상세정보
학술지
Range-Dependent Path-Loss Model in Residential Areas for the VHF and UHF Bands
- 저자
- 정현규, Henry L. Bertoni
- 발행일
- 200201
- 출처
- IEEE Transactions on Antennas and Propagation, v.50 no.1, pp.1-11
- ISSN
- 0018-926X
- 출판사
- IEEE
- 협약과제
- 02MR2200, 초고속패킷 무선전송기술연구, 한기철
- 초록
- Implementation digital fixed wireless systems, such as digital FM, high definition TV (HDTV) and wireless local loop (WLL), require a high level of accuracy of propagation prediction in the VHF and UHF bands. This paper presents a theoretical model that predicts the average path loss from an elevated base station to subscriber antennas at rooftop level in residual areas for frequencies in the approximate band from 30 MHz up to 3 GHz. In addition, the model gives the standard deviation of the path loss at the average rooftop level and the height gain for subscriber antennas above or below the average rooftop level. The approach used here generalizes that of Walfisch and Bertoni, who developed a theoretical model of UHF propagation in urban environments. The rows of buildings in residential areas are modeled as a series of dielectric screens having random heights and uniform spacing. Propagation takes place over and through the dielectric screens, and ground reflections are included. The fields at the plane of each screen are obtained in terms of repeated numerical evaluation of the physical optics (PO) integral. Results obtained for the variation of the range dependence on frequency and row spacing are consistent with those previously found for high frequencies by assuming the screens to be totally absorbing. Using the results at different heights of receiving antenna allows computation of the height gain. The predictions are in agreement with the International Telecommunication Union Radio Communication (ITRU-R) recommendations in the VHF and UHF bands.
- KSP 제안 키워드
- High Frequency(HF), High definition, International Telecommunication Union(ITU), Level of accuracy, Physical Optics, Propagation prediction, Radio communication, Range dependence, Range-dependent, Receiving antennas, Residential areas