Abstract: A method supporting distributed resilient network interconnect (DRNI) in a link aggregation group at a network device is disclosed. The method starts with encapsulating a distributed relay control protocol data unit (DRCPDU) in a frame, wherein the DRCPDU includes a protocol data unit (PDU) structure. The PDU structure includes a type field indicating that the DRCPDU is for DRCP, a version field indicating a version number of the DRCP, and a set of type/length/values (TLVs) including: a terminator TLV indicating an end of the PDU structure, a portal information TLV indicating characteristics of the first portal, a portal configuration information TLV indicating configuration information of the first portal, a DRCP state TLV indicating variables associated with an intra-portal link (IPP), a home ports information TLV and a neighbor ports information TLV. The method continues with transmitting the frame encapsulating the DRCPDU from the network device to a neighbor network device.

Abstract: A method supporting network and intra-portal link (IPL) sharing in a link aggregation group at a network device is disclosed. The method starts with transmitting frames on the IPL at the network device, where the physical link or aggregation link of the link aggregation group is dedicated to the IPL. The network device determines that the network device is configured with a network and IPL sharing method that is consistent with the neighbor network device, the network and IPL sharing method including sharing by at least one of time, tag, and encapsulation, where the network and IPL sharing method indicates sharing of the physical link or link aggregation between frames for the IPL and frames for another IPL or a network link of the link aggregation group. Then the network device transmits the frames between the network device and the neighbor network device using the network and IPL sharing method.

Abstract: A method forward Ethernet frames at a node in a network supporting an implementation of shortest path bridging (SPB) protocol is disclosed. The method starts with a shortest path computation for the node (referred to as the computing node). The shortest path computation selects at least a shortest path to each destination node in the network, where a neighboring node on the shortest path to reach each node is recorded. Then it computes a downstream loop-free alternate (LFA) node for a destination node, where the LFA node is downstream of the computing node but not on the selected shortest path to the destination node from the computing node. Then when connectivity to the neighboring node on the computed shortest path is detected to be abnormal, the node forwards an Ethernet frame with a destination media access control (MAC) address corresponding to the destination node through the LFA node.

Abstract: Systems and methods according to these exemplary embodiments provide for methods and systems for interworking between an Internet Group Management Protocol (IGMP) and a MAC address Multiple Registration Protocol (MMRP). For example, an IGMP join or leave message which is received at node is translated into an equivalent MMRP message for forwarding into an MMRP portion of a network.

Abstract: A method is disclosed to forward Ethernet frames associated with a service instance at a node (a “forwarding node”) in a network supporting an implementation of a protocol for creating logical loop-free topologies. The method starts with receiving a number of MMRPDUs at the forwarding node from links in the first network (receiving links), where each MMRPDU of the first plurality of MMRPDUs contains a first interested node list including one or more interested nodes identified by MAC addresses. Then a service instance identifier (SID) is identified for the service instance and a first set of MAC addresses interested in the service instance is formed. Then a number of MMRPDUs are sent to links associated with the service instance, where each MMRPDU contains a second set of MAC addresses interested in the service instance. The sending may be accompanied by the node installing filtering at the forwarding node accordingly.

Abstract: A method supporting a distributed resilient network interconnect (DRNI) in a link aggregation group at a network device is disclosed. The method starts with receiving a distributed relay control protocol data unit (DRCPDU), where the DRCPDU includes neighbor network device's state information and configuration information, wherein the configuration information includes its operational aggregation key, gateway digest, port digest. The method continue with determine whether or not the received configuration information is different from the one of the network device and how, and causing the next DRCPDU to be transmitted to the neighbor network device to include or not include certain information accordingly.

Abstract: A method and Provider Edge Bridge for providing a Virtual C-tagged User Network Interface (VUNI) service interface or a Hairpin Switching service interface. In one embodiment, the Provider Edge Bridge includes a Customer Virtual Local Area Network (C-VLAN) component; a first Service VLAN (S-VLAN) component connected to the C-VLAN component and to a Metro Ethernet Network (MEN); and a second S-VLAN component connected to the C-VLAN component, to the first S-VLAN component, and to an External Network Network Interface (E-NNI). In another embodiment, the Provider Edge Bridge includes the C-VLAN component and a single S-VLAN component connected to the C-VLAN component, to the MEN, and to the E-NNI. In both embodiments, the Provider Edge Bridge is configured to provide the VUNI service interface or the Hairpin Switching service interface without utilizing a S-VLAN mapping component.

Abstract: A method and Provider Backbone Bridge (PBB) for handling customer multicast frames that are received by a Customer Network Port or Provider Network Port on an I-component of the PBB. Customer multicast frames that are forwarded to a Virtual Instance Port (VIP) on the I-component are encapsulated with a Backbone Destination Address (B-DA) equal to the original Customer Destination Address (C-DA) of the received customer multicast frames instead of the Default B-DA. This capability may be controlled by an “EnableCustomerMulticast” parameter enabling the above behavior to be independently set for each VIP on the I-component.

Abstract: Methods and apparatus are disclosed for applying multiple Link Aggregation Group (LAG) entities on the same set of physical links, thus making bundling of individual services or conversations possible by the different LAG entities within Link Aggregation. Each LAG entity is configured such that a single physical link is Active and all the other links are Standby. Each LAG entity may be regarded as a “bundle.” Thus the services/conversations are bundled into a LAG entity and are handed-off on the Active link during normal operation. If service hand-off is not possible on the Active link (e.g., due to a failure), then the LAG entity switches over to a Standby link thus the service/conversation is handed-off on that formerly Standby link. Bundling may simplify operations of control and signaling.

Abstract: A method forward Ethernet frames at a node in a network supporting an implementation of shortest path bridging (SPB) protocol is disclosed. The method starts with a shortest path computation for the node (referred to as the computing node). The shortest path computation selects at least a shortest path to each destination node in the network, where a neighboring node on the shortest path to reach each node is recorded. Then it computes a downstream loop-free alternate (LFA) node for a destination node, where the LFA node is downstream of the computing node but not on the selected shortest path to the destination node from the computing node. Then when connectivity to the neighboring node on the computed shortest path is detected to be abnormal, the node forwards an Ethernet frame with a destination media access control (MAC) address corresponding to the destination node through the LFA node.

Abstract: A network interconnect node of an internal network may communicate with an external network interconnect node of an external network, other internal network interconnect node(s) and internal network node(s). The network interconnect node may receive frames from the external network interconnect node and forward them according to a Virtual Local Area Network (VLAN) tagging forwarding process to other internal network interconnect node(s) or internal network node(s) based on whether the network interconnect node is active for the service associated with the frames. The network interconnect node may receive frames from other internal network interconnect node(s) or from internal network nodes and forward them according to the VLAN tagging forwarding process to other internal network interconnect nodes, internal network nodes or the external network interconnect node based on whether the frames are encapsulated frames and/or whether the network interconnect node is active for the service.

Abstract: A method and Bridge in a Provider Backbone Bridge Network, PBBN, for enabling frames from a Higher Layer Entity attached alternatively to a Provider Instance Port on an I-Component of a Backbone Edge Bridge or to a Customer Backbone Port on a B-Component of the Backbone Edge Bridge, to reach an intended entity in the PBBN. A Virtual Instance Port Service Access Point, VIP SAP, is configured for every VIP and every Higher Layer Entity configured on the I-Component. An Enhanced VIP Port Connectivity function utilizes the VIP SAP to tunnel customer-initiated Layer 2 Control Protocols, L2CPs. A Special Multiplexed SAP handles the frames of the Higher Layer Entity, and is assigned an I-SID value that is universally recognized to identify the L2CPs. A Service Instance Multiplex Entity utilizes the Special Multiplexed SAP to transfer frames between the Provider Instance Port or the Customer Backbone Port and the entity inside the PBBN.

Abstract: A method and Provider Edge Bridge for providing a C-tagged service interface or a port-based interface. In one embodiment, the Provider Edge Bridge includes a Customer Virtual Local Area Network (C-VLAN) component having a Customer Edge Port (CEP) and a plurality of Provider Edge Ports (PEPs). A first Service VLAN (S-VLAN) component is connected to the C-VLAN component and to a Metro Ethernet Network (MEN). A second S-VLAN component is connected to the C-VLAN component, to the first S-VLAN component, and to an External Network Network Interface (E-NNI). A plurality of ports on the first S-VLAN component facing the MEN are designated as S-VLAN Remote Customer Ports (RCPs) when the ports are connecting internal services in the MEN to provide the C-tagged service interface or the port-based interface to customers from a far side of the E-NNI.

Abstract: The present invention relates to methods and devices for monitoring a data path extending from an originating node to a terminating node in a network. In a first aspect of the present invention, the method comprises the step of submitting, to the originating node, a request to monitor at least one network status parameter associated with a particular data flow transported on the data path. Further, the method comprises the step of submitting, to all nodes in the data path, a data flow identifier indicating the particular data flow being one out of a plurality of data flows that can be transported on the data path. Moreover, the method comprises the step of receiving, from at least one of the nodes in the data path, a response message comprising the requested at least one network status parameter.

Abstract: A system and method for providing Connectivity Fault Management, CFM, in a Provider Backbone Bridge Traffic Engineering, PBB-TE, telecommunication network utilizing Ethernet-based packet transport. PBB-TE point-to-point and point-to-multipoint services are identified, and PBB-TE maintenance points (31, 41) associated with the identified PBB-TE services are addressed. The addressed PBB-TE maintenance points are modified by adding a PBB-TE Service Demultiplexer (32, 42) to each PBB-TE maintenance point for identifying independent PBB-TE service instances. Basic CFM protocols are enhanced to duplicate the behavior of CFM protocols on virtual local area network, VLAN, based maintenance associations. The PBB-TE maintenance points may be Maintenance association End Points, MEPs, and Maintenance association Intermediate Points, MIPs.

Abstract: A method forward Ethernet frames at a node in a network supporting an implementation of shortest path bridging (SPB) protocol is disclosed. The method starts with a shortest path computation for the node (referred to as the computing node). The shortest path computation selects at least a shortest path to each destination node in the network, where a neighboring node on the shortest path to reach each node is recorded. Then it computes a downstream loop-free alternate (LFA) node for a destination node, where the LFA node is downstream of the computing node but not on the selected shortest path to the destination node from the computing node. Then when connectivity to the neighboring node on the computed shortest path is detected to be abnormal, the node forwards an Ethernet frame with a destination media access control (MAC) address corresponding to the destination node through the LFA node.

Abstract: A network bridge configured to convey customer traffic between a customer equipment and any of an MPLS network and an Ethernet network is disclosed. The network bridge comprises a C-VLAN component, an S-VLAN component and an MPLS component. The C-VLAN component can receive an Ethernet frame that carries the customer traffic, and forward the Ethernet frame to the S-VLAN component or to the MPLS component in dependence of a C-VID value of the Ethernet frame. The MPLS component can, when the Ethernet frame is received from the C-VLAN component, add MPLS information to the Ethernet frame, and forward the Ethernet frame to the S-VLAN component. The S-VLAN component then forwards the Ethernet frame to any of the MPLS network and the Ethernet network. A related network core bridge, methods and computer-readable medium are also described.

Abstract: A method, Bridge, and system in a Provider Backbone Bridge Network (PBBN) for enabling frames from a Higher Layer Entity attached alternatively to a Provider Instance Port (PIP) on an I-Component of a Backbone Edge Bridge or to a Customer Backbone Port on a B-Component of the Backbone Edge Bridge, to reach an intended entity in the PBBN. A Multiplexed Service Access Point (SAP) of a Service Instance Multiplex Entity handles the frames of the Higher Layer Entity, and is assigned a Service Instance ID (I-SID) value that is universally recognized to identify Layer 2 Control Protocols. The Service Instance Multiplex Entity utilizes the Multiplexed SAP to transfer frames between the PIP or the Customer Backbone Port and the entity in the PBBN.

Abstract: Methods and apparatus are disclosed for monitoring a Maintenance Association (MA) for Connectivity Fault Management (CFM) in a network supporting Equal Cost Multiple Paths (ECMP). A set of ECMP paths is generated for sending data between endpoints in the network. Furthermore, a set of ECMP MAs is created that are used for monitoring the generated ECMP paths between the endpoints. The created set of ECMP MAs is subsequently used for sending monitoring packets. ECMP path MAs therefore conform to existing CFM operation and are compatible with both ECMP point to point path MAs and ECMP multipoint path MAs.

Abstract: A method is disclosed to forward Ethernet frames associated with a service instance at a node (a “forwarding node”) in a network supporting an implementation of a protocol for creating logical loop-free topologies. The method starts with receiving a number of MMRPDUs at the forwarding node from links in the first network (receiving links), where each MMRPDU of the first plurality of MMRPDUs contains a first interested node list including one or more interested nodes identified by MAC addresses. Then a service instance identifier (SID) is identified for the service instance and a first set of MAC addresses interested in the service instance is formed. Then a number of MMRPDUs are sent to links associated with the service instance, where each MMRPDU contains a second set of MAC addresses interested in the service instance. The sending may be accompanied by the node installing filtering at the forwarding node accordingly.