Conflicts in Routing and UAV Autonomy Algorithms for Ad-hoc & Infrastructure-based UAV Networks
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Keywords
Routing, UAV, High Altitude Platforms, Autonomy Algorithm
Abstract
Routing is very fundamental to the implementation of any networking or communications infrastructure. This paper, therefore, examines the conflicts and relevant considerations for implementing autonomous or self-organising unmanned aerial vehicles (UAVs) for communications area coverage, with particular emphasis on the impact of aerial vehicle autonomy algorithms on routing techniques for such networks. UAV networks can be deployed either as ad-hoc or infrastructure-based solutions. The mobility of UAVs introduces periodic topology changes, impacting link availability and routing paths. This work examines the implications of autonomous coordination of multiple UAVs on routing techniques and network architecture stability. The paper proposes a solution where routing techniques and UAV autonomy algorithms are integrated for improved global network efficiency for both ad-hoc and infrastructure-based scenarios. Integrating UAV autonomy algorithms with routing schemes may be an efficient method to mitigate link/topology stability issues and improve inter-UAV communication and network throughput, a key requirement for UAV networks. The implementation of inter-UAV links using optical, microwave or mmWave transmission is examined in the context of this work. The proposed integration may be crucial for communications coverage, where UAVs provide communications area coverage of a community of mobile or fixed users in either ad-hoc or infrastructure-based modes.
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References
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Copyright Telecommunications Association Inc.
Ogbonnaya Anicho, Mr., Liverpool Hope University
Anicho is currently carrying out a PhD Research on implementing autonomous High Altitude Platform Stations (HAPS), as a communications infrastructure focusing on the problem of coordinating multiple self-organising HAPS platforms for communications area coverage.
He earlier completed an MSc. Degree with Distinction in Telecommunications with Management from the University of Wales, Newport (now University of South Wales) United Kingdom.
His MSc. dissertation investigated Implementing Satellite Communications On-The-Move (SOTM) technology at Ka band analysing uplink Interference and mitigation techniques.
Philip B Charlesworth, Dr, Liverpool Hope University
Dr. Charlesworth is a Chartered Engineer with 38 years experience in communications systems engineering. This includes 16 years as an engineering officer in the Royal Air Force in both command and staff appointments. For 20 years I worked in the defence industry as a solutions architect for large and complex communications networks.
In September 2010 I transferred to the research division of EADS, Innovation Works. My research activity centred on the development of concepts and technologies for UAV communications, including solar-powered UAVs.
He is currently supporting STEM activities in schools, and supervising university research as a Visiting Professor at Liverpool Hope University.
Gurvinder S Baicher, Dr, Liverpool Hope University
Dr. Baicher is an experienced Senior Research Fellow with a demonstrated history of working in the higher education industry. Skilled in E-Learning, Lecturing, Curriculum Development, Research, and Management. Strong research professional with a Doctor of Philosophy (PhD) focused in Optimal design of Digital and Multirate filters using genetic algorithms from University of Wales. He is currently a Visiting Professor at Liverpool Hope University.
Atulya Nagar, Prof, Liverpool Hope University
Prof Nagar is a Professor of Mathematical Sciences at Liverpool Hope University and the Dean of Faculty of Science. He has been the Head of Department of Mathematics and Computer Science at Liverpool Hope since January 2008. A mathematician by training, with multi-disciplinary expertise in Nonlinear Mathematics, Natural Computing, Bio-Mathematics and Computational Biology, Operations Research, and Control Systems Engineering.
