IP and ATM - current evolution for integrated services

Current and future applications make use of different technologies as voice, data, and video. Consequently network technologies need to support them. For many years, the ATM based Broadband-ISDN has generally been regarded as the ultimate networking technology, which can integrate voice, data, and video services. With the recent tremendous growth of the Internet and the reluctant deployment of public ATM networks, the future development of ATM seems to be less clear than it used to be. In the past IP provided (and was though to provide) only best effort services, thus, despite its world wide diffution, was not considered as a network solution for multimedia application. Currently many of the IETF working groups work on areas related to integrated services, and IP is also proposing itself as networking technology for supporting voice, data, and video services. This paper give a technical overview on the competing integrated services network solutions, such as IP, ATM and the different available and emerging technologies on how to run IP over ATM, and tries to identify their potential and shortcomings

IP and ATM integration: A New paradigm in multi-service internetworking

ATM is a widespread technology adopted by many to support advanced data communication, in particular efficient Internet services provision. The expected challenges of multimedia communication together with the increasing massive utilization of IP-based applications urgently require redesign of networking solutions in terms of both new functionalities and enhanced performance. However, the networking context is affected by so many changes, and to some extent chaotic growth, that any approach based on a structured and complex top-down architecture is unlikely to be applicable. Instead, an approach based on finding out the best match between realistic service requirements and the pragmatic, intelligent use of technical opportunities made available by the product market seems more appropriate. By following this approach, innovations and improvements can be introduced at different times, not necessarily complying with each other according to a coherent overall design. With the aim of pursuing feasible innovations in the different networking aspects, we look at both IP and ATM internetworking in order to investigating a few of the most crucial topics/ issues related to the IP and ATM integration perspective. This research would also address various means of internetworking the Internet Protocol (IP) and Asynchronous Transfer Mode (ATM) with an objective of identifying the best possible means of delivering Quality of Service (QoS) requirements for multi-service applications, exploiting the meritorious features that IP and ATM have to offer. Although IP and ATM often have been viewed as competitors, their complementary strengths and limitations from a natural alliance that combines the best aspects of both the technologies. For instance, one limitation of ATM networks has been the relatively large gap between the speed of the network paths and the control operations needed to configure those data paths to meet changing user needs. IP\u27s greatest strength, on the other hand, is the inherent flexibility and its capacity to adapt rapidly to changing conditions. These complementary strengths and limitations make it natural to combine IP with ATM to obtain the best that each has to offer. Over time many models and architectures have evolved for IP/ATM internetworking and they have impacted the fundamental thinking in internetworking IP and ATM. These technologies, architectures, models and implementations will be reviewed in greater detail in addressing possible issues in integrating these architectures s in a multi-service, enterprise network. The objective being to make recommendations as to the best means of interworking the two in exploiting the salient features of one another to provide a faster, reliable, scalable, robust, QoS aware network in the most economical manner. How IP will be carried over ATM when a commercial worldwide ATM network is deployed is not addressed and the details of such a network still remain in a state of flux to specify anything concrete. Our research findings culminated with a strong recommendation that the best model to adopt, in light of the impending integrated service requirements of future multi-service environments, is an ATM core with IP at the edges to realize the best of both technologies in delivering QoS guarantees in a seamless manner to any node in the enterprise

Design of a Scalable Path Service for the Internet

Despite the world-changing success of the Internet, shortcomings in its routing and forwarding system have become increasingly apparent. One symptom is an escalating tension between users and providers over the control of routing and forwarding of packets: providers understandably want to control use of their infrastructure, and users understandably want paths with sufficient quality-of-service (QoS) to improve the performance of their applications. As a result, users resort to various “hacks” such as sending traffic through intermediate end-systems, and the providers fight back with mechanisms to inspect and block such traffic. To enable users and providers to jointly control routing and forwarding policies, recent research has considered various architectural approaches in which provider- level route determination occurs separately from forwarding. With this separation, provider-level path computation and selection can be provided as a centralized service: users (or their applications) send path queries to a path service to obtain provider- level paths that meet their application-specific QoS requirements. At the same time, providers can control the use of their infrastructure by dictating how packets are forwarded across their network. The separation of routing and forwarding offers many advantages, but also brings a number of challenges such as scalability. In particular, the path service must respond to path queries in a timely manner and periodically collect topology information containing load-dependent (i.e., performance) routing information. We present a new design for a path service that makes use of expensive pre- computations, parallel on-demand computations on performance information, and caching of recently computed paths to achieve scalability. We demonstrate that, us- ing commodity hardware with a modest amount of resources, the path service can respond to path queries with acceptable latency under a realistic workload. The ser- vice can scale to arbitrarily large topologies through parallelism. Finally, we describe how to utilize the path service in the current Internet with existing Internet applica- tions

Concepção e implementação de experiências laboratoriais sobre MPLS

Mestrado em Engenharia Electrónica e TelecomunicaçõesO Multiprotocol Label Switching (MPLS) é um mecanismo de transporte de dados, sob a forma de um protocolo agnóstico, com grande potencial de crescimento e adequação. Opera na “Camada 2.5” do modelo OSI e constitui um mecanismo de alto desempenho utilizado nas redes de núcleo para transportar dados de um nó da rede para outro. O sucesso do MPLS resulta do facto de permitir que a rede transporte todos os tipos de dados, desde tráfego IP a tráfego da camada de ligação de dados, devido ao encapsulamento dos pacotes dos diversos protocolos, permitindo a criação de “links virtuais” entre nós distantes. O MPLS pertence à família das “redes de comutação de pacotes”, sendo os pacotes de dados associados a “etiquetas” que determinam o seu encaminhamento, sem necessidade de examinar o conteúdo dos próprios pacotes. Isto permite a criação de circuitos “extremo-aextremo” através de qualquer tipo de rede de transporte e independentemente do protocolo de encaminhamento que é utilizado. O projecto do MPLS considera múltiplas tecnologias no sentido de prestar um serviço único de transporte de dados, tentando simultaneamente proporcionar capacidades de engenharia de tráfego e controlo “out-of-band”, uma característica muito atraente para uma implementação em grande escala. No fundo, o MPLS é uma forma de consolidar muitas redes IP dentro de uma única rede. Dada a importância desta tecnologia, é urgente desenvolver ferramentas que permitam entender melhor a sua complexidade. O MPLS corre normalmente nas redes de núcleo dos ISPs. No sentido de tornar o seu estudo viável, recorreu-se nesta dissertação à emulação para implementar cenários de complexidade adequada. Existem actualmente boas ferramentas disponíveis que permitem a recriação em laboratório de cenários bastante complicados. Contudo, a exigência computacional da emulação é proporcional à complexidade do projecto em questão, tornando-se rapidamente impossível de realizar numa única máquina. A computação distribuída ou a “Cloud Computing” são actualmente as abordagens mais adequadas e inovadoras apara a resolução deste problema. Esta dissertação tem como objectivo criar algumas experiências em laboratório que evidenciam aspectos relevantes da tecnologia MPLS, usando para esse efeito um emulador computacional, o Dynamips, impulsionado por generosas fontes computacionais disponibilizadas pela Amazon ec2. A utilização destas ferramentas de emulação permite testar cenários de rede e serviços reais em ambiente controlado, efectuando o debugging das suas configurações e optimizando o seu desempenho, antes de os colocar em funcionamento nas redes em operação.The Multiprotocol Label Switching (MPLS) is a highly scalable and agnostic protocol to carry network data. Operating at "Layer 2.5" of the OSI model, MPLS is an highperformance mechanism that is used at the network backbone for conveying data from one network node to the next. The success of MPLS results from the fact that it enables the network to carry all kinds of traffic, ranging from IP to layer 2 traffic, since it encapsulates the packets of the diverse network protocols, allowing the creation of "virtual links" between distant nodes. MPLS belongs to the family of packet switched networks, where labels are assigned to data packets that are forwarded based on decisions that rely only on the label contents, without the need to examine the packets contents. This allows the creation of end-to-end circuits across any type of transport medium, using any protocol. The MPLS design takes multiform transport technologies into account to provide a unified data-carrying service, attempting simultaneously to preserve traffic engineering and out-of-band control, a very attractive characteristic for large-scale deployment. MPLS is the way to consolidate many IP networks into a single one. Due to this obvious potential, it is urgent to develop means and tools to better understand its functioning and complexity. MPLS normally runs at the backbone of Service Providers networks, being deployed across an extensive set of expensive equipment. In order to turn the study of MPLS feasible, emulation was considered as the best solution. Currently, there are very good available tools to recreate, in a lab environment, quite complicated scenarios. However, the computational demand of the emulation is proportional to the complexity of the project, becoming quickly unfeasible in a single machine. Fortunately, distributed computing or Cloud computing are suitable and novel approaches to solve this computation problem. So, this work aims to create some lab experiments that can illustrate/demonstrate relevant aspects of the MPLS technology, using the Dynamips emulator driven by the computational resources that were made available by the Amazon ec2 cloud computing facilities. The utilization of these emulation tools allows testing real networks and service scenarios in a controlled environment, being able to debug their configurations and optimize their performance before deploying them in real operating networks

System architecture and hardware implementations for a reconfigurable MPLS router

With extremely wide bandwidth and good channel properties, optical fibers have brought fast and reliable data transmission to today’s data communications. However, to handle heavy traffic flowing through optical physical links, much faster processing speed is required or else congestion can take place at network nodes. Also, to provide people with voice, data and all categories of multimedia services, distinguishing between different data flows is a requirement. To address these router performance, Quality of Service /Class of Service and traffic engineering issues, Multi-Protocol Label Switching (MPLS) was proposed for IP-based Internetworks. In addition, routers flexible in hardware architecture in order to support ever-evolving protocols and services without causing big infrastructure modification or replacement are also desirable. Therefore, reconfigurable hardware implementation of MPLS was proposed in this project to obtain the overall fast processing speed at network nodes. The long-term goal of this project is to develop a reconfigurable MPLS router, which uniquely integrates the best features of operations being conducted in software and in run-time-reconfigurable hardware. The scope of this thesis includes system architecture and service algorithm considerations, Verilog coding and testing for an actual device. The hardware and software co-design technique was used to partition and schedule the protocol code for execution on both a general-purpose processor and stream-based hardware. A novel RPS scheme that is practically easy to build and can realize pipelined packet-by-packet data transfer at each output was proposed to take the place of the traditional crossbar switching. In RPS, packets with variable lengths can be switched intelligently without performing packet segmentation and reassembly. Primary theoretical analysis of queuing issues was discussed and an improved multiple queue service scheduling policy UD-WRR was proposed, which can reduce packet-waiting time without sacrificing the performance. In order to have the tests carried out appropriately, dedicated circuitry for the MPLS functional block to interface a specific MAC chip was implemented as well. The hardware designs for all functions were realized with a single Field Programmable Gate Array (FPGA) device in this project. The main result presented in this thesis was the MPLS function implementation realizing a major part of layer three routing at the reconfigurable hardware level, which advanced a great step towards the goal of building a router that is both fast and flexible

Journal of Telecommunications and Information Technology, 2003, nr 4

kwartalni

Advanced Signaling Support for IP-based Networks

This work develops a set of advanced signaling concepts for IP-based networks. It proposes a design for secure and authentic signaling and provides QoS signaling support for mobile users. Furthermore, this work develops methods which allow for scalable QoS signaling by realizing QoS-based group communication mechanisms and through aggregation of resource reservations