IP and Transport networks are controlled and operated independently today, leading to significant Capex and Opex inefficiencies for the providers. We discuss a unified approach with OpenFlow, and present a recent demonstration of a unified control plane for OpenFlow enabled IP/Ethernet and TDM switched networks. IntroductionWide area networks are expensive to own from a service provider perspective and it is widely understood that much of this cost is in operational expenses. However, service providers such as AT&T and Verizon are obliged to own and operate two distinct networks for IP and Transport. These networks are typically planned, designed and managed by separate divisions within the same organization, leading to substantial management overhead, functionality/resource duplication, and increased Opex. This issue has been widely discussed over the last decade.An important aspect of these networks is that the two do not dynamically interact. The IP network does not exploit the full capabilities offered by the underlying Transport network because IP routers are typically interconnected via static circuits created in the Transport network. The IP network simply views these circuits as fixed pipes that make up the (virtual) IP links. The natural consequence is that carriers do not benefit from dynamic circuit switching in the core, where the latter can offer significant advantages. For example, circuit switches are more easily scalable, switch at higher data rates and consume much less power than packet switches. A useful rule of thumb is that an optical circuit switch consumes a 10 th of the volume and power, and costs 10 times less than an equivalent electronic packet switch with the same capacity. While circuit switches lack the statistical multiplexing benefits of packet switches, this is of less significance in the core, where flows are naturally aggregated and relatively smooth. If the network operations could be unified, and circuits could be dynamically created, modified and destroyed, the service provider could benefit from a more cost-efficient and energy efficient converged network. Such a network would scale better to rising traffic and changing service needs, while reaping the benefits of both kinds of switching technologies -packet switching and dynamic circuit switching.While we are not the first to suggest the benefits of such convergence, we believe one of the main reasons preventing such convergence is the control and management architecture of the two networks. IP networks have control mechanisms that are fully-distributed and tightly linked to the task of packet forwarding in each switch and router in the network. Because of the tight linkage, it becomes difficult to introduce new routing mechanisms or applications into the network. Contrastingly, Transport networks have traditionally had a clean separation between control and data planes, but have no visibility into IP traffic patterns and application requirements, and have been managed primarily through EMS/NMS systems under the ...
The intentional release or threat of release of biologic agents (i.e. viruses, bacteria, fungi or their toxins) in order to cause disease or death among human population or food crops and livestock to terrorize a civilian population or manipulate the government in the present scenario of increased terrorist activity has become a real possibility. The most important step in the event of a bioterrorist attack is the identification of the event. This can be achieved by generating awareness, having high degree of suspicion and having a good surveillance system to assist quick detection. Bioterrorist attacks could be covert or announced and caused by virtually any pathogenic microorganism. Bioterrorist agents of major concern have been categorized as A, B and C based on the priority of the agents to pose a risk to the national security and the ease with which they can be disseminated. The five phases of activities in dealing with a bioterrorist attack are preparedness phase, early warning phase, notification phase, response phase and recovery phase. A bioterrorism attack in a public place is a public health emergency. Early detection and rapid investigation is the key to contain such attacks. The role of public health epidemiologist is critical not only in determining the scope and magnitude of the attack but also in effective implementation of interventions. MJAFI 2010; 66 : 255-260
OpenFlow & Software Defined Networking (SDN) ideas offer drastically reduced complexity in the control plane, increased programmability and extensibility, and a gradual adoption path; all significant advantages over GMPLS for dynamic interaction between packet and circuit networks.
Abstract-There have been many attempts to unify the control and management of circuit and packet switched networks, but none have taken hold. In this paper we propose a simple way to unify both types of network using OpenFlow. The basic idea is that a simple flow abstraction fits well with both types of network, provides a common paradigm for control, and makes it easy to insert new functionality into the network. OpenFlow provides a common API to the underlying hardware, and allows all of the routing, control and management to be defined in software outside the datapath.
Abstract:We demonstrate a converged OpenFlow enabled packet-circuit network, where circuit flow properties (guarantee d bandwidth, low latency, low jitter, bandwidth-on-demand, fast recovery) provide differential treatment to dynamically aggregated packet flows for voice, video and web traffic.
Abstract:We propose a new approach to MPLS that uses the standard MPLS data plane and an OpenFlow based simpler and extensible control plane. We demonstrate this approach using a prototype system for MPLS Traffic Engineering.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.