[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.3837/tiis.2015.11.001

Content Distribution for 5G Systems Based on Distributed Cloud Service Network Architecture

Jiang, Lirong (National Key Laboratory of Communications, University of Electronic Science and Technology of China)
Feng, Gang (National Key Laboratory of Communications, University of Electronic Science and Technology of China)
Qin, Shuang (National Key Laboratory of Communications, University of Electronic Science and Technology of China)

Publication Information

KSII Transactions on Internet and Information Systems (TIIS) / v.9, no.11, 2015 , pp. 4268-4290 More about this Journal

Abstract

Future mobile communications face enormous challenges as traditional voice services are replaced with increasing mobile multimedia and data services. To address the vast data traffic volume and the requirement of user Quality of Experience (QoE) in the next generation mobile networks, it is imperative to develop efficient content distribution technique, aiming at significantly reducing redundant data transmissions and improving content delivery performance. On the other hand, in recent years cloud computing as a promising new content-centric paradigm is exploited to fulfil the multimedia requirements by provisioning data and computing resources on demand. In this paper, we propose a cooperative caching framework which implements State based Content Distribution (SCD) algorithm for future mobile networks. In our proposed framework, cloud service providers deploy a plurality of cloudlets in the network forming a Distributed Cloud Service Network (DCSN), and pre-allocate content services in local cloudlets to avoid redundant content transmissions. We use content popularity and content state which is determined by content requests, editorial updates and new arrivals to formulate a content distribution optimization model. Data contents are deployed in local cloudlets according to the optimal solution to achieve the lowest average content delivery latency. We use simulation experiments to validate the effectiveness of our proposed framework. Numerical results show that the proposed framework can significantly improve content cache hit rate, reduce content delivery latency and outbound traffic volume in comparison with known existing caching strategies.

Keywords

Caching; cooperation; content distribution; cloudlet; mobile network;

Citations & Related Records

Reference

1	M. Felemban, S. Basalamah, and A. Ghafoor, “A Distributed Cloud Architecture for Mobile Multimedia Services,” IEEE Network, October, 2013. Article (CrossRef Link).
2	J. Erman, A. Gerber, M. Hajiaghayi, et al., “to cache or not to cache the 3G case,” IEEE Internet Computing, vol. 15, no. 2, pp. 27–34, Mar. 2011. Article (CrossRef Link). DOI
3	S. Woo, E. Jeong, S. Park, et al., "Comparison of Caching Strategies in Modern Cellular Backhaul Networks," ACM MobiSys, June, 2013. Article (CrossRef Link).
4	H. Ahlehagh and S. Dey, "Video caching in radio access network: impact on delay and capacity," IEEE WCNC, 2012. Article (CrossRef Link).
5	X. Wang, M. Chen, T. Taleb, et al., “Cache in the air: exploiting content caching and delivery techniques for 5g systems,” IEEE Communications Magazine 52.2 (2014): 131-139. Article (CrossRef Link). DOI
6	B. A. Ramanan, L. M. Drabeck, M. Haner, et al., "Cacheability Analysis of HTTP traffic in an Operational LTE Network," Wireless Telecommun. Symp., Apr. 2013. Article (CrossRef Link).
7	A. Arvidsson, A. Mihaly and L. Westberg, “Optimized local caching in cellular mobile network,” Computer Networks, vol.55, 2011. Article (CrossRef Link). DOI
8	M. Satyanarayanan, P. Bahl, R. Caceres, et al., “The case for VM-based cloudlets in mobile computing,” IEEE Pervasive Computing, vol. 8, no. 4, pp. 14–23, Oct. 2009. Article (CrossRef Link). DOI
9	M. Arlitt, L. Cherkasova, J. Dilley, et al., “Evaluating content management techniques for web proxy caches,” ACM SIGMETRICS Performance Evaluation Review, vol. 27, no. 4, pp. 3–11, 2000. Article (CrossRef Link). DOI
10	W. Qing, H. Zheng, W. Ming, et al., “CACTSE: Cloudlet Aided Cooperative Terminals Service Environment for Mobile Proximity Content Delivery,” China Communications, Vol.10, June, 2013. Article (CrossRef Link). DOI
11	D. Fesehaye, Y. Gao, K. Nahrstedt, et al., "Impact of Cloudlets on Interactive Mobile Cloud Applications," 16th International Enterprise Distributed Object Computing Conference, 2012. Article (CrossRef Link).
12	M. Abrams, C. R. Standridge, G. Abdulla, et al., "Caching proxies: Limitations and potentials," WWW-4, Boston Conference, 1995. Article (CrossRef Link).
13	M. Arlitt, R. Friedrich, and T. Jin, “Workload characterization of a web proxy in a cable modem environment,” ACM SIGMETRICS Performance Evaluation Review, vol. 27, no. 2, pp. 25–36, 1999. Article (CrossRef Link). DOI
14	K. Psounis and B. Prabhakar, "A randomized web-cache replacement scheme," in Proc. of IEEE Infocom 2001, vol. 3, pp. 1407-1415, 2001. Article (CrossRef Link).
15	Y. Bernet, “The complementary roles of RSVP and differentiated services in the full-service QoS network,” Communications Magazine, IEEE38.2 (2000): 154-162. Article (CrossRef Link). DOI
16	S. Glassman, “A caching relay for the World Wide Web,” Computer Networks and ISDN Systems 27.2: 165-173, 1994. Article (CrossRef Link). DOI
17	H. Yu, D. Zheng, B. Y. Zhao, et al., “Understanding user behavior in large-scale video-on-demand systems,” ACM SIGOPS Operating Systems Review, Vol. 40. No. 4. ACM, 2006. Article (CrossRef Link). DOI
18	J. Gu, W. Wang, A. Huang, et al., "Distributed cache replacement for caching-enable base stations in cellular networks," Communications (ICC), 2014 IEEE International Conference on. IEEE, 2014. Article (CrossRef Link).
19	M. R. Garey and D. S. Johnson, “Computers and intractability: a guide to the theory of NP-completeness,” 1979[J]. San Francisco, LA: Freeman, 1979.
20	W. Tang, Y. Fu, L Cherkasova, et al., “Modeling and generating realistic streaming media server workloads,” Computer Networks 51.1: 336-356, 2007. Article (CrossRef Link). DOI
21	Extended LINGO Release 8.0 HLP. LINDO Systems Ins. 2003.
22	D. M. B. Masi, M. J. Fischer, D. A. Garbin, “Video Frame Size Distribution Analysis,” The Telecommunications Review 2008, Volume 19, Sept 2008.
23	J. Shen, S. Suo, H. Quan, et al., 3GPP long term evolution: principle and system design[J]. 2008.
24	N. D. Han, Y. Chung, M. Jo, “Green data centers for cloud-assisted mobile ad hoc networks in 5G,” IEEE Network, 29.2: 70-76, 2015. Article (CrossRef Link). DOI
25	B. Liu，V. Firoiu，J. Kurose, et al., "Capacity of Cache Enabled Content Distribution Wireless Ad Hoc Networks," Mobile Ad Hoc and Sensor Systems (MASS), 2014 IEEE 11th International Conference on. IEEE, 2014: 309-317, 2014. Article (CrossRef Link).
26	I. Psaras, W. K. Chai, G. Pavlou, “In-Network Cache Management and Resource Allocation for Information-Centric Networks,” IEEE Transactions on Parallel & Distributed Systems 25.11:2920 – 2931, 2014. Article (CrossRef Link). DOI
27	C. Ranaweera, E. Wong, C. Lim, et al., “Next generation optical-wireless converged network architectures,” IEEE Network, 26(2): 22-27, 2012. Article (CrossRef Link). DOI
28	A. Damnjanovic, J. Montojo, Y. Wei, et al., “A survey on 3GPP heterogeneous networks,” IEEE Wireless Communications, 2011, 18(3): 10-21. Article (CrossRef Link). DOI
29	L. Al-Kanj, Z. Dawy, E. Yaacoub, “Energy-Aware Cooperative Content Distribution over Wireless Networks: Design Alternatives and Implementation Aspects,” IEEE Communications Surveys & Tutorials 15.4(2013):1736 - 1760. Article (CrossRef Link). DOI
30	X. Zheng, C. Cho, Y. Xia, "Algorithms and Stability Analysis for Content Distribution over Multiple Multicast Trees," in Proc. of the IEEE Conference on Decision & Control (2014):1. Article (CrossRef Link).
31	"White Paper on 5G Concept," IMT-2020 (5G) Promotion Group, Fb, 2015. Article (CrossRef Link).
32	“Deliverable D6.4: Final report on architecture,” Mobile and wireless communications Enablers for the Twenty-twenty Information Society (METIS), Document Number: ICT-317669-METIS/D6.4. Article (CrossRef Link).
33	“NGMN 5G Initiative White Paper,” NGMN Alliance, Dec. 2014. Article (CrossRef Link).
34	C. Liu, K. Sundaresan, M. L. Jiang, "The Case for Re-configurable Backhaul in Cloud-RAN based Small Cell Networks," in Proc. of IEEE INFOCOM. Article (CrossRef Link).
35	S. Namba, T. Warabino, S. Kaneko, "BBU-RRH Switching Schemes for Centralized RAN," 7th International ICST Conference on CHINACOM, 2012. Article (CrossRef Link).
36	C.-L. I, C. Cui, J. Huang, et al., “C-RAN: Towards open, green and soft RAN,” IEEE Netw., to be published.
37	M. Jo, T. Maksymyuk, B. Strykhalyuk, et al., “Device-to-Device Based Heterogeneous Radio Access Network Architecture for Mobile Cloud Computing,” IEEE Wireless Communications, Vol.12, No.3, June 2015. Article (CrossRef Link).
38	http://www.cisco.com/web/CN/aboutcisco/news_info/corporate_news/2013/06_27.html.
39	CMCC (China Mobile Communications Corporation) white paper: "C-RAN the road towards green RAN," Version 2.5, Oct. 2011. Article (CrossRef Link).
40	C.-L. I, C. Rowell, S. Han, et al., “Towards green and soft: A 5G perspective,” IEEE Commun. Mag., vol. 52, no. 2, pp. 6673, Feb. 2014. Article (CrossRef Link). DOI
41	N. Abedini and S. Shakkottai, “Content caching and scheduling in wireless networks with elastic and inelastic traffic,” IEEE transaction on networking, 22(3), 2014. Article (CrossRef Link).