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Abstract

Residential broadband gateways comprise equipment, router, and Wi-Fi access point, though one by one overwhelming only 5-10 Watts of power and important contributors to overall network energy consumption because of huge preparation numbers. Wi-Fi traces collected throughout a building with thirty access points and twenty 5,000 shopper connections, and worth via simulation the tradeoffs between energy savings, session disruptions, and fairness.

Our system on artifact Wi-Fi access points, take a glance at it throughout a two-storey building emulating vi residences, and demonstrate radio energy reduction of over sixty influence little or no impact on user experience.

Considering the spotlight the effectiveness of the approach we have got a bent to demonstrate six WLAN network services on prime of Odin moreover as load-balancing, quality management, and sender Detection, automatic channel-selection, energy management, and guest policy group action.

Index Terms—Energy consumption, aggregation, centralized control, Green networking, WLAN, sleep modes.

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Author Biographies

V.S. Suresh Kumar, Research Scholar, Karpagam University, Coiambatore

Dept. of Computer Science

Dr. K. Ravi Kumar, Tamil University, Thanjavur

Dept Compter Science
How to Cite
Kumar, V. S., & Kumar, D. K. R. (2015). Greening Resource Provisioning and role of communication systems in Wi-Fi Networks. International Journal of Emerging Trends in Science and Technology, 2(03). Retrieved from http://igmpublication.org/ijetst.in/index.php/ijetst/article/view/557

References

1. R. Tucker, J. Baliga, R. Ayre, K. Hinton. Energy Consumption of science Networks. In Proc. European Conf. on Optical Communications, Belgium, Sep 2008.
2. M. Pickavet. Energy in ICT – Trends and analysis Directions. In IEEE Advanced Networking and Telecommunications Systems (ANTS), India, Dec 2009
3. E. Goma et al. sleep disorder within the Access or a way to Curb Access Network connected Energy Consumption. In Proc. ACM SIGCOMM, Canada, Aug 2011.
4. BeWiFi from Telefonica. http://www.
bewifi. es/.
5. Xfinity from Comcast. http://www.comcast. com/.
6. A.P. Jardosh et al. inexperienced LANs: On-Demand WLAN Infrastructures. Springer Mobile Networks and Applications (MONET), 14(6):798–814, Dec 2009.
7. DD-WRT. Open supply linux-based code. www.dd-wrt.com.
8. Cisco IOS NetFlow. www.cisco.com/go /netflow.
9. Wiviz. www.dd-wrt.com/wiki/index.php/ Wiviz.
10. TP-LINK WAP. www.tp-link.com/en/ products/details
11. Sandvine. international web Phenomena Spotlight: Netflix Rising. Technical report, May 2011.
12. N. Burton, M. Haynes, J. Uffelen, W. Brown, and G. Turrell. Mid-Aged Adults Sitting Time in 3 Contexts. yank Journal of PreventiveMedicine, 42(4):363–373, 2012.
13. E. Rozner, V. Navda, R. Ramjee, and S. Rayanchu. NAPman: Network-Assisted Power Management for LAN Devices. In Proc.ACM MobiSys, USA, Jun 2010.
14. J. Manweiler and R. R. Choudhury. Avoiding the frenzy Hours: LAN Energy Management via Traffic Isolation. In Proc. ACM MobiSys, USA, Jun/Jul 2011
15. X. Zhang and K. G. Shen. E-MiLi: Energy-Minimizing Idle Listening in Wireless Networks. In Proc. ACM MOBICOM, USA, Sep 2011.
16. A. Patro, S. Govindan, and S. Banerjee. observant Home Wireless expertise through LAN APs. In Proc. ACM MOBICOM, USA,Sep/Oct 2013.
17. J. Manweiler and R. R. Choudhury. RxIP: observation the Health of Home Wireless Networks. In Proc. IEEE INFOCOM, USA, Mar 2012.
18. V. Shrivastava, N. Ahmed, S. Rayanchu, S. Banerjee, S. Keshav, K. Papagiannaki, and A. Mishra. CENTAUR: Realizing the complete Potential of Centralized WLANs through a Hybrid information Path. In Proc. ACM MOBICOM, China, Sep 2009
19. Y. Chen, S. Zhang, S. Xu, and G. Li, “Fundamental trade-offs on inexperienced wireless networks,” IEEE Communications Magazine, vol. 49, no. 6, pp. 30–37, Jun. 2011.
20. S. Lambert, W. V. Heddeghem, W. Vereecken, B. Lannoo, D. Colle, and M. Pickavet, “Worldwide electricity consumption of communication networks,” Optics specific, vol. 20, no. 26, pp. B513–B524, Dec. 2012.
21. S. Vadgama and M. Hunukumbure, “Trends in inexperienced wireless access networks,” in Workshops, IEEE International Conference on Communications (ICC Wkshps ’11), Jun. 2011.
22. S. Ehsan and B. Hamdaoui, “A survey on energy-efficient routing techniques with qos assurances for wireless multimedia system device networks,” IEEE Communications Surveys & Tutorials, vol. 14, no. 2, pp. 265–278, Second Quarter 2012.
23. R. Bolla, R. Bruschi, F. Davoli, and F. Cucchietti, “Energy potency within the future internet: a survey of existing approaches and trends in energy-aware mounted network infrastructures,” IEEE Communications Surveys & Tutorials, vol. 13, no. 2, pp. 223–244, Second Quarter 2011.
24. A. Bianzino, C. Chaudet, D. Rossi, and J. Rougier, “A survey of inexperienced networking analysis,” IEEE Communications Surveys & Tutorials, vol. 14, no. 1, pp. 3–20, half-moon 2012.
25. D. Feng, C. Jiang, G. Lim, J. Cimini, L.J., G. Feng, and G. Li, “A survey of energy-efficient wireless communications,” IEEE Communications Surveys & Tutorials, vol. 15, no. 1, pp. 167–178, half-moon 2013
26. L. Shi, P. Chowdhury, and B. Mukherjee, “Saving energy in long-reach broadband access networks: subject field approaches,” IEEE Communications Magazine, vol. 51, no. 2, pp. S16–S21, Feb. 2013.
27. M. Deruyck, W. Joseph, B. Lannoo, D. Colle, and L. Martens, “Designing energy-efficient wireless access networks: LTE and LTE-Advanced,” IEEE web Computing, vol. 17, no. 5, pp. 39–45, Sep. 2013.
28. EARTH (Energy Aware Radio and network technologies) project, “Energy potency analysis of the reference systems, areas of enhancements and target breakdown,” 2012.
29. M. Hoque, M. Siekkinen, and J. Nurminen, “Energy economical multimedia system streaming to mobile devices - a survey,” IEEE Communications Surveys & Tutorials, vol. 16, no. 1, pp. 579–597, half-moon 2014.
30. B. Rengarajan, G. Rizzo, and M. Ajmone Marsan, “Qos-aware greening of interference-limited cellular networks,” in IEEE ordinal International conference and Workshops on a World of Wireless, Mobile and multimedia system Networks ,Jun. 2013.
31. Deutsche Telekom. http://tinyurl.com/ dtoffload.
32. Meraki. https://meraki.cisco.com.
33. J. Herzen, R. Merz, and P. Thiran. Distributed spectrum assignment for home wlans. In IEEE INFOCOM 2013.
34. Steven S. Hong et al. Picasso: versatile RF and Spectrum Slicing. In ACM SIGCOMM 2012.
35. inexperienced bit Initiative, http://www.greentouch.org, last access February 2013.
36. value Action IC1004, Cooperative Radio Communications for inexperienced good Environments , http://www.ic1004.org/, last access February 2013.
37. Intel, Heterogeneous Network answer temporary, www.intel.com/ content/dam/ www/public/us/en/documents/solution-briefs/ communications-heterogeneous-net work-brief.pdf, last access February 2013.