Work place: School of Information Sciences and Technology, Kisii University, 40200 - Kenya
E-mail: vincent@kisiiuniversity.ac.ke
Website:
Research Interests: Computer Networks, Computer Architecture and Organization, Computer systems and computational processes, Software Engineering, Computational Science and Engineering, Applied computer science
Biography
Vincent Omollo Nyangaresi, is a PhD student in the area of IT security and Audit. He has published numerous research articles covering areas such as communication systems, secure network communications, information systems acceptance modeling, TCP architecture and design, radio wave propagation, virtualization and cloud computing. In addition, he lecturers in the fields of computer networks, digital forensics, software engineering, information technology, and applied computer science.
By Vincent Omollo Nyangaresi Silvance O. Abeka Anthony J. Rodrigues
DOI: https://doi.org/10.5815/ijitcs.2020.05.04, Pub. Date: 8 Oct. 2020
Accurate mobility prediction enables efficient and faster paging services in these networks. This in turn facilitates the attainment of higher bandwidths and execution of activities such as handovers at low latencies. The conventional mobility prediction models operate on unrealistic assumptions that make them unsuitable for cellular network mobile station tracking. For instance, the Feynman-Verlet, first order kinetic model and Random Waypoint assume that mobile phones move with constant velocity while Manhattan, Freeway, city area, street unit, obstacle mobility, and pathway mobility postulate that mobile station movement is restricted along certain paths. In addition, obstacle mobility model speculate that the mobile station signal is completely absorbed by an obstacle while random walk, random waypoint, Markovian random walk, random direction, shortest path model, normal walk, and smooth random assume that a mobile station can move in any direction. Moreover, the greatest challenge of the random direction model is the requirement that a border behavior model be specified for the reaction of mobile stations reaching the simulation area boundary. In this paper, a protocol that addresses the border behavior problem is developed. This protocol is shown to detect when the subscriber has moved out of the current tracking area, which is crucial during handovers.
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