Abstract
Reliable and real-time propagation loss modeling play a significant role in the efficient planning, development, and optimization of macrocellular communication networks in a given terrain. Thus, the need to adapt or tune an existing model to enhance its signal prediction accuracy in a specified terrain becomes imperative. In this paper, we proposed and applied a non-linear square regression method based on the Levenberg-Marquart (LM) algorithm to adapt and improve the empirical propagation loss estimation accuracy of the Egli model for two major cities in Nigeria. A comprehensive propagation loss measurement acquired over Long Term Evolution (LTE) mobile broadband networks operating at 2630 MHz for four different cities was collected using TEMS investigation tools to achieve the Egli model adaption. Results indicate that the adapted Egli model displays a high estimation accuracy over the Gauss-Newton (GN) algorithm leveraging the non-linear regression method employed to benchmark the propagation loss estimation. Using six standard statistical indicators, the adapted Egli model displayed lower estimation errors than the classical Egli model across the tested locations in the two cities investigated. Finally, the LM-adapted Egli model was compared with extensive measurements from another eNodeB in Port Harcourt different from the initial four eNodeBs investigated. The results indicate that the adapted model is suitable for deployment in related macrocellular environments.
Highlights
Radio wave propagation in typical terrestrial terrains is a stochastic phenomenon whose characteristics vary in time due to atmospheric conditions and in space due to other clutter and environmental obstructions [1]
Such significant error differences may be attributed to the physical terrain and topographical differences between locations where the measurement loss data is conducted and the terrain characterization where the Egli model was developed
To adapt the Egli model to the measured propagation loss data acquired over the two study locations using the non-linear square regression method, we employ the robust
Summary
Radio wave propagation in typical terrestrial terrains is a stochastic phenomenon whose characteristics vary in time due to atmospheric conditions and in space due to other clutter and environmental obstructions [1]. The. Isabona and Imoize Journal of Engineering and Applied Science (2021) 68:33 resultant effect of this stochastic phenomenon is large-scale attenuation and reduction of the propagated signal from radio waves between the transmitting and receiving channels [4]. Isabona and Imoize Journal of Engineering and Applied Science (2021) 68:33 resultant effect of this stochastic phenomenon is large-scale attenuation and reduction of the propagated signal from radio waves between the transmitting and receiving channels [4] Such reduction in strength or power of the propagated radio signal over a communication channel is known as propagation path loss [5,6,7]. Over the past few decades, several researchers have attempted to develop different models that can reliably estimate the signal propagation path loss over two or more radio communication terminals [8, 9]. One of such terrainbased models is the Egli propagation model developed from terrain-based measurements [12]
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