CLC number: TP393
On-line Access: 2019-01-07
Received: 2018-09-17
Revision Accepted: 2018-11-14
Crosschecked: 2018-12-17
Cited: 0
Clicked: 4459
Shen Wang, Jun Wu, Wu Yang, Long-hua Guo. Novel architectures and security solutions of programmable software-defined networking: a comprehensive survey[J]. Frontiers of Information Technology & Electronic Engineering,in press.https://doi.org/10.1631/FITEE.1800575 @article{title="Novel architectures and security solutions of programmable software-defined networking: a comprehensive survey", %0 Journal Article TY - JOUR
可编程软件定义网络的新架构与安全技术:综述关键词组: Darkslateblue:Affiliate; Royal Blue:Author; Turquoise:Article
Reference[1]Ali ST, Sivaraman V, Radford A, et al., 2015. A survey of securing networks using software defined networking. IEEE Trans Reliab, 64(3):1086-1097. [2]Benton K, Camp LJ, Small C, 2013. OpenFlow vulnerability assessment. 2nd ACM SIGCOMM Workshop on Hot Topics in Software Defined Networking, p.151-152. [3]Botelho F, Bessani A, Ramos FMV, et al., 2014. On the design of practical fault-tolerant SDN controllers. 3rd European Workshop on Software Defined Networks, p.73-78. [4]Braga R, Mota E, Passito A, 2010. Lightweight DDoS flooding attack detection using NOX/OpenFlow. IEEE Local Computer Network Conf, p.408-415. [5]Casado M, Freedman MJ, Pettit J, et al., 2007. Ethane: taking control of the enterprise. Conf on Applications, Technologies, Architectures, and Protocols for Computer Communications, p.1-12. [6]Cheng YN, Dong C, Chu LW, et al., 2015. Design and implementation of software-defined networking based firewall system. Comput Appl Softw, 32(1):286-288, 312 (in Chinese). [7]David K, Berndt H, 2018. 6G vision and requirements: is there any need for beyond 5G? IEEE Veh Technol Mag, 13(3): 72-80. [8]European Telecommunications Standards Institute, 2012. Network Functions Virtualisation. https://portal.etsi.org/nfv/nfv_white_paper.pdf [9]Fayazbakhsh SK, Sekar V, Yu ML, et al., 2013. FlowTags: enforcing network-wide policies in the presence of dynamic middlebox actions. 2nd ACM SIGCOMM Workshop on Hot Topics in Software Defined Networking, p.19-24. [10]Feng MJ, Mao SW, Jiang T, 2016. Enhancing the performance of future wireless networks with software-defined networking. Front Inform Technol Electron Eng, 17(7):606- 619. [11]Gelberger A, Yemini N, Giladi R, 2013. Performance analysis of software-defined networking (SDN). IEEE 21st Int Symp on Modelling, Analysis and Simulation of Computer and Telecommunication Systems, p.389-393. [12]Greenberg A, Hjalmtysson G, Maltz DA, et al., 2005. A clean slate 4D approach to network control and management. ACM SIGCOMM Comput Commun Rev, 35(5):41-54. [13]Guan ZT, Zhang Y, Wu LF, et al., 2019. APPA: an anonymous and privacy preserving data aggregation scheme for fog-enhanced IoT. J Netw Comput Appl, 125:82-92. [14]Gude N, Koponen T, Pettit J, et al., 2008. NOX: towards an operating system for networks. ACM SIGCOMM Comput Commun Rev, 38(3):105-110. [15]Handigol N, Heller B, Jeyakumar V, et al., 2012. Where is the debugger for my software-defined network? 1st Workshop on Hot Topics in Software Defined Networks, p.55- 60. [16]Hata H, 2013. A study of requirements for SDN switch platform. Int Symp on Intelligent Signal Processing and Communication Systems, p.79-84. [17]Heller B, Sherwood R, McKeown N, 2012. The controller placement problem. 1st Workshop on Hot Topics in Software Defined Networks, p.7-12. [18]Hu ZY, Wang MW, Yan XQ, et al., 2015. A comprehensive security architecture for SDN. 18th Int Conf on Intelligence in Next Generation Networks, p.30-37. [19]Jafarian JH, Al-Shaer E, Duan Q, 2012. OpenFlow random host mutation: transparent moving target defense using software defined networking. 1st Workshop on Hot Topics in Software Defined Networks, p.127-132. [20]Keller E, Ghorbani S, Caesar M, et al., 2012. Live migration of an entire network (and its hosts). 11th ACM Workshop on Hot Topics in Networks, p.109-114. [21]Kim H, Feamster N, 2013. Improving network management with software defined networking. IEEE Commun Mag, 51(2):114-119. [22]Kreutz D, Ramos FMV, Verissimo P, 2013. Towards secure and dependable software-defined networks. 2nd ACM SIGCOMM Workshop on Hot Topics in Software Defined Networking, p.55-60. [23]Li GL, Wu J, Li JH, et al., 2017. Battery status sensing software-defined multicast for V2G regulation in smart grid. IEEE Sens J, 17(23):7838-7848. [24]Linux Foundation, 2015. OpenDaylight. http://www.opendaylight.org [25]Liu B, Chen M, Xu B, et al., 2016. An OpenFlow-based performance-oriented multipath forwarding scheme in datacenters. Front Inform Technol Electron Eng, 17(7): 647-660. [26]Liu CF, Samarakoon S, Bennis M, et al., 2018. Fronthaul- aware software-defined wireless networks: resource allocation and user scheduling. IEEE Trans Wirel Commun, 17(1):533-547. [27]Liu ZJ, Li Y, Su L, et al., 2014. TCAM-efficient flow table mapping scheme for OpenFlow multiple-table pipelines. J Tsinghua Univ (Sci Technol), 54(4):437-442 (in Chinese). [28]McKeown N, Anderson T, Balakrishnan H, et al., 2008. OpenFlow: enabling innovation in campus networks. ACM SIGCOMM Comput Commun Rev, 38(2):69-74. [29]Narayana S, Rexford J, Walker D, 2014. Compiling path queries in software-defined networks. 3rd Workshop on Hot Topics in Software Defined Networking, p.181-186. [30]Nayak AK, Reimers A, Feamster N, et al., 2009. Resonance: dynamic access control for enterprise networks. 1st ACM Workshop on Research on Enterprise Networking, p.11-18. [31]Nunes BBA, Mendonca M, Nguyen XN, et al., 2014. A survey of software-defined networking: past, present, and future of programmable networks. IEEE Commun Surv Tutor, 16(3):1617-1634. [32]Open Networking Foundation, 2012. Software-Defined Networking: the New Norm for Networks. http://www.valleytalk.org/wp-content/uploads/2012/05/wp-sdn-newnorm.pdf [33]Pan H, Guan HT, Liu JJ, et al., 2013. The FlowAdapter: enable flexible multi-table processing on legacy hardware. 2nd ACM SIGCOMM Workshop on Hot Topics in Software Defined Networking, p.85-90. [34]Porras P, Shin S, Yegneswaran V, et al., 2012. A security enforcement kernel for OpenFlow networks. 1st Workshop on Hot Topics in Software Defined Networks, p.121-126. [35]Qazi ZA, Tu CC, Chiang L, et al., 2013. SIMPLE-fying middlebox policy enforcement using SDN. ACM SIGCOMM Comput Commun Rev, 43(4):27-38. [36]Reitblatt M, Foster N, Rexford J, et al., 2011. Consistent updates for software-defined networks: change you can believe in! 10th ACM Workshop on Hot Topics in Networks, Article 7. [37]Reitblatt M, Foster N, Rexford J, et al., 2012. Abstractions for network update. ACM SIGCOMM Comput Commun Rev, 42(4):323-334. [38]Scott-Hayward S, 2015. Design and deployment of secure, robust, and resilient SDN controllers. 1st IEEE Conf on Network Softwarization, p.1-5. [39]Scott-Hayward S, O’Callaghan G, Sezer S, 2013. SDN security: a survey. IEEE SDN for Future Networks and Services, p.1-7. [40]Sezer S, Scott-Hayward S, Chouhan PK, et al., 2013. Are we ready for SDN? Implementation challenges for software- defined networks. IEEE Commun Mag, 51(7):36-43. [41]Shin S, Gu GF, 2012. CloudWatcher: network security monitoring using OpenFlow in dynamic cloud networks. 20th IEEE Int Conf on Network Protocols, p.1-6. [42]Shin S, Porras P, Yegneswaran V, et al., 2013. FRESCO: modular composable security services for software- defined networks. ISOC Network and Distributed Security Symp, p.1-16. [43]Tavakoli A, Casado M, Koponen T, et al., 2009. Applying NOX to the datacenter. 8th ACM Workshop on Hot Topics in Networks, p.1-6. [44]Voellmy A, Kim H, Feamster N, 2012. Procera: a language for high-level reactive network control. 1st Workshop on Hot Topics in Software Defined Networks, p. 43-48. [45]Wang K, Li JH, Wu J, et al., 2018. QoS-predicted energy efficient routing for information-centric smart grid: a network calculus approach. IEEE Access, 6:52867-52876. [46]Wang X, Liu Z, Qi YX, et al., 2012. LiveCloud: a lucid orchestrator for cloud datacenters. 4th IEEE Int Conf on Cloud Computing Technology and Science, p.341-348. [47]Wen XT, Chen Y, Hu CC, et al., 2013. Towards a secure controller platform for openflow applications. 2nd ACM SIGCOMM Workshop on Hot Topics in Software Defined Networking, p.171-172. [48]Wu J, Dong MX, Ota K, et al., 2017. FCSS: fog computing based content-aware filtering for security services in information centric social networks. IEEE Trans Emerg Top Comput, in press. [49]Wu J, Dong MX, Ota K, et al., 2018a. Big data analysis-based secure cluster management for optimized control plane in software-defined networks. IEEE Trans Netw Serv Manag, 15(1):27-38. [50]Wu J, Luo SB, Wang S, et al., 2018b. NLES: a novel lifetime extension scheme for safety-critical cyber-physical systems using SDN and NFV. IEEE Internet Things J, in press. [51]Yang EZ, Zhang LK, Yao Z, et al., 2016. A video conferencing system based on SDN-enabled SVC multicast. Front Inform Technol Electron Eng, 17(7):672-681. [52]Yeganeh SH, Ganjali Y, 2012. Kandoo: a framework for efficient and scalable offloading of control applications. 1st Workshop on Hot Topics in Software Defined Networks, p.19-24. [53]Yeganeh SH, Tootoonchian A, Ganjali Y, 2013. On scalability of software-defined networking. IEEE Commun Mag, 51(2):136-141. [54]Zhang D, Chang Z, Yu FR, et al., 2016a. A double auction mechanism for virtual resource allocation in SDN-based cellular network. IEEE 27th Annual Int Symp on Personal, Indoor, and Mobile Radio Communications, p.1-6. [54]Zhang D, Chang Z, Hämäläinen T, 2016b. Reverse combinatorial auction based resource allocation in heterogeneous software defined network with infrastructure sharing. IEEE 83rd Vehicular Technology Conf, p.1-6. [55]Zhang D, Chang Z, Hämäläinen T, et al., 2017. Double auction based multi-flow transmission in software-defined and virtualized wireless networks. IEEE Trans Wirel Commun, 16(12):8390-8404. Journal of Zhejiang University-SCIENCE, 38 Zheda Road, Hangzhou
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