964 resultados para software-defined networking (SDN)
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The proposed multi-table lookup architecture provides SDN-based, high-performance packet classification in an OpenFlow v1.1+ SDN switch. The objective of the demonstration is to show the functionality of the architecture deployed on the NetFPGA SUME Platform.
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Network management tools must be able to monitor and analyze traffic flowing through network systems. According to the OpenFlow protocol applied in Software-Defined Networking (SDN), packets are classified into flows that are searched in flow tables. Further actions, such as packet forwarding, modification, and redirection to a group table, are made in the flow table with respect to the search results. A novel hardware solution for SDN-enabled packet classification is presented in this paper. The proposed scheme is focused on a label-based search method, achieving high flexibility in memory usage. The implemented hardware architecture provides optimal lookup performance by configuring the search algorithm and by performing fast incremental update as programmed the software controller.
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Recent trends, such as Software-Defined Networking (SDN), introduce programmability to the network with the opportunity to dynamically route traffic based on flow descriptions. Packet header lookup is the first phase in this process. In this paper, we illustrate improved header lookup and flow rule update speeds over conventional lookup algorithms. This is achieved by performing individual packet header field searches and combining the search results. We propose that individual algorithms should be selected for packet classification based on the application requirements. Improving the network processing performance with our configurable solution will directly support the proposed capability of programmability in SDN.
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Previous attempts in addressing Access Point (AP) association at overlapping zone of IEEE 802.11 networks have shown some issues. They work passively and estimate load from different network metrics such as frame delay, packet loss, number of users etc. that may not always true. Further the user behaviour is selfish i.e. illegitimate user consume high network resources. This adversely affect existing or new users which in turn motivates them to change locations. To alleviate these issues, we propose the use of a Software Defined Networking (SDN) enabled client side (wireless end user) solution. In this paper, we start by proposing a dynamic AP selection algorithm/framework in wireless user device. The device receive network resource related statistics from SDN Controller and guide the client device to associate itself with the best selected AP. We justify that the use of SDN discourage users to act selfishly. Further, a mathematical modelling of the proposed scheme is derived using Fuzzy membership function and the simulation is carried out. Results obtained from simulation necessitates to implement SDN enabled client side methods.
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Il paradigma “Software-Defined Networking” (SDN) ha suscitato recentemente interesse grazie allo sviluppo e all'implementazione di uno standard tecnologico come OpenFlow. Con il modello SDN viene proposta una rete programmabile tramite la separazione dell’unità di controllo e l'unità di instradamento, rendendo quindi i nodi di rete (come ad es. router o switch) esclusivamente hardware che inoltra pacchetti di dati secondo le regole dettate dal controller. OpenFlow rappresenta lo standard dominante nella tecnologia SDN in grado di far comunicare l'unità controller e l'hardware di uno o più nodi di rete. L'utilizzo di OpenFlow consente maggiore dinamicità e agevolazione nella personalizzazione della rete attraverso un'interfaccia utente, includendo svariate funzioni quali la modifica e l’automatizzazione delle regole di instradamento, la creazione di una rete virtuale dotata di nodi logici o la possibilità di monitorare il traffico accrescendo la sicurezza della propria rete.
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Questa tesi è una rassegna sul tema del Software-Defined Networking (SDN):un paradigma emergente nel campo delle reti di calcolatori che consente di controllare, tramite un software centralizzato a livello logico, il comportamento dell’intera rete. In particolore è stato approfondito il protocollo OpenFlow ovvero l'interfaccia aperta e standardizzata per la comunicazione tra piano di controllo e piano di inoltro che è divenuto uno standard “de facto” nell'ambito della tecnologia SDN.
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Le reti devono essere in grado di gestire i modelli di traffico generati dalle nuove applicazioni, per questo si sta concentrando un interesse senza precedenti nella storia di Internet parlando di Software Defined Networking (SDN), un nuovo modo di concepire le reti. SDN è un paradigma che permette di dividere il piano di controllo dal piano dati consentendo il controllo della rete da un dispositivo unico centralizzato,il controller. In questa tesi abbiamo voluto esaminare due specifici casi di studio, affinché si dimostri come SDN possa fornire il miglior supporto per risolvere il problema delle architetture tradizionali, e uno strumento utile per progettare SDN. Per primo viene analizzato Procera, utilizzato nelle reti domestiche e nelle reti campus per dimostrare che, grazie ad esso, è possibile ridurre la complessità di un’intera rete. Poi è stato visto AgNos, un’architettura basata su azioni svolte da agenti rappresentando così un ottimo strumento di lavoro sia perché gli agenti sono implementati nei controller di rete e sia perché AgNos ha la peculiarità di fornire all’utente (o al sistema) un livello stabile di concretezza. Inoltre sono stati analizzati due problemi comuni su Internet: 1.la mitigazione degli attacchi Ddos, dove i domini SDN collaborano per filtrare i pacchetti dalla fonte per evitare l’esaurimento delle risorse 2.l’attuazione di un meccanismo di prevenzione per risolvere il problema dell’attacco Dos nella fase iniziale rendendo l’aggressione più facile da gestire. L’ultimo argomento trattato è il sistema Mininet, ottimo strumento di lavoro in quanto permette di emulare topologie di rete in cui fanno parte host, switch e controller, creati utilizzando il software. Rappresenta un ottimo strumento per implementare reti SDN ed è molto utile per lo sviluppo, l'insegnamento e la ricerca grazie alla sua peculiarità di essere open source.
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Questo elaborato è una rassegna riguardante il Software-Defined Networking ed in particolare il protocollo OpenFlow.
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With the emergence of Internet-of-Things (IoT), there is now growing interest to simplify wireless network controls. This is a very challenging task, comprising information acquisition, information analysis, decision-making, and action implementation on large scale IoT networks. Resulting in research to explore the integration of software-defined networking (SDN) and IoT for a simpler, easier, and strain less network control. SDN is a promising novel paradigm shift which has the capability to enable a simplified and robust programmable wireless network serving an array of physical objects and applications. This paper starts with the emergence of SDN and then highlights recent significant developments in the wireless and optical domains with the aim of integrating SDN and IoT. Challenges in SDN and IoT integration are also discussed from both security and scalability perspectives.
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The proposition of increased innovation in network applications and reduced cost for network operators has won over the networking world to the vision of Software-Defined Networking (SDN). With the excitement of holistic visibility across the network and the ability to program network devices, developers have rushed to present a range of new SDN-compliant hardware, software and services. However, amidst this frenzy of activity, one key element has only recently entered the debate: Network Security. In this article, security in SDN is surveyed presenting both the research community and industry advances in this area. The challenges to securing the network from the persistent attacker are discussed and the holistic approach to the security architecture that is required for SDN is described. Future research directions that will be key to providing network security in SDN are identified.
Resumo:
Resource management is of paramount importance in network scenarios and it is a long-standing and still open issue. Unfortunately, while technology and innovation continue to evolve, our network infrastructure system has been maintained almost in the same shape for decades and this phenomenon is known as “Internet ossification”. Software-Defined Networking (SDN) is an emerging paradigm in computer networking that allows a logically centralized software program to control the behavior of an entire network. This is done by decoupling the network control logic from the underlying physical routers and switches that forward traffic to the selected destination. One mechanism that allows the control plane to communicate with the data plane is OpenFlow. The network operators could write high-level control programs that specify the behavior of an entire network. Moreover, the centralized control makes it possible to define more specific and complex tasks that could involve many network functionalities, e.g., security, resource management and control, into a single framework. Nowadays, the explosive growth of real time applications that require stringent Quality of Service (QoS) guarantees, brings the network programmers to design network protocols that deliver certain performance guarantees. This thesis exploits the use of SDN in conjunction with OpenFlow to manage differentiating network services with an high QoS. Initially, we define a QoS Management and Orchestration architecture that allows us to manage the network in a modular way. Then, we provide a seamless integration between the architecture and the standard SDN paradigm following the separation between the control and data planes. This work is a first step towards the deployment of our proposal in the University of California, Los Angeles (UCLA) campus network with differentiating services and stringent QoS requirements. We also plan to exploit our solution to manage the handoff between different network technologies, e.g., Wi-Fi and WiMAX. Indeed, the model can be run with different parameters, depending on the communication protocol and can provide optimal results to be implemented on the campus network.
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The telecommunication industry is entering a new era. The increased traffic demands imposed by the huge number of always-on connections require a quantum leap in the field of enabling techniques. Furthermore, subscribers expect ever increasing quality of experience with its joys and wonders, while network operators and service providers aim for cost-efficient networks. These requirements require a revolutionary change in the telecommunications industry, as shown by the success of virtualization in the IT industry, which is now driving the deployment and expansion of cloud computing. Telecommunications providers are currently rethinking their network architecture from one consisting of a multitude of black boxes with specialized network hardware and software to a new architecture consisting of “white box” hardware running a multitude of specialized network software. This network software may be data plane software providing network functions virtualization (NVF) or control plane software providing centralized network management — software defined networking (SDN). It is expected that these architectural changes will permeate networks as wide ranging in size as the Internet core networks, to metro networks, to enterprise networks and as wide ranging in functionality as converged packet-optical networks, to wireless core networks, to wireless radio access networks.
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Cloud services are exploding, and organizations are converging their data centers in order to take advantage of the predictability, continuity, and quality of service delivered by virtualization technologies. In parallel, energy-efficient and high-security networking is of increasing importance. Network operators, and service and product providers require a new network solution to efficiently tackle the increasing demands of this changing network landscape. Software-defined networking has emerged as an efficient network technology capable of supporting the dynamic nature of future network functions and intelligent applications while lowering operating costs through simplified hardware, software, and management. In this article, the question of how to achieve a successful carrier grade network with software-defined networking is raised. Specific focus is placed on the challenges of network performance, scalability, security, and interoperability with the proposal of potential solution directions.
Resumo:
Software-defined network (SDN) is the next generation of networking architecture that is dynamic, manageable, cost-effective, and adaptable, making it ideal for the high-bandwidth, dynamic nature of today's applications. In SDN, network management is facilitated through software rather than low-level device configurations. However, the centralized control plane introduced by SDN imposes a great challenge for the network security. In this paper, we present a secure SDN structure, in which each device is managed by multiple controllers rather than a single one as in a traditional manner. It can resist Byzantine attacks on controllers and the communication links between controllers and SDN switches. Furthermore, we design a cost-efficient controller assignment algorithm to minimize the number of required controllers for a given set of switches. Extensive simulations have been conducted to show that our proposed algorithm significantly outperforms random algorithms. © 2014 IEEE.
Resumo:
One of the core properties of Software Defined Networking (SDN) is the ability for third parties to develop network applications. This introduces increased potential for innovation in networking from performance-enhanced to energy-efficient designs. In SDN, the application connects with the network via the SDN controller. A specific concern relating to this communication channel is whether an application can be trusted or not. For example, what information about the network state is gathered by the application? Is this information necessary for the application to execute or is it gathered for malicious intent? In this paper we present an approach to secure the northbound interface by introducing a permissions system that ensures that controller operations are available to trusted applications only. Implementation of this permissions system with our Operation Checkpoint adds negligible overhead and illustrates successful defense against unauthorized control function access attempts.
