[1] ZTE Institute. Dialog to Cloud[M]. Beijing: Posts & Telecom Press, 2012: 23-24.

[2] Nelson M R. The next generation internet, e-business, and e-everything[C]. 25th Anniversary AAS colloquium of Science and Technology Policy, 2010.

[3] Zhao Zisen. Past, present and future of optical fiber communications[J]. Acta Optica Sinica, 2011, 31(9): 0900109.

[4] Zhao Yongli, Zhang Jie, Ji Yuefeng. Flexible Spectrum Optical Networks[M]. Beijing: Posts & Telecom Press, 2013: 1-2.

[5] Buysse J, Georgakilas K, Tzanakaki A, et al.. Energy-efficient resource-provisioning algorithms for optical clouds[J]. Journal of Optical Communications and Networking, 2013, 5(3): 226-239.

[6] Contreras L M, López V, De Dios O G, et al.. Toward cloud-ready transport networks[J]. Communications Magazine, IEEE, 2012, 50(9): 48-55.

[7] Pickavet M, Vereecken W, Demeyer S, et al.. Worldwide energy needs for ICT: The rise of power-aware networking[C]. Advanced Networks and Telecommunication Systems, 2008: 1-3.

[8] Zhang Yinfa, Ren Shuai, Wang Peng, et al.. Research progress of effect of high power signal on optical networks and protection technology[J]. Laser & Optoelectronics Progress, 2014, 51(10): 100003.

[9] Vicat-Blanc P, Figuerola S, Chen X, et al.. Bringing Optical Networks to the Cloud: An Architecture for a Sustainable Future Internet[M]. Springer Berlin Heidelberg, 2011.

[10] O′Mahony M J, Simeonidou D, Hunter D K, et al.. The application of optical packet switching in future communication networks[J]. Communications Magazine, IEEE, 2001, 39(3): 128-135.

[11] De Leenheer M, Thysebaert P, Volckaert B, et al.. A view on enabling-consumer oriented grids through optical burst switching[J]. Communications Magazine, IEEE, 2006, 44(3): 124-131.

[12] Hou Rui, He Tingting, Mao Tengyue. Burst-segmentation-based and path-correlation-considered controlled retransmission scheme in optical burst switching networks[J]. Acta Optica Sinica, 2013, 33(7): 0706025.

[13] Jinno M, Tsukishima Y. Virtualized optical network (VON) for agile cloud computing environment[C]. Optical Fiber Communication Conference, 2009: OMG1.

[14] Velasco L, Klinkowski M, Ruiz M, et al.. Elastic spectrum allocation for variable traffic in flexible-grid optical networks[C]. National Fiber Optic Engineers Conference, Optical Society of America, 2012: JTh2A. 39.

[15] Zhang G, Leenheer M D, Mukherjee B. Optical grooming in OFDM-based elastic optical networks[C]. Optical Fiber Communication Conference, 2012: OTh1A. 1.

[16] Stevens T, De Leenheer M, Develder C, et al.. Multi-cost job routing and scheduling in grid networks[J]. Future Generation Computer Systems, 2009, 25(8): 912-925.

[17] Ming L, Yinfa Z, Shuai R, et al.. Research on the resource joint scheduling in optical networks for cloud computing[C]. Intelligent Computation Technology and Automation (ICICTA), IEEE, 2014: 596-599.

[18] Wang Y, Jin Y, Guo W, et al.. Joint scheduling for optical grid applications[J]. Journal of Optical Networking, 2007, 6(3): 304-318.

[19] Aoun R, Gagnaire M. Service differentiation based on flexible time constraints in market-oriented grids[C]. Global Telecommunications Conference, IEEE, 2009: 1-8.

[20] Abosi C E, Nejabati R, Simeonidou D. Service oriented resource orchestration in future optical networks[C]. Computer Communications and Networks (ICCCN), IEEE, 2011: 1-6.

[21] Zhao Y, He R, Yang H, et al.. Data center application oriented control architecture in multi-domain optical networks[J]. Optik-International Journal for Light and Electron Optics, 2013, 124(20): 4260-4265.

[22] Lee Y, Bernstein G, So N, et al.. Research proposal for cross stratum optimization (CSO) between data centers and networks[OL]. http://tools. ietf. Org /html/ draft-lee-cross-stratum-optimization-datacenter-00.

[23] Liu X, Wei W, Yu X, et al.. Distributed computing task assignment and lightpath establishment (TALE)[C]. High-Speed Networks Workshop, IEEE, 2007: 16-20.

[24] Zervas G, Escalona E, Nejabati R, et al.. Phosphorus grid-enabled GMPLS control plane (G MPLS): Architectures, services, and interfaces[J]. Communications Magazine, IEEE, 2008, 46(6): 128-137.

[25] Williams J. NASA Nebula in action: Cloud computing case examples[OL]. http://nebula. nasa. gov/blog/2011/08/16/white-paper-nebula-action, 2011.

[26] Belter B, Martinez J R, Aznar J I, et al.. The GEYSERS optical testbed: A platform for the integration, validation and demonstration of cloud-based infrastructure services[J]. Computer Networks, 2014, 61: 197-216.

[27] Tzanakaki A, Anastasopoulos M, Georgakilas K, et al.. Planning of dynamic virtual optical cloud infrastructures: The GEYSERS approach[J]. Communications Magazine, IEEE, 2014, 52(1): 26-34.

[28] Martini B, Martini V, Baroncelli F, et al.. Application-driven control of network resources in multiservice optical networks[J]. Journal of Optical Communications and Networking, 2009, 1(2): A270-A283.

[29] Zervas G S, Martini V, Qin Y, et al.. Service-oriented multigranular optical network architecture for clouds[J]. Journal of Optical Communications and Networking, 2010, 2(10): 883-891.

[30] Channegowda M, Nejabati R, Simeonidou D. Software-defined optical networks technology and infrastructure: Enabling software-defined optical network operations (Invited)[J]. Journal of Optical Communications and Networking, 2013, 5(10): A274-A282.

[31] Simeonidou D, Nejabati R, Azodolmolky S. Enabling the future optical internet with OpenFlow：A paradigm shift in providing intelligent optical network services[C]. Prec of the 13th IEEE International Conference on Transparent Optical Networks, 2011: 1-4.

[32] Chowdhury N M, Boutaba R. A survey of network virtualization[J]. Computer Networks, 2010, 54(5): 862-876.

[33] Wang A, Iyer M, Dutta R, et al.. Network virtualization: Technologies, perspectives, and frontiers[J]. J Lightwave Technol, 2013, 31(4): 523-537.

[34] Fischer A, Botero J F, Till Beck M, et al.. Virtual network embedding: A survey[J]. IEEE Communications Surveys & Tutorials, 2013, 15(4): 1888-1906.

[35] Peng S, Nejabati R, Simeonidou D. Impairment-aware optical network virtualization in single-line-rate and mixedline-rate WDM networks[J]. Journal of Optical Communications and Networking, 2013, 5(4): 283-293.

[36] Basta A, Barla B, Hoffmann M, et al.. Failure coverage in optimal virtual networks[C]. Optical Fiber Communication Conference, 2013: OTh3E. 2.

[37] Zhang Q, Xie W, She Q, et al.. RWA for network virtualization in optical WDM networks[C]. National Fiber Optic Engineers Conference, 2013: JTh2A. 65.

[38] Tzanakaki A, Anastasopoulos M P, Georgakilas K N. Dynamic virtual optical networks supporting uncertain traffic demands (invited)[J]. Journal of Optical Communications and Networking, 2013, 5(10): A76-A85.

[39] Nejabati R, Escalona E, Peng S, et al.. Optical network virtualization[C]. Optical Network Design and Modeling (ONDM), IEEE, 2011: 1-5.

[40] Jinno M. Virtualization in optical networks: From elastic networking level to sliceable equipment level[C]. Optical Internet (COIN), IEEE, 2012: 61-62.

[41] Jinno M, Takara H, Yonenaga K, et al.. Virtualization in optical networks from network level to hardware level (Invited)[J]. Journal of Optical Communications and Networking, 2013, 5(10): A46-A56.

[42] Zhang S, Shi L, Vadrevu C S K, et al.. Network virtualization over WDM and flexible-grid optical networks[J]. Optical Switching and Networking, 2013, 10(4): 291-300.

[43] Gong L, Zhu Z. Virtual optical network embedding (VONE) over elastic optical networks[J]. J Lightwave Technol, 2013, 32(3): 450-460.

[44] Peng S, Nejabati R, Simeonidou D. Role of optical network virtualization in cloud computing (invited) [J]. Journal of Optical Communications and Networking, 2013, 5(10): A162-A170.

[45] Anastasopoulos M P, Tzanakaki A, Simeonidou D. Stochastic planning of dependable virtual infrastructures over optical data center networks[J]. Journal of Optical Communications and Networking, 2013, 5(9): 968-979.

[46] Georgakilas K N, Tzanakaki A, Anastasopoulos M, et al.. Converged optical network and data center virtual infrastructure planning[J]. Journal of Optical Communications and Networking, 2012, 4(9): 681-691.

[47] Anastasopoulos M P, Tzanakaki A. Adaptive virtual infrastructure planning over interconnected IT and optical network resources using evolutionary game theory[C]. Optical Network Design and Modeling (ONDM), IEEE, 2012: 1-5.

[48] Tzanakaki A, Anastasopoulos M P, Zervas G S, et al.. Virtualization of heterogeneous wireless-optical network and IT infrastructures in support of cloud and mobile cloud services[J]. IEEE Communications Magazine, 2013, 51(8): 155-161.

[49] Yang H, Zhao Y, Zhang J, et al.. Multi-stratum resource integration for OpenFlow-based data center interconnect (invited)[J]. Journal of Optical Communications and Networking, 2013, 5(10): A240-A248.

[50] Zhao Y, Zhang J, Yang H, et al.. Data center optical networks (DCON) with OpenFlow based software defined networking (SDN)[C]. Communications and Networking in China (CHINACOM), IEEE, 2013: 771-775.

[51] Zhao Y, He R, Chen H, et al.. Experimental performance evaluation of software defined networking (SDN) based data communication networks for large scale flexi-grid optical networks[J]. Opt Express, 2014, 22(8): 9538-9547.

[52] Zhang J, Yang H, Zhao Y, et al.. Experimental demonstration of elastic optical networks based on enhanced software defined networking (eSDN) for data center application[J]. Opt Express, 2013, 21(22): 26990.

[53] Zuo X, Feng Y, Jin Y. OptoVisor: An infrastructure-as-a-service framework based on virtualization of optical network[C]. SPIE/OSA/IEEE Asia Communications and Photonics, International Society for Optics and Photonics, 2011: 83101.

[54] Hou W, Guo L, Liu Y, et al.. Virtual network planning for converged optical and data centers: Ideas and challenges[J]. IEEE Network, 2013, 27(6): 52-58.