ACM Transactions on Computer Systems (TOCS)
Research on scheduling algorithms in Web cluster servers
Journal of Computer Science and Technology
OpenFlow: enabling innovation in campus networks
ACM SIGCOMM Computer Communication Review
NOX: towards an operating system for networks
ACM SIGCOMM Computer Communication Review
Using Memcached for Data Distribution in Industrial Environment
ICONS '08 Proceedings of the Third International Conference on Systems
Flexible, wide-area storage for distributed systems with WheelFS
NSDI'09 Proceedings of the 6th USENIX symposium on Networked systems design and implementation
The nature of data center traffic: measurements & analysis
Proceedings of the 9th ACM SIGCOMM conference on Internet measurement conference
Scalable flow-based networking with DIFANE
Proceedings of the ACM SIGCOMM 2010 conference
HyperFlow: a distributed control plane for OpenFlow
INM/WREN'10 Proceedings of the 2010 internet network management conference on Research on enterprise networking
Onix: a distributed control platform for large-scale production networks
OSDI'10 Proceedings of the 9th USENIX conference on Operating systems design and implementation
DevoFlow: scaling flow management for high-performance networks
Proceedings of the ACM SIGCOMM 2011 conference
Multihoming Management for Future Networks
Mobile Networks and Applications
Quality of Service and Max-Min Fair Transmit Beamforming to Multiple Cochannel Multicast Groups
IEEE Transactions on Signal Processing
Hi-index | 0.00 |
Currently, the architecture of network device is closed which is detrimental to network innovation. Software defined networking decouples the vertically coupled architecture and reconstructs the Internet as a modular structure. The idea of software defined networking is widely accepted. OpenFlow, a typical instance of the software defined networking, has been deployed by many universities and research institutions all over the world. With the increasing scale of deployment, the poor scalability of the OpenFlow centralized control mode becomes more and more obvious. To solve this scalability problem, this paper adopts the idea of load balance and proposes an architecture for the scalable intra-domain control named ASIC in OpenFlow. ASIC balances all the data flow initialization requests to several physical controllers in an OpenFlow network, and then, those requests are processed with a shared global network view in a parallel manner. ASIC also builds a data cluster for the global network view. By this way, the scalability problem in the intra-domain control plane could be completely solved. At the end of this paper, the emulation shows the feasibility of ASIC.