Abstract
In recent years, Open Flow [1] is becoming a popular network architecture. As more and more users starts to join the conventional Internet, the drawbacks of the conventional networks are now gradually appearing. OpenFlow network provides us a brand new sight to the development of networks. This architecture separates the control plane and data plane from the hardware level(physically). OpenFlow has plenty of benefit compare to other network structures. Firstly, the control plane and data plane are decoupled, this means more flexible networks can be figure out with customized rules in the network. Secondly, OpenFlow provides us a new platform to design and test network protocols. Researchers could test new protocols in a real network environment. Thirdly, in OpenFlow architecture networks we could monitor flow traffic statistics. This fine-grained monitoring of flows enables us to better understanding the network protocols and scheme we applied.
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References
McKeon, N., Anderson, T., Balakrishnan, H., Parulkar, G., Peterson, L., Rexford, J., Shenker, S., Turner, J.: OpenFlow: Enabling Innovation in Campus Networks. ACM SIGCOMM Computer Communication Review, April 2008
Iyer, A.S., Mann, V., Samineni, N.R.: SwitchReduce: reducing switch state and controller involvement in OpenFlow networks. In: IFIP Networking Conference, 2013, pp. 1–9, May 22–24, 2013
Luo, T., et al.: Enhancing responsiveness and scalability for OpenFlow networks via control-message quenching. In: 2012 International Conference on ICT Convergence (ICTC). IEEE (2012)
Huang, X., Hu, F., Wu, J.: Intelligent Cooperative Spectrum Sensing via Hierarchical Dirichlet Networks. IEEE Journal on Selected Areas in Communication
Curtis, A.R., Mogul, J.C., Tourrilhes, J., Yalagandula, P., Sharma, P., Banerjee, S.: DevoFlow: Scaling flow management for high-performance networks. ACM SIGCOMM (2011)
Open Networking Foundation. OpenFlow switch specification, April 16, 2012
Luo, T., Tan, H.-P., Quek, T.Q.S.: Sensor OpenFlow: Enabling software-defined wireless sensor networks. IEEE Communications Letters (2012, to appear)
Open Networking Foundation. Software-defined networking: The new norm for networks, April 2012 (white paper)
Yu, M., Rexford, J., Freedman, M.J., Wang, J.: Scalable flow-based networking with DIFANE. ACM SIGCOMM (2010)
Gude, N., Koponen, T., Pettit, J., Pfaff, B., Casado, M., McKeown, N., Shenker, S.: NOX: Towards an operating system for networks. SIGCOMM Comput. Commun. Rev. 38(3), 105–110 (2008)
Koponen, T., Casado, M., Gude, N., Stribling, J., Poutievski, L., Zhu, M., Ramanathan, R., Iwata, Y., Inoue, H., Hama, T., Shenker, S.: Onix: a distributed control platform for largescale production networks. In: The 9th USENIX Conference on Operating Systems Design and Implementation (OSDI), pp. 1–6 (2010)
Tootoonchian, A., Ganjali, Y.: HyperFlow: a distributed control plane for openflow. In: INM/WREN. USENIX Association (2010)
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Li, X., Hong, X., Lu, Y., Hu, F., Bao, K., Kumar, S. (2016). A Control-Message Quenching Algorithm in Openflow-Based Wireless Mesh Networks with Dynamic Spectrum Access. In: Latifi, S. (eds) Information Technology: New Generations. Advances in Intelligent Systems and Computing, vol 448. Springer, Cham. https://doi.org/10.1007/978-3-319-32467-8_7
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DOI: https://doi.org/10.1007/978-3-319-32467-8_7
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