Bottleneck Management Using Consecutive Intervention Annulment in Deeply chocked G2G Networks

Authors

  • Ayesha Taranum  Assistant Professor, Department of ISE, GSSSIETW, Mysore, Karnataka, India
  • Dr. Reshma Banu  Professor & HOD, Department of ISE, GSSSIETW, Mysore, Karnataka, India

Keywords:

MTC, Gizmo-to-Gizmo, smart cities, IoT, LTE-A, Random Access, ACB, Bottleneck, Cross Layer Design, Interference, Physical Layer Techniques, Scheduling

Abstract

The Internet of Things (loT) and particularly Gizmo-to-Gizmo (G2G) communications are considered as major enablers for future smart cities' initiatives. While offering a wide range of applications and services, supporting such devices constitutes, however, one of the most important challenges to be faced by Network Operators (NO). Indeed, the expected huge number of devices requesting to connect to the network at the same time may result in severe Bottleneck in the access network with a high risk of Bottleneck collapse. Although there has been exploitation of the physical layer technique enhance the capability of multi-trip system, link scheduling problems still exist. Link scheduling problem addressed with a cross layer design. Cross layer design is a process of solving Bottleneck and scheduling problems in wireless systems wherever nodes capable by way of the Consecutive Intervention Annulment (CIA) capability under Signal to Interference Noise Ratio (SINR) model. CIA an efficient advance to tolerate the multiple adjacent concurrent communication to coexist, enable multi-packet reception. Cross layer design placed among the physical layer and MAC layer. The technique of both layers can support the additional difficult cross layer design intended use of improve system process. The proposed system consists of distributed link scheduling for solving the interference occurring during communications. This scheduling is an effectual process used for managing the interference relationships and with the help of advanced physical layer technique using CIA to take out the interference moreover decode the data by receivers.

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IInternational Journal of Scientific Research in Computer Science, Engineering and Information Technology

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Published

2018-05-08

Issue

Volume 4, Issue 6, May-June-2018

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Research Articles

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How to Cite

[1]
Ayesha Taranum, Dr. Reshma Banu, " Bottleneck Management Using Consecutive Intervention Annulment in Deeply chocked G2G Networks, IInternational Journal of Scientific Research in Computer Science, Engineering and Information Technology(IJSRCSEIT), ISSN : 2456-3307, Volume 4, Issue 6, pp.577-583, May-June-2018.