 56-60. doi: 10.11648/j.ajsea.20170602.18
AMA Style
Ogungbemi Emmanuel Oluropo, Ikechukwu H. Ezeh, Chibuzo Promise Nkwocha. Determination of Diffraction Loss over Isolated Doubled Edged Hill Using the ITU-R P.526-13 Method for Rounded Edge Diffraction. Am J Softw Eng Appl. 2017;6(2):56-60. doi: 10.11648/j.ajsea.20170602.18
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Download@article{10.11648/j.ajsea.20170602.18,
author = {Ogungbemi Emmanuel Oluropo and Ikechukwu H. Ezeh and Chibuzo Promise Nkwocha},
title = {Determination of Diffraction Loss over Isolated Doubled Edged Hill Using the ITU-R P.526-13 Method for Rounded Edge Diffraction},
journal = {American Journal of Software Engineering and Applications},
volume = {6},
number = {2},
pages = {56-60},
doi = {10.11648/j.ajsea.20170602.18},
url = {https://doi.org/10.11648/j.ajsea.20170602.18},
eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.ajsea.20170602.18},
abstract = {In this paper, Recommendation ITU-R P.526-13 rounded edge diffraction loss method is used to determine the diffraction loss over a double edged hilltop in the path of 6 GHz C-band microwave signal. The computation is based on the path profile with path length of 6188.665 m. The path profile has maximum elevation of 412.75 m and it occurred at a distance of 2877.3 m from the transmitter. The line of sight clearance height is 35.393521m and occultation distance is 532.203m. The diffraction loss computed for the double edged hilltop using the Recommendation ITU-R P.526-13 model is 42.563065 dB.},
year = {2017}
}
TY - JOUR T1 - Determination of Diffraction Loss over Isolated Doubled Edged Hill Using the ITU-R P.526-13 Method for Rounded Edge Diffraction AU - Ogungbemi Emmanuel Oluropo AU - Ikechukwu H. Ezeh AU - Chibuzo Promise Nkwocha Y1 - 2017/06/12 PY - 2017 N1 - https://doi.org/10.11648/j.ajsea.20170602.18 DO - 10.11648/j.ajsea.20170602.18 T2 - American Journal of Software Engineering and Applications JF - American Journal of Software Engineering and Applications JO - American Journal of Software Engineering and Applications SP - 56 EP - 60 PB - Science Publishing Group SN - 2327-249X UR - https://doi.org/10.11648/j.ajsea.20170602.18 AB - In this paper, Recommendation ITU-R P.526-13 rounded edge diffraction loss method is used to determine the diffraction loss over a double edged hilltop in the path of 6 GHz C-band microwave signal. The computation is based on the path profile with path length of 6188.665 m. The path profile has maximum elevation of 412.75 m and it occurred at a distance of 2877.3 m from the transmitter. The line of sight clearance height is 35.393521m and occultation distance is 532.203m. The diffraction loss computed for the double edged hilltop using the Recommendation ITU-R P.526-13 model is 42.563065 dB. VL - 6 IS - 2 ER -
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