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An SDN-Based Secure Mobility Model for UAV-Ground Communications

  • Rajesh KumarEmail author
  • Mohd. Abuzar Sayeed
  • Vishal Sharma
  • Ilsun You
Conference paper
Part of the Communications in Computer and Information Science book series (CCIS, volume 971)

Abstract

Multi-UAV collaborative networks provide with the opportunity to exploit civil, chemical, biological, radiological, nuclear and geographical reconnaissance, survey, management, and control. For the collaborative network formation, coverage is of prime paramountcy. Alongside coverage, possession of information and communication security is withal a major challenge. The coverage quandary can be resolved by a perspicacious selection of UAV waypoints. But the security paradigm which can be an effect of faulty node, intrusion or even choice of erroneous communication channels needs to be taken care of through efficacious strategies. Consequently, both a specialized UAV mobility model and a security mechanism are required in order to establish prosperous collaborative networks. In this article, an SDN-based secure mobility model is proposed which takes into account the topological density and restricts the UAV and ground node (Wireless Sensor Networks (WSNs)) transmissions to authenticity. Significant gains are observed for throughput, coverage, and latency by establishing a simulated network between multiple UAVs and WSN motes.

Keywords

UAVs Mobility model SDN Security WSNs 

Notes

Acknowledgement

This paper was presented at the Workshop associated with the 12th International Conference on Provable Security, 25–28 October, 2018, Jeju, Rep. of Korea.

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Copyright information

© Springer Nature Singapore Pte Ltd. 2019

Authors and Affiliations

  • Rajesh Kumar
    • 1
    Email author
  • Mohd. Abuzar Sayeed
    • 1
  • Vishal Sharma
    • 2
  • Ilsun You
    • 2
  1. 1.Computer Science and Engineering DepartmentThapar Institute of Engineering and Technology (TIET)PatialaIndia
  2. 2.Department of Information Security EngineeringSoonchunhyang UniversityAsan-siRepublic of Korea

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