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| GÉANT Whitepaper May 26, 2021 |
5G is a mobile technology that is addressing, by design,abroad range of requirements: very high data rates, very low latency, low energy consumption, high scalability, improved connectivity and reliability, and improved security [FGPPP18], [FGPPP20]. The 5G specifications focus on serving mobile operator needs in terms of extreme mobile broadband services and include several features to support vertical industries in terms of enablers for an industrial Internet of Things (IoT)and Ultra Reliable Low Latency Communications(URLLC)[FGPPP20]. Within the 5G system, end-to-end (E2E) network slicing, service-based architecture, Software-Defined Networking (SDN) and Network Functions Virtualisation (NFV) are seen as the fundamental pillars of the 5G architecture.
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| GÉANT Whitepaper May 26, 2021 |
The European Open Science Cloud (EOSC) initiative [EOS20] is part of the EuropeanCommission’s effortto increase the competitive digital economy in Europe. The main idea of the initiative is to support Open Science, which in turn will enable a more agile approach to innovation. The main goal of EOSC is to provide researchers from different research fields with the means necessary not only to conduct research, but alsotomake their research outcomes open to the wide community. Thus, in essence, the end goal is to create a cloud-based virtual environment that will provide a number of open services that can be used to store, manage and analyse research data.Six different actions are being implemented in parallel to achieve this goal, described in the EOSC implementation roadmap [ETS20]. One of the action lines focuses on the architecture of the virtual environment,whichshould achieve a federated, seamless view of all available research infrastructures and services built on top. |
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EOSCtechnicalarchitecture–interactionsbetween
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| GÉANT Whitepaper May 26, 2021 |
One of the main requirements for future architectures and digital service providers is to be able to transform all manual management of network and services into Automated and Autonomic Management & Control (AMC) so that the system dynamically responds to the changing environment. This behaviour is also known as autonomics and is the main focus of the Generic Autonomic Network Architecture (GANA) [GANA16]. In other words, the GANA reference model provides a way to build autonomic architecture using a generic AMC framework that can integrate with any type of network management architecture. The ETSI Network Technologies (NTECH) Autonomic network engineering for the self-managing Future Internet (AFI)workinggroup leads the AMC standardisation efforts that will transform the traditional networking environment into a smart and intelligent network with a number of self-* features including self-healing, self-configuration, self-optimisation and others.
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| GÉANT Whitepaper May 26, 2021 |
ETSI Open Source MANO(OSM)[EOSM20] is a management and orchestration solution that complies withtheETSI NFV architectural framework. While it offers its own Virtual Infrastructure Manager (VIM),it also supports many third-party VIMssuch asOpenStack, VMware vCloud and VIO, Amazon Web Services, Azure and Google Cloud and,since release seven,also Kubernetes. This last integration allowsthedeployment ofmore than 20,000 pre-existing production-ready Kubernetes applications, with no need of any translation or repackaging, which are added to the steadily increasing number of Virtual Network Functions (VNFs)commercially or freely available. |
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| GÉANT Whitepaper May 26, 2021 |
TheEuropean Telecommunications Standards Institute(ETSI)Zero-touch network and Service Management(ZSM)working group has the aim of defining a universal framework to enable end-to-endzero-touchserviceautomationinvolvingdifferentmanagementdomains.The proposed framework[EZSM]focuses on closed-loop service automation based on monitoring and high-quantity data collection, to which machine learning and artificial intelligence proceduresapply. The end-to-end automation procedures considered by ETSI ZSM comprise all operational processes and tasks, including delivery, deployment, configuration, lifecycle management, assurance, optimisation and finalisation. It aims to provide 5G E2E network slicing and management capacity, ideally with 100% automation or zero human intervention,and aims to be general enough to integrate current and future networks and services. |
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| GÉANT Whitepaper May 26, 2021 |
The Generalized Virtualization Model (GVM) describes an architecture that supports managing the lifecycle of different network topologies as virtual network slices over a physical infrastructure in a fully automated fashion. These virtual networks are environments where abstracted virtualised objects,called resources, can be defined, instantiated and arranged to create application-specific insulated networks and services. This process is performed via agraphicaluserinterface (GUI) and without the need for human intervention from network operationsor engineering teams.
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Virtualisation, management and user control layers in GVM
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| GÉANT Whitepaper May 26, 2021 |
Metro EthernetForum Lifecycle Service Orchestration(MEF LSO) [MSOS16] is a layered abstraction architecture defined to build the systems for coordinated management and control across all network domains responsible for delivering an end-to-end connectivity service. LSO provides interoperable automation of operations over the entire lifecycle of Layer 2 and Layer 3 connectivity services,as shown inFigureB.2. This includes design, fulfilment, control, testing, problem management, quality management, billing & usage, security, analytics and policy capabilities. The architecture specifies high-level functional requirements, the functional management entities and the management interface reference points (logical points of interaction) between them. |
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| GÉANT Whitepaper May 26, 2021 |
Open Baton [OB20] is an open source platform developed by Fraunhofer FOKUS andtheTechnical University ofBerlin that enables implementation of an NFV environment based on the ETSI NFV MANO architecture framework [ETSINFVSPEC].
Open Baton uses an agile development process to provide a customisable network service orchestration framework based on the MANO NFVO. The framework supports multiple sites that provide heterogeneous Network Function Virtualisation infrastructure. Using the generic Virtual Network Function Manager (VNFM) the architecture can manage a large set of different VNFs.
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| manual work and procedures to a model where services are automatically provisioned and orchestrated. The mappingofthe tools in use at GÉANT to functional blocksshows, how ODA can be used as a frameworktounderstandarchitecturesinsituationswhereenvironmentalcomplexityand independent growth have led to dependencies that are not easy to identify. This helps manage and guide the digital transformation process in complex organisations such as GÉANT and other Research and Education (R&E) entities| Column |
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| GÉANT Whitepaper January 24, 2022 |
The document analyses the mapping of theGRNET(Greek Research and TechnologyNetwork) architecture to the TM Forum’s Open Digital Architecture aiming to provide a standardised view of the components and implementations of orchestration, automation,and virtualisation for network management services.
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| The Greek National Research and Education Network(GRNET)provides a network infrastructure for the Greek research and education community,and connects educational and research institutions. It also provides a variety of additional services, including cloud services, high performance computing, Firewall-on-Demand,Firewall-as-a-Service, sound-,video-andteleconference-services,and a large collection of digital servicesforthe educational community. In May 2019 GRNET participated in a GÉANT survey [SURVEY2019, SURVEY-RESULTS] and, as part of that, performed an analysis of existing systems and architecture components in the context of automation, virtualisation, and orchestration. Based on this analysis GRNET architectural components have been identified and matched to the TMForum Open Digital Architecture (ODA) functional blocks.
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| GÉANT Whitepaper October 20May 26, 2021 |
The document analyses the mapping of the HEAnet architecture to the TM Forum’s Open Digital Architecture, aiming to provide a standardised view of the components and implementations of orchestration, automation, and virtualisation within the National Research and Education Networks (NRENs).
Open Network Automation Platform (ONAP) [ONAP20] arose after the combination of two Network Function Virtualisation (NFV) orchestration and management initiatives: Enhanced Control, Orchestration, Management & Policy(ECOMP), led by AT&T, and Open Orchestrator(Open-O), led by China Mobile. |
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| | In this document the team reports on an analysis of the different functional aspects of the HEAnet service management architecture, and how their components map to the ODA reference model. The mapping highlights the main characteristics and capabilities of the current HEAnet architecture, and how they fit into the main functional domains of ODA. The analysis was carried out in July 2021 by the WP6T2 team, supported by HEANet network architects. ONAP architecture
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| GÉANT Whitepaper February 4May 26, 20222021 |
The document analyses themapping of the network architecture of the Polish Optical Internet (PIONIER)- a nationwide broadband optical network for e-science to the TM Forum’s Open Digital Architecture (ODA). This analysis is one of a series of such documents aiming to provide a standardised view of the components and implementations of orchestration, automation and virtualisation (OAV) within the NRENs.
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| | In this document, the team reports on an analysis of the different functional aspects of the PIONIER network architecture, managed by the Poznań Supercomputing and Networking Centre (PSNC). The document focuses on PSNC networking activities,and analyses how different components map to the ODA reference model. The mapping highlights the main characteristics and capabilities of the current PIONIER network architecture, and how they fit into the main functional domains of ODA. The analysis was carried out by the PSNC network architects supported by the WP6T2 team SDN for End-to-end Networked Science at the Exascale (SENSE) [SEN20], [MON18]was developed in a research project with the goal to provide a network architecture that will facilitate the rapid deployment of smart network services in support of science applications. The main contributors to this project are ESnet/Lawrence Berkeley National Laboratory, California Institute of Technology, Fermi National Accelerator Laboratory, Argonne National Laboratory and the University of Maryland College Park.
The architecture was developed with next-generation big data/exascale science workflowsin mind that will require intelligent network services in cloud computing, AI and machine learning. The idea is to support scientists and their science workflows with a system that will automatically build virtual guaranteed networks over large-scale distributed storage and computing infrastructures without any human intervention and without the static non-interactive network infrastructures in place today. |
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| GÉANT Whitepaper December 9May 26, 20202021 |
This document analyses the mapping of the SURFnet architecture to the TM Forum’s Open Digital Architecture, as part of the GN4-3 project’s ongoing activity in the Network Technologies and Service Development’s work package to provide a standardised view of the components and implementations of orchestration, automation and virtualisation within the NRENs. Overall, it can be concluded that the SURFnet OAV architecture, although independently developed, is very much aligned to the ODA’s core principles and design concepts. |
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| | Using a common reference architecture to analyse NREN architectures from an orchestration, automation and virtualisation (OAV) point of view helps align the NRENs’ efforts and find commonalities in the way they implement different functionalities and components. To this end, the GN4-3 WP6 Network Technologies and Services Development OAV team has selected the TM Forum Open Digital Architecture (ODA) to be used as a reference blueprint architecture for cross-comparison. This document presents an analysis performed by the WP6 OAV team of the different functional aspects of the SURFnet network architecture, mapping its components to the TM Forum ODA. The mapping highlights the main characteristics and functionalities of the current SURFnet network architecture and how they fit into the main functional domains of ODA. |
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