Title :
Evaluation of cellular networks in Underwater acoustic communication
Author :
Nabavinejad, Amirmansour ; Ghahfarokhi, Samar Shahabi
Author_Institution :
Dept. of Electr. Eng., Islamic Azad Univ., Najafabad, Iran
Abstract :
The characteristics of acoustic propagation through the underwater environment are the greatest challenges faced by Underwater acoustic communications systems. Limit bandwidth in these systems is of paramount obstacles. To overcome this problem the idea of frequency reuse pattern seems to be useful. The key characteristic of a cellular network is the ability to re-use frequencies to increase both coverage and capacity. One element that determines frequency reuse is the reuse distance depending on the cell radius and the number of cells per cluster. Analysis of frequency reuse between adjacent clusters and optimal cell-radius selection criteria has been carried out recently. In other recent woks, the parameters of the cellular networks designing have been calculated based on a rough approximation of the attenuation and propagation model. In our work, after driving the ratio of signal to interference for underwater acoustic channels with more accuracy, the constraints for the cell radius are determined. One of the most important results of this contribution is that, for special parameters like bandwidth, it may be impossible to provide the required signal to interference ratio and bandwidth for the network users. Furthermore, in this paper, the number of supportable users, per-user bandwidth, and the user capacity for a cellular underwater network are determined.
Keywords :
approximation theory; cellular radio; frequency allocation; interference (signal); underwater acoustic communication; underwater acoustic propagation; acoustic propagation; adjacent clusters; attenuation model; cell radius; cellular networks design; cellular networks evaluation; cellular underwater network; frequency reuse pattern; limit bandwidth; optimal cell-radius selection criteria; paramount obstacles; per-user bandwidth; propagation model; reuse distance; rough approximation; signal to interference; underwater acoustic channels; underwater acoustic communication; underwater environment; user capacity; Absorption; Bandwidth; Interference; Land mobile radio cellular systems; Underwater acoustics; Wireless sensor networks; Cell Radius; Frequency Reuse; Signal to Interference Ratio; Underwater Cellular Networks; User Capacity;
Conference_Titel :
Advanced Communication Technology (ICACT), 2012 14th International Conference on
Conference_Location :
PyeongChang
Print_ISBN :
978-1-4673-0150-3