WAVEFORM and TWINWAVE microwave links are designed for wide range of application with focus for high flexibility and system efficiency. All systems can be extended by additional EMM cards (external extension module) which increase number and type of connected ports. WAVEFORM family of microwave links is available in split mount and rack mount (full indoor) version. TWINWAVE microwave links are designed for full outdoor application with exceptional two carrier modification in one housing.

uNMS's comprehensive, E2E perspective supports comprehensive definition of MPLS tunnels, Ethernet services, and SDH/SONET and optical trails, for primary and protection paths. uNMS supports all types of trails and links (MoT, MoE, EoS, ETY, SDH/SONET, optical), protection schemes, and user constraints. Simply point and click to connect any two endpoints, even in the most complex topology. uNMS provides powerful trail reconstruction options to reconcile discrepancies between different layers, as well as batch traffic management capabilities. uNMS provides smoothly integrated management for packet, optical, and MSPP-based platforms. Our management concept is based on a layered architecture in accordance with the ITU-T M.3010 standard for compliant layer architecture. Also we will support Service Operations Guidelines(MEF-50) and LSO Reference Architecture and frameworks(MEF-55). Separate layers make up the management structure.

• Data Layer Abstraction: At the heart of our management approach lays the multi-layer multi-technology concept, tailored to transport networks that rely on multiple technologies (data, TDM, optics). uNMS helps network operators focus on the particular layer of interest by graphically separating the various layers. For example, the data layer view displays the Ethernet technology layer with data logical elements (LEs) only, providing a simple, intuitive, and easy-to-grasp view.
• Inserting and Removing Provider Edge (PE) Nodes: One issue that can be an endless source of errors and loss of service is any change in the network that calls for insertion or removal of a PE node. With one simple mouse-click, uNMS's powerful insert-and-remove-PE node function initiates a completely automatic reconfiguration and recalculation of tunnels and services traversing the link associated with that PE node. In this way, human error and exhausting manual reconfiguration are avoided.
• Point-and-Click MPLS-TP Tunnel/Service Configuration: With uNMS, point-and-click is not merely a catchy phrase. Simply select the endpoints and the associated tunnels and services are automatically selected as well. The ease of implementing P2P, P2MP, MP2MP, HVPLS, and CES yields tangible OPEX savings. The services can be auto-provisioned over a combination of MPLS and Provider Bridge (PB) networks. For example, even complex MP2MP services are activated in 2-3 minutes (instead of the typically required 10-15 minutes with the CLI scheme).
• IP/MPLS L2VPN/L3VPN Service Management: uNMS makes it simple to manage IP/MPLS L2/L3VPN services, offering point-and-click convenience for configuring, monitoring, and viewing them in a network-wide view. IP/MPLS management includes the full set of L2/L3VPN services over IP/MPLS.
• Automated Provisioning: With the operator in mind, uNMS provides a set of easy-to-use automation tools that make provisioning across complex networks a simple and scalable task. New PEs and links are configured automatically with a system preference default feature. This saves time and trouble when provisioning, as there is no need to re-create the list of all the relevant configuration parameters each time. Automatic provisioning features include automatic tunnel creation over complex topologies and automatic bypass tunnel assignment.

uNMS offers the important advantage of resource optimization, since uNMS’s sophisticated pathfinding algorithm can be programmed to account for criteria such as shared risk link group (SRLG), link cost, length, and minimum hops. In this way, the operator benefits from a built-in optimization tool that eliminates the need for cumbersome offline planning and optimization tools. uNMS also offers a unique enhanced FRR (eFRR) mechanism that saves bandwidth by connecting source and destination directly. Bandwidth that would be wasted by classic node-and-link FRR schemes routing the signal back and forth can be exploited for other purposes. In addition, the eFRR mechanism increases resiliency by enabling fast recovery from double failures as well, one in each ring. uNMS’s northbound interface (NBI) was developed according to MTNM (also known as TMF-814), the leading industry standard and based on CORBA. It is rich in functionality and allows uNMS to be integrated under any OSS for alarms, and equipment and service inventory retrieval. The single point of integration and standards-based approach means that any new equipment or version deployed under uNMS does not require additional integration efforts.