Abstract

Large number of low power, tiny radio jammers are constituting a Distributed Jammer Network (DJN) is used nowadays to cause a Denial of Service (DoS) attack on a Distributed Wireless Network (DWN). Using NANO technologies, it is possible to build huge number of tiny jammers in millions, if not more. The Denial of Service (DoS) attacks in Distributed Wireless Network (DWN) using Distributed Jammer Network (DJN) considering each of them as separate Poisson Random Process. In an integrated approach, in this study, we advocate the more natural Birth-Death Random Process route to study the impact of Distributed Jammer Network (DJN) on the connectivity of Distributed Wireless Network (DWN). We express that the Distributed Jammer Network (DJN) can root a phase transition in the performance of the target network. We use Birth-Death Random Process (BDRP) route for this phase transition to evaluate the collision of Distributed Jammer Network (DJN) on the connectivity and global percolation of the target network. This study confirms the global percolation of Distributed Wireless Network (DWN) is definite when the Distributed Jammer Network (DJN) is not more significant.

Highlights

  • Miniaturization of jammers is possible, compared to wireless sensors, due to the fact that jammers emitA manifestation of the development of radio technology is the transition from huge vacuum tube radios to micro nanotube radios

  • In this study, we advocate the more natural birth-death random process route to study the impact of Distributed Jammer Network (DJN) on the connectivity of Distributed Wireless Network (DWN)

  • We use Birth-Death Random Process (BDRP) route for this phase transition to evaluate the collision of Distributed Jammer Network (DJN) on the connectivity and global percolation of the target network

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Summary

Introduction

A manifestation of the development of radio technology is the transition from huge vacuum tube radios to micro nanotube radios. This in its wake has ushered in radical changes in the design and use of radio devices. Distributed Jammer Network (DJN) has many applications in the defense scenario of a country New devices such as nanotube radio may find their application in the jamming dust. Distributed jammer network can be deployed to form a low power air-born jamming dust, to disrupt the communication capabilities of an adversary, which is more advantages because the naked eye cannot even see the nanotube jammers, with much reduced effect on self-interface. The advantage of self-interface free jamming has been amply and purposefully seen in the second Iraq war as dust of micro sensors (Kahn et al, 1999)

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