未来网络体系架构研究综述

doi:10.3969/j.issn.1000-436x.2014.08.023

Abstract

Abstract:

Nowadays, the Internet is facing unprecedented challenges, including scalability, security, management, mobil-ity, content distribution capability, and energy saving, etc., which are difficult to solve through incremental development. In such context, it is a hot field of global focus to develop an innovative future network architecture. Firstly, The global progress in this field is introduced. Then the main current research results are described. Finally, the development trends and core problems in this field are discussed. It is expected to be helpful for the domestic research in the related fields.

Key words: future network architecture, information centric networking, software defined networking, cloud networking;mobility, choice network; integratio

Tao HUANG,Jiang LIU,Ru HUO,Liang WEI,Yun-jie LIU. Survey of research on future network architectures[J]. Journal on Communications, 2014, 35(8): 184-197.

Figures/Tables 9

References 55

[56]	KIM D , KIM J , KIM Y , et al. Mobility support in content centric networks[A]. Proceedings of the Second Edition of the ICN Workshop on Information-Centric Networking[C]. Helsinki, Finland, 2012. 13-18.
[57]	LEE J , CHO S , KIM D . Device mobility management in con-tent-centric networking[A]. IEEE Communications Magazine[C]. 2012, 50(12): 28-34.
[58]	LEE J , KIM D Y , JANG M , et al. Mobility management for mobile-consumer devices in content centric networking (CCN)[A]. 2012 IEEE International Conference on Consumer Electronics[C] Las Vegas, USA, 2012. 502-503.
[59]	TYSON G , SASTRY N , RIMAC I , et al. A survey of mobility in in-formation-centric networks: challenges and research directions[A]. Proceedings of the 1st ACM Workshop on Emerging Name-Oriented Mobile Networking Design-Architecture, Algorithms, and Applica-tions[C] Hilton Head, SC, USA, 2012. 1-6.
[60]	VELTRI L , MORABITO G , SALSANO S , et al. Supporting informa-tion-centric functionality in software defined networks[A]. IEEEInternational Conference on Communications (ICC)[C] Ottawa, ON, Canada, 2012. 6645-6650.
[61]	C-flow: content-oriented networking over OpenFlow[EB/OL]. . 2012.
[1]	FELDMANN A . Internet clean-slate design: what and why[J]. ACM SIGCOMM Computer Communication Review, 2007, 37(3): 59-64.
[2]	PAUL S , PAN J , JAIN R . Architectures for the future networks and the next generation internet: a survey[J]. Computer Communications, 2011, 34(1): 32-42.
[3]	GAVRAS A , KARILA A , FDIDA S , et al. Future internet research and experimentation: the fire initiative[J]. ACM SIGCOMM Computer Communication Review, 2007, 37(3): 89-92.
[4]	AHLGREN B , D'AMBROSIO M , DANNEWITZ C , et al. Second netinf architecture description[J]. FP7-ICT-2007-1- 216041/D-6.2, 4WARD Project, 2010.
[5]	CASADO M , FREEDMAN M J , PETTIT J , et al. Ethane: taking control of the enterprise[J]. ACM SIGCOMM Computer Communica-tion Review, 2007, 37(4): 1-12.
[6]	MCKEOWN N , ANDERSON T , BALAKRISHNAN H , et al. Open-Flow: enabling innovation in campus networks[J]. ACM SIGCOMM Computer Communication Review, 2008, 38(2): 69-74 .
[7]	Software-defined networking: the new norm for networks[EB/OL]. . 2012.
[8]	Element management systems[EB/OL]. . 2012.
[9]	GUDE N , KOPONEN T , PETTIT J , et al. NOX: towards an operating system for networks[J]. ACM SIGCOMM Computer Communication Review, 2008,38 (3): 105-110.
[10]	ERICKSON D . The beacon openflow controller[A]. Proceedings of the Second ACM SIGCOMM Workshop on Hot Topics in Software Defined Networking[C]. Hong Kong, China, 2013. 13-18.
[11]	TOOTOONCHIAN A , GANJALI Y . Hyperflow: a distributed control plane for OpenFlow[A]. Proceedings of the 2010 Internet Network Management Conference on Research on Enterprise Networking[C] San Jose, CA, USA: USENIX Association, 2010.
[12]	KOPONEN T , CASADO M , GUDE N , et al. Onix: a distributed con-trol platform for large-scale production networks[A]. Proceedings of the 9th USENIX Conference on Operating Systems Design and Im-plementation[C]. Berkeley, CA, USA: USENIX Association, 2010. 1-6.
[13]	TAM A S W , XI K , CHAO H J . Use of devolved controllers in data center networks[A]. IEEE Conference on Computer Communications Workshops (INFOCOM WKSHPS)[C] Shanghai, China, 2011. 596-601.
[14]	OpenDaylight[EB/OL]. . 2013.
[15]	YU M , REXFORD J , FREEDMAN M J , et al. Scalable flow-based networking with difane[J]. ACM SIGCOMM Computer Communica-tion Review, 2010,40 (4): 351-362.
[16]	CURTIS A R , MOGUL J C , TOURRILHES J , et al. DevoFlow: scal-ing flow management for high-performance networks[A]. ACM SIGCOMM Computer Communication Review[C]. Toronto, on, Can-ada, 2011. 254-265.
[17]	JACOBSON V , SMETTERS D K , THORNTON J D , et al. Network-ing named content[J]. Communications of the ACM, 2012,55 (1): 117-124.
[18]	ZHANG L , ESTRIN D , BURKE J , et al. Named Data Networking (NDN) Project[J]. RelatórioTécnico NDN-0001, Xerox Palo Alto Re-search Center-PARC, 2010.
[19]	SMETTERS D , JACOBSON V . Securing network content[R]. PARC, 2009.
[20]	ZHANG G , LI Y , LIN T . Caching in information centric networking: a survey[J]. Computer Networks, 2013,57 (16): 3128-3141.
[21]	PSARAS I , CLEGG R G , LANDA R , et al. Modelling and Evaluation of CCN-Caching Trees[J]. Springer Berlin Heidelberg, 2011. 78-91.
[22]	CAROFIGLIO G , GALLO M , MUSCARIELLO L , et al. Modeling data transfer in content-centric networking[A]. Proceedings of the 23rd International Teletraffic Congress International Teletraffic Congress[C]. San Francisco, CA, USA, 2011. 111-118.
[23]	MUSCARIELLO L , CAROFIGLIO G , GALLO M . Bandwidth and storage sharing performance in information centric networking[A]. Proceedings of the ACM SIGCOMM Workshop on Information Cen-tric Networking[C] Toronto, Canada, 2011. 26-31.
[24]	ROSSI D , ROSSINI G . Caching Performance of Content Centric Networks Under Multi-path Routing (and more)[R]. Relatóriotécnico, Telecom ParisTech, 2011.
[25]	CAROFIGLIO G , GEHLEN V , PERINO D . Experimental evaluation of memory management in content-centric networking[A]. IEEE In-ternational Conference on Communications (ICC)[C]. Kyoto, Japan, 2011. 1-6.
[26]	PSARAS I , CHAI W , PAVLOU G . In-network cache management and resource allocation for information-centric networks[J]. IEEE Transac-tions on Parallel and Distributed Systems, 2013. (99) 1.
[27]	WANG S , BI J , WU J , et al. Could in-network caching benefit infor-mation-centric networking[A]. Proceedings of the 7th Asian Internet Engineering Conference[C] Bangkok, Thailand, 2011. 112-115.
[28]	MING Z , XU M , WANG D . Age-based cooperative caching in infor-mation-centric networks[A]. IEEE Conference on Computer Commu-nications Workshops (INFOCOM WKSHPS)[C] Orlando, FL, USA, 2012. 268-273.
[29]	HE D , CHAI W K , PAVLOU G . Leveraging in-network caching for efficient content delivery in content-centric network[A]. London Communication Symposium[C] London, England, 2011.
[30]	CHAI W K , HE D , PSARAS I , et al. Cache “less for more” in Infor-Mation-Centric Networks[M. Springer Berlin Heidelberg, 2012.
[31]	ZHU Y , CHEN M , NAKAO A . CONIC: content-oriented network with indexed caching[A]. INFOCOM IEEE Conference on Computer Communications Workshops[C] San Diego, CA, USA, 2010. 1-6.
[32]	PSARAS I , CHAI W K , PAVLOU G . Probabilistic in-network caching for information-centric networks[A]. Proceedings of the Second Edi-tion of the ICN Workshop on Information Centric Networking[C]. Helsinki, Finland, 2012. 55-60.
[33]	LI Z , SIMON G . Time-shifted TV in content centric networks: the case for cooperative in-network caching[A]. IEEE International Conference on Communications (ICC)[C] Kyoto, Japan, 2011. 1-6.
[34]	LIU Y , SIMON G . Peer-assisted time-shifted streaming systems: de-sign and promises[A]. IEEE International Conference on Communica-tions (ICC)[C] Kyoto, Japan, 2011. 1-5.
[35]	CHO K , LEE M , PARK K , et al. WAVE: Popularity-based and col-laborative in network caching for content-oriented networks[A]. IEEE Conference on Computer Communications Workshops[C] Orlando, FL, USA, 2012. 316-321.
[36]	FRICKER C , ROBERT P , ROBERTS J , et al. Impact of traffic mix on caching performance in a content centric network[A]. IEEE Confer-ence on Computer Communications Workshops[C] Orlando, FL, USA, 2012. 310-315.
[37]	WANG L , HOQUE A , YI C , et al. OSPFN: An OSPF Based Routing Protocol for Named Data Networking[R]. NDN-0003, University of Memphis and University of Arizona, 2012.
[38]	HOQUE A K M , AMIN S O , ALYYAN A , et al. NISR: named-data link state routing protocol[A]. Proceedings of the 3rd ACM SIG-COMM Workshop on Information-centric Networking[C]. Hong Kong, China, 2013. 15-20.
[39]	DAI H , LU J , WANG Y , et al. A two-layer intra-domain routing scheme for named data networking[A]. IEEE Global Communications Conference[C] Anaheim, CA, USA, 2012. 2815-2820.
[40]	SHANBHAG S , SCHWAN N , RIMAC I , et al. SoCCeR: services over content-centric routing[A]. Proceedings of the ACM SIGCOMM Workshop on Information-Centric Networking[C]. Toronto, Canada, 2011. 62-67.
[41]	YE R , XU M . Neighbor cache explore routing strategy in named data network[J]. Journal of Frontiers of Computer Science ＆ Technolog, 2012, 6(7): 593-601.
[42]	HE J J , WANG G Q , LIU J . A content-popularity-based ACO mecha-nism for content centric networking routing[A]. Proceedings of the 14th International Conference on Communication Technology[C] Chengdu, China, 2012. 9-11.
[43]	KHAN A Z , BAQAI S , DOGAR F R . QoS aware path selection in content centric networks[A]. 2012 IEEE International Conference on Communications[C] Ottawa, ON, Canada, 2012. 2645-2649.
[44]	CHENGMING L I , WENJING L I U , OKAMURA K . A greedy ant colony forwarding algorithm for named data networking[J]. Proceed-ings of the Asia-Pacific Advanced Network, 2013, 34: 17-26.
[45]	YUAN S , LIN T , ZHANG G , et al. A future anycast routing scheme for information centric network[A]. 2012 18th Asia-Pacific Confer-ence on Communications (APCC)[C]. Jeju Island, Korea, 2012. 173-178.
[46]	EUM S , NAKAUCHI K , MURATA M , et al. CATT: potential based routing with content caching for ICN[A]. Proceedings of the Second Edition of the ICN Workshop on Information-centric Networking[C]. Helsinki, Finland, 2012. 49-54.
[47]	MELAZZI N B , DETTI A , POMPOSINI M , et al. Route discovery and caching: a way to improve the scalability of information-centric networking[A]. IEEE Global Communications Conference (GLOBE-COM)[C] Anaheim, CA, USA, 2012. 2701-2707.
[48]	WONG W , GIRALDI M , MAGALHAES M F , et al. Content routers:fetching data on network path[A]. 2011 IEEE International Conference on Communications (ICC)[C] Kyoto, Japan, 2011. 1-6.
[49]	DAI J , HU Z , LI B , et al. Collaborative hierarchical caching with dy-namic request routing for massive content distribution[A]. Proceedings IEEE INFOCOM[C]. Orlando, FL, USA, 2012. 2444-2452.
[50]	GUO S , XIE H , SHI G . Collaborative Forwarding and Caching in Content Centric Networks[A]. Springer Berlin Heidelberg, 2012.
[51]	MEISEL M , PAPPAS V , ZHANG L . Listen first, broadcast later:Topology-agnostic forwarding under high dynamics[A]. Annual Con-ference of International Technology Alliance in Network and Informa-tion Sciences[C] Aberdeen, England, 2010. 1-8.
[52]	LI C , OKAMURA K , LIU W . Ant colony based forwarding method for content-centric networking[A]. 27th International Conference on Advanced Information Networking and Applications Workshops (WAINA)[C] Barcelona, Spain, 2013. 306-311.
[53]	CHENGMING L I , WENJING L I U , OKAMURA K . OKAMURA K. A greedy ant colony forwarding algorithm for Named data networking[A]. Pro-ceedings of the Asia-Pacific Advanced Network[C]. 2013. 17-26.
[54]	YI C , AFANASYEV A , WANG L , et al. Adaptive forwarding in named data networking[A]. ACM SIGCOMM Computer Communica-tion Review[C]. 2012, 42(3): 62-67.
[62]	The challenges of SDN/OpenFlow in an operational and large-scale net-work[EB/OL]. . 2012.
[55]	LEE J , KIM D . Proxy-assisted content sharing using content centric networking (CCN) for resource-limited mobile consumer devices[A]. IEEE Transactions on Consumer Electronics[C]. 2011, 57(2): 477-483.

Metrics

Recommended 0

No Suggested Reading articles found!

Survey of research on future network architectures

RichHTML

PDF

Knowledge

Abstract

Cite this article

share this article

Figures/Tables 9

References 55

Related Articles 15

Metrics

Recommended 0

[1]	Tao HUANG, Jiang LIU, Shuo WANG, Chen ZHANG, Yunjie LIU. Survey of the future network technology and trend [J]. Journal on Communications, 2021, 42(1): 130-150.
[2]	Fang DONG,Yuxiang HU,Ou LI. Routing framework and creation algorithm in Ad Hoc based SDN [J]. Journal on Communications, 2019, 40(9): 33-44.
[3]	CHEN Xingshu,HUA Qiang,WANG Yitong,GE Long,ZHU Yi. Research on low-rate DDoS attack of SDN network in cloud environment [J]. Journal on Communications, 2019, 40(6): 210-222.
[4]	Xianwei ZHU,Chaowen CHANG,Zhiqiang ZHU,Xi QIN. SDN control and forwarding method based on identity attribute [J]. Journal on Communications, 2019, 40(11): 1-18.
[5]	Junfeng TIAN,Liuling QI. DDoS attack detection method based on conditional entropy and GHSOM in SDN [J]. Journal on Communications, 2018, 39(8): 140-149.
[6]	Tao HUANG,Jiang LIU,Chen ZHANG,Liang WEI,Yunjie LIU. Survey on SDN-based network testbeds [J]. Journal on Communications, 2018, 39(6): 155-168.
[7]	Xi QIN,Guodong TANG,Chaowen CHANG. SDN security control and forwarding method based on cipher identification [J]. Journal on Communications, 2018, 39(2): 31-42.
[8]	Yong-hong FU,Jun BI,Ke-yao ZHANG,Jian-ping WU. Scalability of software defined network [J]. Journal on Communications, 2017, 38(7): 141-154.
[9]	Jiang ZHI,Jun LI,Hai-bo WU,Yong-mao REN. Edge-first-based cooperative caching strategy in information centric networking [J]. Journal on Communications, 2017, 38(3): 53-64.
[10]	Tao HU,Jian-hui ZHANG,Teng MA,Wei ZHAO. Multi-controller balancing deployment strategy based on reliability evaluation in SDN [J]. Journal on Communications, 2017, 38(11): 188-198.
[11]	Jiang LIU,Tao HUANG,Chen ZHANG,Ge ZHANG. Research on network virtualization slicing mechanism in SDN-based testbeds [J]. Journal on Communications, 2016, 37(4): 159-171.
[12]	Bo-hao FENG,Hua-chun ZHOU,Hong-ke ZHANG,Ming-chuan ZHANG. Cache allocation policy of service contents along delivery paths for the smart collaborative network [J]. Journal on Communications, 2016, 37(3): 129-138.
[13]	Xiu-lei WANG,Guo-min ZHANG,Chao HU,Ming CHEN,Xiang-lin WEI. SDFAC:software defined flow access control mechanism [J]. Journal on Communications, 2015, 36(Z1): 188-196.
[14]	Ming CHEN,Fei DAI,Bo XU,Chang-you XING,Bing LI,Guo-min ZHANG. Active measurement mechanism measuring SDN performances [J]. Journal on Communications, 2015, 36(6): 31-40.
[15]	. IMISA：interconnection mechanism for IP subnet and SDN subnet in autonomous system [J]. Journal on Communications, 2014, 35(Z1): 15-81.