H.H. Xia scite author profile

This paper presents results of wide-band path loss and delay spread measurements for five representative microcel-Mar environments in the San Francisco Bay area at 1900 MHz. Measurements were made with a wide-band channel sounder using a 100-ns probing pulse. Base station antenna heights of 3.7 m, 8.5 m, and 13.3 m were tested with a mobile receiver antenna height of 1.7 m to emulate a typical microcellular scenario. The results presented in this paper provide insight into the satistical distributions of measured path loss by showing the validity of a double regression model with a break point at a distance that has first Fresnel zone clearance for line-of-sight topographies. The variation of delay spread as a function of path loss is also investigated, and a simple exponential overbound model is developed. The path loss and delay spread models are then applied to communication system design allowing outage probabilities, based on path loss or delay spread, to be estimated for a given microcell size.

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UHF propagation prediction for wireless personal communications

Bertoni¹,

Honcharenko

Macel³

et al. 1994

Proc. IEEE

235

101

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Radio propagation characteristics for line-of-sight microcellular and personal communications

Xia

Bertoni²,

Maciel³

et al. 1993

IEEE Trans. Antennas Propagat.

259

101

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To acquire a knowledge of radio propagation characteristics in the microcellular environments for personal communications services (PCS), a comprehensive measurement program was conducted by Telesis Technologies Laboratory (nZ) in the San Francisco Bay area using three base station antenna heights of 3.2 m, 8.7 m, and 13.4 m and two frequencies at 900 MHz and 1900 MHz. Five test settings were chosen in urban, suburban, and rural areas in order to study propagation in a variety of environments. This paper reports the LOS measurements in different environments, all of which show variations of signal strength with distance that have distinct near and far regions separated by a break point. It was also found that the location of the break point for different frequencies and antenna heights can be calculated based on first Fresnel zone clearance.The regression analysis reveals a slope that is less than two before the break point, while it is greater than two after the break point. This break distance can be used to define the size of microcell and to design for fast hand-off. Beyond the first Fresnel zone break distance the base station antenna height gain was observed to approximately follow the square power law of antenna height.

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Diffraction of cylindrical and plane waves by an array of absorbing half-screens

Xia¹,

Bertoni²

1992

IEEE Trans. Antennas Propagat.

100

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Path-loss prediction model for microcells

Har¹,

Xia²,

Bertoni³

1999

IEEE Trans. Veh. Technol.

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H.H. Xia

Path loss, delay spread, and outage models as functions of antenna height for microcellular system design

UHF propagation prediction for wireless personal communications

Radio propagation characteristics for line-of-sight microcellular and personal communications

Diffraction of cylindrical and plane waves by an array of absorbing half-screens

Path-loss prediction model for microcells

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