4 research outputs found
Fiber optical network design problems : case for Turkey
Ankara : The Department of Industrial Engineering and the Graduate School of Engineering and Science of Bilkent University, 2013.Thesis (Master's) -- Bilkent University, 2013.Includes bibliographical references leaves 102-110.The problems within scope of this thesis are based on an application arising from one of
the largest Internet service providers operating in Turkey. There are mainly two different
problems: the green field design and copper field re-design. In the green field design
problem, the aim is to design a least cost fiber optical network from scratch that will
provide high bandwidth Internet access from a given central station to a set of
aggregated demand nodes. Such an access can be provided either directly by installing
fibers or indirectly by utilizing passive splitters. Insertion loss, bandwidth level and
distance limitations should simultaneously be considered in order to provide a least cost
design to enable the required service level. On the other hand, in the re-design of the
copper field application, the aim is to improve the current service level by augmenting
the network through fiber optical wires. Copper rings in the existing infrastructure are
augmented with cabinets and direct fiber links from cabinets to demand nodes provide
the required coverage to distant nodes. Mathematical models are constructed for both
problem specifications. Extensive computational results based on real data from Kartal
(45 points) and Bakırköy (74 points) districts in Istanbul show that the proposed models
are viable exact solution methodologies for moderate dimensions.Yazar, BaşakM.S
Resilient virtual topologies in optical networks and clouds
Optical networks play a crucial role in the development of Internet by providing a high speed infrastructure to cope with the rapid expansion of high bandwidth demand applications such as video, HDTV, teleconferencing, cloud computing, and so on. Network virtualization has been proposed as a key enabler for the next generation networks and the future Internet because it allows diversification the underlying architecture of Internet and lets multiple heterogeneous network architectures coexist.
Physical network failures often come from natural disasters or human errors, and thus cannot be fully avoided. Today, with the increase of network traffic and the popularity of virtualization and cloud computing, due to the sharing nature of network virtualization, one single failure in the underlying physical network can affect thousands of customers and cost millions of dollars in revenue. Providing resilience for virtual network topology over optical network infrastructure thus becomes of prime importance.
This thesis focuses on resilient virtual topologies in optical networks and cloud computing. We aim at finding more scalable models to solve the problem of designing survivable logical topologies for more realistic and meaningful network instances while meeting the requirements on bandwidth, security, as well as other quality of service such as recovery time.
To address the scalability issue, we present a model based on a column generation decomposition. We apply the cutset theorem with a decomposition framework and lazy constraints. We are able to solve for much larger network instances than the ones in literature. We extend the model to address the survivability problem in the context of optical networks where the characteristics of optical networks such as lightpaths and wavelength continuity and traffic grooming are taken into account.
We analyze and compare the bandwidth requirement between the two main approaches in providing resiliency for logical topologies. In the first approach, called optical protection, the resilient mechanism is provided by the optical layer. In the second one, called logical restoration, the resilient mechanism is done at the virtual layer. Next, we extend the survivability problem into the context of cloud computing where the major complexity arises from the anycast principle. We are able to solve the problem for much larger network instances than in the previous studies. Moreover, our model is more comprehensive that takes into account other QoS criteria, such that recovery time and delay requirement