Abstract
A standout amongst the most basic demands of 4G and 5G frameworks is that the clients ought not feel any contrast between a wired and a remote system, and they ought to have different choices for availability over heterogeneous systems. TCP convention can accomplish these necessities. The immediate approach to enhance the performance of TCP for the new generation. A static stream control window can prompt issues, being too small or too large and requiring adjustment in an attempt to get to the current ideal value. To overcome this issue, the sending rate ought to be adjusted as an element of the accessible limit of the eNode B rate. In any case, these arrangements are not just required to adjust the TCP stack at end frameworks, they also additionally disregard the attributes of unmistakable streams in LTE. They do not recognize burst streams and foundation streams. Thus, despite everything, it experiences poor execution under blasts of burst streams because of its evenhanded treatment of all system streams. In this work, we propose a novel Software Defined Networking (SDN)-based TCP blockage control component, alluded to as Taxed AIMD, that is more suited to blast streams, can accomplish quick stream transmission, can enhance the general system execution and can be used to relieve the TCP Congestion issue in LTE.
This is a preview of subscription content, log in via an institution to check access.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
References
Tikhvinskiy, V. O., and G. S. Bochechka. “Conceptual aspects of 5G construction.” (2013): 29–33.
ITU-T, Recommendation H. “265 (04/13): Series H: Audiovisual and Multimedia Systems, Infrastructure of audiovisual services–Coding of Moving Video, High Efficiency Video Coding.” Online: http://www.itu.int.
Puigrefagut, Elena. “HDTV and beyond.” Proc. ITU Regional Seminar on Transition to Digital Terrestrial Television Broadcasting and Digital Dividend. 2012.
Gao, Jianbo, and Nageswara SV Rao. “TCP AIMD dynamics over Internet connections.” IEEE communications letters 9.1 (2005): 4–6.
Yang, Yang Richard, et al. “Two problems of tcp aimd congestion control.” Department of Computer Sciences, UT Austin, Tech. Rep. TR-00-13 (2000).
Mondal, Amit, and Aleksandar Kuzmanovic. “Removing exponential backoff from TCP.” ACM SIGCOMM Computer Communication Review 38.5 (2008): 17–28.
Floyd, Sally. “Limited slow-start for TCP with large congestion windows.” (2004).
Gao, Jianbo, and Nageswara SV Rao. “TCP AIMD dynamics over Internet connections.” IEEE communications letters 9.1 (2005): 4–6.
Floyd, Sally. “A report on recent developments in TCP congestion control.” IEEE Communications Magazine 39.4 (2001): 84–90.
Alazemi, Hamed M., Ahmed Mokhtar, and Murat Azizoglu. “Stochastic approach for modeling random early detection gateways in TCP/IP networks.” Communications, 2001. ICC 2001. IEEE International Conference on. Vol. 8. IEEE, 2001.
G. holland, N. vaidya, “Analysis of TCP performance over mobile ad hoc networks”, Kluwer Academic Publishers. Manufactured in The Netherlands Wireless Networks, vol. 8, no 2, issue 3, pp. 275–288, 2002.
A. Ghassan, M. Ismail, and K. Jumari, “A survey on performance of congestion control mechanisms for standard TCP versions”, Journal of Basic and Applied Sciences 5 Australian, vol. 5, no 12, pp. 1345–1352. 12 (2011).
K. I. Oyeyinka1, A. O. Oluwatope, A. T. Akinwale, O. Folorunso, G. A. Aderounmu, O. O. Abiona, “TCP Window Based Congestion Control-Slow-Start approach”, Published Online Communications and Network, vol. 3, no 02, pp. 85. May 2011.
S. Jain and G. Raina, “An experimental evaluation of CUBIC TCP in a small buffer regime”, IEEE Communications (NCC), National Conference pp. 1–5. 2011.
B. S. L. Sassatelli, D. Collange, D. Lopez-Pacheco, and G. Urvoy-Keller, “Understanding TCP cubic performance in the cloud: A mean-field approach”, IEEE 2nd International Conference. In Cloud Networking (Cloud Net), pp. 190–194. 2013.
L. Zhao, L. Ping, chumming Wu, Q. Yang, “Avoiding the Evolved Node B Buffer Overflow by using Advertisement Window Control”, IEEE Communications and Information Technologies (ISCIT), pp. 268–273. 2011.
F. Fatima, B. Doan, Hoang, “LTE_FICC: A New Mechanism for Provision of QoS and Congestion Control in LTE/LTE-Advanced Networks”, Springer International Publishing, In International Conference on Mobile and Ubiquitous Systems, Computing, Networking, and Services, pp. 768–781. 2013.
H. Lee, K. Han, “Buffer overflow notification protocol at link level for wireless ad hoc networks”, IEEE ELECTRONICS LETTERS Vol. 36, No. 22 pp. 1899–1900. 26th October 2000.
K. Jamshaid, B. Shihada, L. Xia, and P. Levis, “Buffer sizing in 802.11 wireless mesh networks,” IEEE Eighth International Conference on Mobile Ad-Hoc and Sensor Systems, pp. 272–281, 2011.
Author information
Authors and Affiliations
Corresponding author
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 2018 Springer Nature Singapore Pte Ltd.
About this paper
Cite this paper
Chahal, P., Rathi, K. (2018). Improved TCP Congestion Control Algorithm for LTE SDN Networks. In: Perez, G., Tiwari, S., Trivedi, M., Mishra, K. (eds) Ambient Communications and Computer Systems. Advances in Intelligent Systems and Computing, vol 696. Springer, Singapore. https://doi.org/10.1007/978-981-10-7386-1_21
Download citation
DOI: https://doi.org/10.1007/978-981-10-7386-1_21
Published:
Publisher Name: Springer, Singapore
Print ISBN: 978-981-10-7385-4
Online ISBN: 978-981-10-7386-1
eBook Packages: EngineeringEngineering (R0)