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Time Validity-Based Message Transmission for College Activities

  • Neeraj Garg
  • J. S. Lather
  • S. K. Dhurandher
Conference paper
Part of the Lecture Notes on Data Engineering and Communications Technologies book series (LNDECT, volume 18)

Abstract

As the existence of an end-to-end connected path between the sender and the receiver is not possible but still opportunistic networks (OppNets), look into that aspect of finding a path after considering some parameters like joining frequency of same nodes, distance from most frequented nodes (most reliable) to the destination, etc. We are looking into this connection between nodes, from college campus point of view. So routing in this type of scenario networks (campus) is different from the traditional mobile networks. Here intermittent nodes between source and destination play a vital role to decide the validity of message so as to transmit it to a destination within time validity limit. Routes are constructed dynamically as the source node or an intermediate node will choose any node, as next hop from a group of nearby neighbors depending upon (some parameter matched in the message body header of sender node by using utility metric calculated in that situation). In this paper, we had proposed a novel college campus-based timely validated message routing (CCTVMR) protocol. The proposed protocol will be compared with the all other routing protocols, prophet, epidemic, and HiBOp, on basis of some parameters. The CCTVMR protocol is introduced to address the message-passing problem in college campus network where speedily information delivery is important for students and teachers and thus fast delivery of messages was exchanged as delivery probability of spray and wait routing is best for our scenario between faculty and students and direct delivery routing protocol outperforms others in hop count (least).

Keywords

Opportunistic network (opponents) Delay-tolerant networks (DTN) ONE Routing Disconnections Message 

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Copyright information

© Springer International Publishing AG, part of Springer Nature 2018

Authors and Affiliations

  • Neeraj Garg
    • 1
  • J. S. Lather
    • 2
  • S. K. Dhurandher
    • 3
  1. 1.Department of Computer Science EngineeringMAITNew DelhiIndia
  2. 2.Department of Electrical and Electronics EngineeringNIT KurukshetraKurukshetraIndia
  3. 3.CAITFS, Division of Information Technology, Netaji Subhas Institute of TechnologyUniversity of DelhiNew DelhiIndia

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