Radio wave propagation interference and compatibility analysis in ITU-R

Lin Leke; Zhang Rui; Zhao Zhenwei; Zhang Hongbo

doi:10.11884/HPLPB201931.180338

Volume 31 Issue 2

Feb. 2019

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Zhao Ying, He Jun, Wang Lin, et al. Thermal analysis and solutions of new parametric current transformer in BEPC Ⅱ[J]. High Power Laser and Particle Beams, 2018, 30: 085106. doi: 10.11884/HPLPB201830.180027

Citation:

Lin Leke, Zhang Rui, Zhao Zhenwei, et al. Radio wave propagation interference and compatibility analysis in ITU-R[J]. High Power Laser and Particle Beams, 2019, 31: 023201. doi: 10.11884/HPLPB201931.180338

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Radio wave propagation interference and compatibility analysis in ITU-R

doi: 10.11884/HPLPB201931.180338

National Key Laboratory of Electromagnetic Environment, Qingdao 266107, China

Received Date: 2018-11-23
Rev Recd Date: 2018-12-29
Publish Date: 2019-02-15

Abstract

Abstract

The standard texts (Recommendations, Manuals, Reports, etc.) in ITU-R SG3 related to the interference and compatibility analysis are systematically organized and analyzed in this contribution. The main propagation mechanisms leading to radio signal interference are introduced. The propagation models of interference and compatibility analysis are also briefly introduced. In particular, the latest developments of related propagation models and standards are also given in this paper, while the development of standards and models is proposed in the conclusion.
- interference and compatibility analysis,
- radio wave propagation,
- radio signals,
- ITU,
- recommendation

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References(17)

References

[1]	Editing group chaired by Carol Wilson. ITU-R propagation prediction methods for interference and sharing studies[M]. ITU-R Handbook, 2012.
[2]	Rec. ITU-R P. 452-16, Prediction procedure for the evaluation of interference between stations on the surface of the Earth at frequencies above about 0. 1 GHz[S]. 2015.
[3]	ITU-R Question 208-5/3, Propagation factors in frequency sharing issues affecting space radiocommunication services and terrestrial services[S]. 2013.
[4]	Rec. ITU-R P. 2001-2, A general purpose wide-range terrestrial propagation model in the frequency range 30 MHz to 50 GHz[S]. 2015.
[5]	Rec. ITU-R P. 619-3, Propagation data required for the evaluation of interference between stations in space and those on the surface of the Earth[S]. 2017.
[6]	Rec. ITU-R P. 620-7, Propagation data required for the evaluation of coordination distances in the frequency range 100 MHz to 105 GHz[S]. 2003.
[7]	Rec. ITU-R P. 1412, Propagation data for the evaluation of coordination between Earth stations working in the bidirectionally allocated frequency bands[S]. 1999.
[8]	Rec. ITU-R P. 528-3, Propagation curves for aeronautical mobile and radionavigation services using the VHF, UHF and SHF bands[S]. 2012.
[9]	Rec. ITU-R P. 1546-5, Method for point-to-area predictions for terrestrial services in the frequency range 30 MHz to 3 000 MHz[S]. 2013.
[10]	Rec. ITU-R P. 1812-4, A path-specific propagation prediction method for point-to-area terrestrial services in the VHF and UHF bands[S]. 2015.
[11]	Rec. ITU-R P. 2108, Prediction of clutter loss[S]. 2017.
[12]	Rec. ITU-R P. 2109, Prediction of building entry loss[S]. 2017.
[13]	Rec. ITU-R P. 844-1, Ionospheric factors affecting frequency sharing in the VHF and UHF bands (30 MHz-3 GHz)[S]. 1994.
[14]	Rec. ITU-R P. 1060, Propagation factors affecting frequency sharing in HF terrestrial systems[S]. 1994.
[15]	Rec. ITU-R P. 533-13, Method for the prediction of the performance of HF circuits[S]. 2015.
[16]	Rep. ITU-R P. 2406, Studies for short-path propagation data and models for terrestrial radiocommunication systems in the frequency range 6 GHz to 100 GHz[S]. 2017.
[17]	Rec. ITU-R P. 372-13, Radio noise[S]. 2016.

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