A key objective of 5G and Software Defined Networking (SDN) technologies is the provision of Quality of Service (QoS) guarantees. These guarantees are reflected to the requirements emerging from the agreements between the customers and service providers, the corresponding Service Level Agreements (SLAs). While traditional SLAs included aspects for example regarding data center availability of "five 9s", or five minutes of downtime per year [1], a 5G-driven SLA includes additional aspects related both to the infrastructure and to the provisioned services, as for example: “five 9s availability” while also “2 seconds to deploy a new Service Instance”.
But what is an SLA? An SLA is a contract between the Network Service (NS) provider and the customer, which underlines each party’s responsibilities while at the same time defining the performance standards that are to be met by the provider [2]. SLAs establish customer expectations regarding the service provider's performance and overall quality. Over the past few years, SLAs set the expectations for a service provider performance, establish penalties for missing the targets and, in some cases, bonuses for exceeding them. In that concept, SDN explosion could not leave unaffected the evolution of SLA models, and their flexibility in adapting more demanded parameters. 5GTANGO is a frontrunner in defining SLAs for 5G environments, by introducing a complete SLA Management Framework, in order to fulfill the gap between NS providers and their customers [3].

As factories become mobile, machines will physically move inside a factory or to another site. Current network infrastructure does not match the associated requirements because wired connections and fix subnets as well as fix routes cause high effort for each adaptation. Using NFV technology and the 5GTANGO platform, the factory network will be raised to a new level of flexibility.

The smart manufacturing pilot focuses on three use cases for modern factories: create an innovative, flexible factory network and analyze the operational data, machine data, and process data (O/M/P data) gathered from the machines; detecting and containing threats; and enable augmented reality (AR-)based support for machine maintenance and repairs.

The following use cases were defined during a face-2-face meeting at Weidmüller premises in Detmold. The participants gained many insights of a manufacturing process by visiting one of Weidmüller’s factories and created a time schedule for the development of needed components. Many aspects of the use cases will be tested and evaluated in demonstration setups during the final year of 5GTANGO.

You may have heard that ONAP is preparing for its second release in a few weeks time.Perhaps now is a good time to take another look at the goals of ONAP, its current direction and how ONAP can actually be a part of the final realization of the vision for NFV.

In this blog post, we describe the integrated workflow with 5GTANGO's SDK from setting up a workspace to on-boarding a complete package with a desired network service. The SDK supports developers in all these steps through multiple tools that work together seamlessly and are available on public GitHub repositories.

You may have heard ETSI started a few months ago a new ISG, codenamed ZSM, focused on achieving full automation in network service management.

First things first: an ETSI ISG (Industry Specification Group) is a group dedicated to analyse and standardize a particular technology of interest to the telecommunications industry, with a few interesting characteristics: it is widely open to any participant worldwide, it has to renew its mandate every few (typically two years), and it is expected to be focused not only in produce documents, in the form of reports and specifications, but also on demonstrate them by means of experiments (proofs of concept) and interoperability events. This makes an ISG a quite powerful tool to shape the evolution of technologies that are in their initial consolidation stages in the network and telecommunications landscape. ETSI ISGs have defined the NFV framework and the MEC foundations.

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