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dc.contributor.author | Rehman, Amad Ur | |
dc.contributor.author | Tawfik, Kasiita | |
dc.contributor.author | Umaru, Mohamed | |
dc.date.accessioned | 2020-10-28T14:51:10Z | |
dc.date.available | 2020-10-28T14:51:10Z | |
dc.date.issued | 2018-11-15 | |
dc.identifier.citation | 1. Concurrent bandwidth scheduling for big data transfer over a dedicated channel [Liudong Zuo and Michelle M. Zhu*, Chase Q. Wu] Int. J. Communication Networks and Distributed Systems, Vol. 15, Nos. 2/3, 2015. 2. On Design of Scheduling Algorithms for Advance Bandwidth Reservation in Dedicated Networks[Yunyue Lin, Qishi Wu, Nageswara S.V. Rao, Mengxia Zhu] Source: IEEE Xplore May 2008 3. Advance Bandwidth Reservation for Energy Efficiency in High-performance Networks[Tong Shu, Chase Qishi Wu, and Daqing Yun] IEEE 2013. 4. Bandwidth Scheduling and Path Computation Algorithms for Connection-Oriented Networks [Sartaj Sahni Nageshwara Rao Sanjay Ranka Yan Li Eun-Sung Jung Nara Kamath] Sixth International Conference on Networking (ICN'07) 2007. 5. Tera scale High-Fidelity Simulations of Turbulent Combustion with Detailed Chemistry. http://scidac.psc.edu. 6. TerascaleSupernovaInitiative(TSI).http://www.phy.ornl.gov/ti. 7. UCLP:UserControlledLightPathProvisioning.http://phi.badlab.crc.ca/uclp. 8. EnlightenedComputing.http://www.enlightenedcomputing.org. 9. Geant2. http://www.geant2.net. 10. HOPI:HybridOpticalandPacketInfrastructure.http://networks.internet2.edu/hopi. 11. GENI: Global Environment for Network Innovations. http://www.geni.net. 12. Z. Zhang, Z. Duan, and Y. Hou. Decoupling qos control from core routers: A novel bandwidth broker architecture for scalable support of guaranteed services. In Proc. of ACM SIGCOMM, 2000. 13. N. Rao, Q. Wu, S. Carter, W. Wing, D. G.A. Banerjee, and B. Mukherjee. Control plane for advance bandwidth scheduling in ultrahigh-speed networks. In INFOCOM 2006 Workshop on Terabits Networks, 2006. 14. S. Sahni, N. Rao, S. Ranka, Y. Li, E. Jung, and N. Kamath. Bandwidth scheduling and path computation algorithms for connection-oriented networks. In Proc. of Int. Conf. on Networking, 2007. 15. A Scalable and High-Performance Scheduling Algorithm for Multiple Memory Controllers.[ Yoongu Kim Dongsu Han Onur Mutlu Mor Harchol-Balter] 2009 IEEE 16. S. Gorinsky and N. Rao. Dedicated channels as an optimal network support for effective transfer of massive data. In INFOCOM 2006Workshop on High-Speed Networks, 2006. 17. R. Guerin and A. Orda. Networks with advance reservations: the routing perspective. In Proc. of the19th IEEE INFOCOM, 2000. 18. N. Rao, W. Wing, S. Carter, and Q. Wu.Ultrascience net: Network test bed for large-scale science applications. IEEE Communications Magazine, 43(11):s12–s17, 2005. An expanded version available at www.csm.ornl.gov/ultranet. 19. Bandwidth scheduling for big data transfer using multiple fixed node-disjoint paths Aiqin Hou, Chase Q. Wu, Dingyi Fang, Yongqiang Wang, Meng Wang. 20. On Design of Scheduling Algorithms for Advance Bandwidth Reservation in Dedicated Networks [Yunyue Lin, Qishi Wu, Nageswara S.V. Rao, Mengxia Zhu] IEEE 2008. 21. https://en.wikipedia.org/wiki/Scheduling_ (computing) 22. https://en.wikipedia.org/wiki/Bandwidth_ (computing) 23. https://www.webopedia.com/TERM/B/bandwidth.html 24. http://www.northropgrumman.com/Capabilities/HighPerformanceNetworking/Pages/default.aspx 25. https://www.canopyhealth.com/en/brokers/articles/high-performance-network.html | en_US |
dc.identifier.uri | http://hdl.handle.net/123456789/618 | |
dc.description | Supervised by Prof. Dr. Muhammad Mahbul Alam | en_US |
dc.description.abstract | The significance of high-performance dedicated networks has well recognized due to the rapidly increasing number of large-scale applications that require high-speed data transfer. Efficient algorithms are needed for path computation and bandwidth scheduling in dedicated networks to improve the utilization of network resources and meet diverse user request. We consider three periodic bandwidth scheduling problems: multiple data transfer allocation (MDTA), multiple data transfer allocation with shortest job first (MDTA/SJF) and multiple fixed-slot bandwidth reservation (MFBR), all of which schedule a number a number of user requests accumulated in a certain period. MDTA is to assign multiple data transfer requests on several pre-specified network paths to minimize the total data transfer end time, while MDTA/SJF is to minimize the total transfer end time by sorting the user requests in increasing order, while MFBR is to satisfy multiple bandwidth reservation requests, each of which specifies a bandwidth and a time slot. For MDTA, and MDTA/SJF we design an optimal algorithm and provide its corresponding proof. For MFBR we prove an algorithm and purpose of the algorithm, Minimal Bandwidth and Distance Product Algorithm (MBDPA). Extensively simulation results illustrate the performance of superiority of the proposed MDBPA algorithm over a greedy approach and provide valuable insight into the advantage of periodic bandwidth scheduling over instant bandwidth scheduling. | en_US |
dc.language.iso | en | en_US |
dc.publisher | Department of Computer Science and Engineering, Islamic University of Technology, Board Bazar, Gazipur, Bangladesh | en_US |
dc.title | Bandwidth Scheduling Algorith for Multiple Data Transfers in High Performance Networks (HPNS) | en_US |
dc.type | Thesis | en_US |