ارزیابی شبکه انتقال داده در دو تکنولوژی وایمکس (Wimax) و نسل پنجم (5G)
محورهای موضوعی : مهندسی الکترونیکعلی مولودیان 1 , حسین مومن زاده حقیقی 2
1 - گروه فناوری اطلاعات،واحد بوشهر،دانشگاه آزاد اسلامی،بوشهر،ایران
2 - گروه فناوری اطلاعات،واحد بوشهر،دانشگاه آزاد اسلامی،بوشهر،ایران
کلید واژه: ارزیابی شبکه, انتقال داده, وایمکس, Network assessment, data transmission, 5G mobile networks, WiMAX, نسل پنجم شبکه های موبایل,
چکیده مقاله :
شبکه 4G فعلی برای سلولهای کوچک بی قاعده طراحی نشده بودند. بر اساس سیر تکاملی بلند مدت که وقفه زمان مخابره یک میلی ثانیه و پیشوند تناوبی حدود ۵ میلی ثانیه است این امر باعث شده است. به علاوه رابط درون سلول به مقدار زیادی توسط آرایش طرحریزی شده کنترل شده است.با توسعه سریع فناوریهای بیسیم، مفهوم نسل پنجم سیستمهای ارتباطی مطرح شد؛ که با این پیشرفت هر یک از مشترکان مخابراتی میتوانند با سرعت 1۱هزار گیگابیت در ثانیه به اینترنت متصل شوند. در این بستر، سیستمی که برای پیاده سازی آن مورد استفاده قرار گرفته است، گره هایی که بسته های اطلاعاتی را جا به جا می کنند کاملاً هوشمند هستند و الگوریتم هوشمندسازی گره ها براساس مسیر و مقصد می باشد. این سیستم باعث می شود تا داده ها بسیار هوشمندانه مسیریابی شده و با سرعت و امنیت بالا منتقل شوند در این مقاله سعی شده است تا با اندازه گیری پارامترهای QoS در شبکه های Wimax و 5G به مقایسه آن دو پرداخته و کارایی شبکه های 5G در انتقال داده را مورد بررسی قرار دهیم.
Current 4G networks were not designed for small cells promiscuous. Based on long-term evolution of the transmission time interval of about 5 milliseconds is a cyclic prefix milliseconds and this has caused. Also, a small cell base station (LTE) eNB is highly similar to a large cell eNB mature in functional areas, with the ability to move less. In addition, the interface cell is controlled to a large amount planned by arrangement With the rapid development of wireless technologies, the concept was introduced the fifth-generation communication systems; that with the progress of each telecom subscribers can connect to the Internet at a speed of 11 thousand Gbps. This makes the system very intelligent routing and data transfer with high speed and security. It is the process of separating hardware from software and the networking functions than a second. Software Defined Networking Foundation Network SDN by the standard theory of separation of control and data becomes smoother. As a result, thanks to the focus and planning, maintenance is largely automated. In this context, a system that is used to implement it, the nodes that are pasted packets are quite smart and intelligent algorithm based on the route and the destination node. This makes the system very intelligent routing and data transfer with high speed and security. In this article, we have tried to measure the QoS parameters in WiMAX networks and network performance 5G to compare them and examine the data transfer.
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_||_[1] A. Zakrzewska, S.Ruepp, M.S. Berger, “Towards converged 5G mobile networks-challenges and current trends,” in proc. Proceedings of the 2014 ITU kaleidoscope academic conference: Living in a converged world - Impossible without standards?, June 2014.
[2] G. P. Fettweis, “A 5G Wireless Communications Vision,” Microwave J, Dec. 2012.
[3] Amdocs Smart NetSolution, http://www.amdocs.com/Products/OSS/Pages/small-cell-solution.aspx, visited on 17 Apr. 2014..
[4] L.C Wang, “A Survey on Green 5G Cellular Networks,” in proc. 2012 International Conference on Signal Processing and Communications (SPCOM), July 2012.
[5] C.Cho, I. Han, Y. Jun, H.Lee, “Improvement of channel zapping time in IPTV services using the adjacent groups join-leave method,” in proc. The 6th International Conference on Advanced Communication Technology, 2004, pp. 971-975.
[6] Y. Kim, J.K.Park, H.J. Choi, S. Lee, H.Park, J.Kim, Z.Lee, K. Ko, “Reducing IPTV Channel Zapping Time Based on Viewer’s Surfing Behavior and Preference,” in proc. IEEE International Symposium on Broadband Multimedia Systems and Broadcasting, 2008.
[7] S.Akhtar, “Evolution of Technologies, Standards, and Deployment of 2G-5G Networks,” Encyclopedia of Multimedia Technology and Networking, Second Edition, pp. 522-532, 2009.
[8] K.Santhi, V.Srivastava, G.SenthilKumaran, & A.Butare, “Goals of true broad band's wireless next wave (4G-5G),” in proc. Vehicular Technology Conference, 2003. VTC 2003-Fall. 2003 IEEE 58th, 2003, pp. 2317 - 2321.
[9] T.Janevski, “5G Mobile Phone Concept,” in proc. Consumer Communications and Networking Conference, 2009. CCNC 2009. 6th IEEE, 2009, pp.1-2.
[10] F.Cheng-Xiang WangHaider, X.Gao, X.H.You, Y.Yang, D.Yuan, H.Aggoune, E.Hepsaydir, “Cellular Architecture and Key Technologies for 5G Wireless Communication Networks,” IEEE Communications Magazine, pp. 122-130, 2014.
[11] P.Rost, C.Bernardos, A.Domenico, M.Girolamo, M.Lalam, A.Maeder, D.Wübben, “Cloud technologies for flexible 5G radio access networks,” IEEE Communications Magazine, 68-76, 2014.
[12] N.Bhushan, J.Li, D.Malladi, R.Gilmore, D.Brenner, A.Damnjanovic, S.Geirhofer, “Network densification: the dominant theme for wireless evolution into 5G,” IEEE Communications Magazine, pp.82-89, 2014
[13] B.Bangerter, S.Talwar, R.Arefi, & K.Stewart, “Networks and devices for the 5G era. IEEE Communications Magazine, pp. 90-96, 2014.
[14] J. Kempf, “Moving the Mobile Evolved Packet Core to the Cloud,” 2012 IEEE 8th Int'l. Conf. Wireless and Mobile Computing Networking and Commun, pp. 784-91, 2012.
[15] A. Shokrollahi, “Raptor codes,” IEEE Transaction Information Theory, vol. 52, no. 6, Jun. 2006, pp. 2551-2567
[16] M. Afgani, H. Haas, H. Elgala, and D. Knipp, “Visible Light Communication using OFDM,” in Proc. of the 2nd International Conference on Testbeds and Research Infrastructures for the Development of Networks and Communities (TRIDENTCOM), Barcelona, Spain, March 1-3 2006, pp. 129-134.
[17] X. Wang, “Cache in the Air: Exploiting Content Caching and Delivery Techniques for 5G Systems,” IEEE Commun. Mag, vol. 52, no. 2, pp. 131-39.
[18] V. Chandrasekhar, J. G. Andrews, and A. Gatherer, Femtocell, “networks: A survey,” IEEE Communications Magazine, vol. 46, no. 9, pp. 59-67, September 2008.
[19] “Cisco visual network index: Global mobile traffic forecast update,” 2012, [online] Available: http://www.cisco.com/en/US/solutions/collateral/ns341/ns525/ns537/ns705/ns827/white_paper_c11-520862.html.
[20] G. A. Abed, M. Ismail, and K. Jumari, “A Realistic Model and Simulation Parameters of LTE-Advanced Networks,” Faculty of Engineering and Built Environment, National University of Malaysia, Selangor, Rep, ISSN: 2278-1021, Aug 2012.