Patent application number | Description | Published |
20080253367 | Method for Establishing Multi Segment Pseudowire Across Domains Having Different Pseudowire Signaling Protocol - A method of establishing a multi-segment pseudowire across domains executing different pseudowire signaling protocols augments the Label Distribution Protocol (LDP) label message to include a MS-PW TLV. The MS-PW TLV carries pseudowire signal 22 FEC TLV protocol information associated with signaling protocols of other segments of the MS-PW. As a result a multi-segment pseudowire can be extended between domains that execute different pseudowire signaling protocols. | 10-16-2008 |
20080298379 | FULL MESH STATUS MONITOR - A method for verifying full mesh status in a network is disclosed. The network includes endpoint entities in full mesh configuration. The method includes a step of maintaining a first value in the endpoint entities. The first value is related to counting of network endpoint entities. Another step in the method is maintaining a second value in the endpoint entities. The second value is related to counting non-operational transmission paths before a point in time. An additional step in the method is discovering an additional value related to counting non-operational transmission paths after the point in time. Yet another step in the method is comparing the additional value with the first value and the second value. | 12-04-2008 |
20090041023 | Method and Apparatus for Interworking VPLS and Ethernet Networks - To allow seamless interworking between an 802.1ah service instance (ISID) and a VPLS service instance, the AGI value used to signal the setup of the pseudowire portion of the VPLS may carry the ISID value of an associated 802.1ah service instance. This allows the service instance to be identified end-to-end across the Ethernet and VPLS networks using the same value without modifying how the MPLS network operates. The VPLS network will use AGI/AII signaling to set up pseudowires on the MPLS network, but instead of using an AGI value assigned by the MPLS network, the AGI value that is assigned will be taken from the ISID value of the Ethernet frame or from ISIDs registered by the Ethernet network. The AGI message may be given a new type value indicating that the AGI message carries a value that corresponds to the ISID value on an attached Ethernet network. Alternatively, an existing AGI message type may be used to carry the ISID value, and a second type field may be used to indicate that the AGI contains an ISID value. | 02-12-2009 |
20100226376 | Method and Apparatus for Transporting Ethernet Services - Frames of customer traffic may be encapsulated by adding Mac-in-Mac (MiM) encapsulation fields for transportation of the frames over a portion of provider network. The MiM encapsulated traffic may be further encapsulated using VPLS by adding VPLS encapsulation fields for transportation of the frames over another portion of the provider network. The MiM encapsulations use provider network MAC addresses which enables VPLS MAC learning to occur using provider network MAC address space. MiM tunnels are mapped to VPLS service instances which are assigned pseudowire tags for transportation over the VPLS portion of provider network. The MiM header is retained when the MiM encapsulated frames are transported over the VPLS portion of the provider network. As VPLS frames exit the core network, the VPLS encapsulation fields are removed to extract the original MiM encapsulated frames for further transportation over the MiM portion of the provider network. | 09-09-2010 |
20120008630 | Border Gateway Protocol Extended Community Attribute for Layer-2 and Layer-3 Virtual Private Networks - Described are a network, computer program product, and method of distributing routing information for a virtual private network (VPN) application through a packet-switched network (PSN) having fully meshed provider edge (PE) routers through Provider Backbone Bridge (PBB) tunnels. A PE router is configured to participate in a VPN and to run a BGP (Border Gateway Protocol) as an auto-discovery process for finding one or more other PE routers participating in the VPN. The VPN is associated with a PBB tunnel. A service instance identifier (I-SID) is assigned to the VPN. The PE router advertises membership in the VPN by including the I-SID assigned to the VPN in a BGP message issued during the auto-discovery process. | 01-12-2012 |
20120044939 | Method and Apparatus for Transporting Ethernet Services - Frames of customer traffic may be encapsulated by adding Mac-in-Mac (MiM) encapsulation fields for transportation of the frames over a portion of provider network. The MiM encapsulated traffic may be further encapsulated using VPLS by adding VPLS encapsulation fields for transportation of the frames over another portion of the provider network. The MiM encapsulations use provider network MAC addresses which enables VPLS MAC learning to occur using provider network MAC address space. MiM tunnels are mapped to VPLS service instances which are assigned pseudowire tags for transportation over the VPLS portion of provider network. The MiM header is retained when the MiM encapsulated frames are transported over the VPLS portion of the provider network. As VPLS frames exit the core network, the VPLS encapsulation fields are removed to extract the original MiM encapsulated frames for further transportation over the MiM portion of the provider network. | 02-23-2012 |
20120120957 | Border Gateway Protocol Procedures for Multi-Protocol Label Switching and Layer-2 Virtual Private Networks Using Ethernet-Based Tunnels - Described is a method of operating a first provider edge (PE) router to support virtual private network (VPN) applications through a packet-switched network (PSN). Routing information is obtained for a VPN route to be routed through an Ethernet switched path between the first PE router and a second PE router. The first PE router is at a source end of the Ethernet switched path and the second PE router is at a destination end of the Ethernet switched path. The VPN route is associated with the Ethernet switched path. A Border Gateway Protocol (BGP) message is sent from the first PE router to the second PE router, the BGP message containing routing information for the VPN route. | 05-17-2012 |
20120207171 | Method and Apparatus for Interworking VPLS and Ethernet Networks - To allow seamless interworking between an 802.1ah service instance (ISID) and a VPLS service instance, the AGI value used to signal the setup of the pseudowire portion of the VPLS may carry the ISID value of an associated 802.1ah service instance. This allows the service instance to be identified end-to-end across the Ethernet and VPLS networks using the same value without modifying how the MPLS network operates. The VPLS network will use AGI/AII signaling to set up pseudowires on the MPLS network, but instead of using an AGI value assigned by the MPLS network, the AGI value that is assigned will be taken from the ISID value of the Ethernet frame or from ISIDs registered by the Ethernet network. | 08-16-2012 |
20120226821 | APPARATUS AND METHOD FOR LAYER-2 AND LAYER-3 VPN DISCOVERY - An apparatus and a method for layer-2 and layer-3 VPN discovery are disclosed. The apparatus is incorporated in a network, and the network includes a first carrier network. The first carrier network includes at least two layer-1 provider edge devices. Layer-1 VPN information is created within the first carrier network. BGP next hop information passes within the first carrier network. The BGP next hop information is for a selected one of the following: a layer-2 VPN-based provider edge device, a layer-3 VPN-based provider edge device, and a layer-2 and layer-3 VPN-based provider edge device. The network also includes a second carrier network within which the BGP next hop information is used for VPN discovery. | 09-06-2012 |
20120307683 | LAYER-2 TO MPLS SERVICE MEDIATION ARCHITECTURE - An architecture for providing service mediation in a network having a Layer-2 domain and an MPLS domain includes at least one Layer-2 provider edge device in communication with a first customer site; at least one Layer-2 edge device in communication with the Layer-2 provider edge device; at least one MPLS mediation edge device in communication with the Layer-2 edge device; and at least one MPLS provider edge device in communication with both the MPLS mediation edge device and a second customer site. An end-to-end connection is established using native Layer-2 signaling, if any, in the Layer-2 domain and PWE3 signaling protocols in the MPLS domain. The MPLS mediation edge device resolves associations between Layer-2 edge devices and MPLS provider edge devices. The service is “mediated” in the sense that native Layer-2 signaling is terminated at the MME, and a new domain, i.e., pseudowire, is established across the MPLS domain. | 12-06-2012 |
20130272308 | Method and Apparatus for Transporting Ethernet Services - Frames of customer traffic may be encapsulated by adding Mac-in-Mac (MiM) encapsulation fields for transportation of the frames over a portion of provider network. The MiM encapsulated traffic may be further encapsulated using VPLS by adding VPLS encapsulation fields for transportation of the frames over another portion of the provider network. The MiM encapsulations use provider network_MAC addresses which enables VPLS MAC learning to occur using provider network MAC address space. MiM tunnels are mapped to VPLS service instances which are assigned pseudowire tags for transportation over the VPLS portion of provider network. The MiM header is retained when the MiM encapsulated frames are transported over the VPLS portion of the provider network. As VPLS frames exit the core network, the VPLS encapsulation fields are removed to extract the original MiM encapsulated frames for further transportation over the MiM portion of the provider network. | 10-17-2013 |
20140023078 | Method and Apparatus for Transporting Ethernet Services - Frames of customer traffic may be encapsulated by adding Mac-in-Mac (MiM) encapsulation fields for transportation of the frames over a portion of provider network. The MiM encapsulated traffic may be further encapsulated using VPLS by adding VPLS encapsulation fields for transportation of the frames over another portion of the provider network. The MiM encapsulations use provider network_MAC addresses which enables VPLS MAC learning to occur using provider network MAC address space. MiM tunnels are mapped to VPLS service instances which are assigned pseudowire tags for transportation over the VPLS portion of provider network. The MiM header is retained when the MiM encapsulated frames are transported over the VPLS portion of the provider network. As VPLS frames exit the core network, the VPLS encapsulation fields are removed to extract the original MiM encapsulated frames for further transportation over the MiM portion of the provider network. | 01-23-2014 |
20140023081 | Method and Apparatus for Transporting Ethernet Services - Frames of customer traffic may be encapsulated by adding Mac-in-Mac (MiM) encapsulation fields for transportation of the frames over a portion of provider network. The MiM encapsulated traffic may be further encapsulated using VPLS by adding VPLS encapsulation fields for transportation of the frames over another portion of the provider network. The MiM encapsulations use provider network_MAC addresses which enables VPLS MAC learning to occur using provider network MAC address space. MiM tunnels are mapped to VPLS service instances which are assigned pseudowire tags for transportation over the VPLS portion of provider network. The MiM header is retained when the MiM encapsulated frames are transported over the VPLS portion of the provider network. As VPLS frames exit the core network, the VPLS encapsulation fields are removed to extract the original MiM encapsulated frames for further transportation over the MiM portion of the provider network. | 01-23-2014 |
20140079069 | LAYER-2 TO MPLS SERVICE MEDIATION ARCHITECTURE - An architecture for providing service mediation in a network having a Layer-2 domain and an MPLS domain includes at least one Layer-2 provider edge device in communication with a first customer site; at least one Layer-2 edge device in communication with the Layer-2 provider edge device; at least one MPLS mediation edge device in communication with the Layer-2 edge device; and at least one MPLS provider edge device in communication with both the MPLS mediation edge device and a second customer site. An end-to-end connection is established using native Layer-2 signaling, if any, in the Layer-2 domain and PWE3 signaling protocols in the MPLS domain. The MPLS mediation edge device resolves associations between Layer-2 edge devices and MPLS provider edge devices. The service is “mediated” in the sense that native Layer-2 signaling is terminated at the MME, and a new domain, i.e., pseudowire, is established across the MPLS domain. | 03-20-2014 |
20140153578 | Border Gateway Protocol Extended Community Attribute for Layer-2 and Layer-3 Virtual Private Networks - Described are a network, computer program product, and method of distributing routing information for a virtual private network (VPN) application through a packet-switched network (PSN) having fully meshed provider edge (PE) routers through Provider Backbone Bridge (PBB) tunnels. A PE router is configured to participate in a VPN and to run a BGP (Border Gateway Protocol) as an auto-discovery process for finding one or more other PE routers participating in the VPN. The VPN is associated with a PBB tunnel. A service instance identifier (I-SID) is assigned to the VPN. The PE router advertises membership in the VPN by including the I-SID assigned to the VPN in a BGP message issued during the auto-discovery process. | 06-05-2014 |
20140369692 | TECHNIQUE FOR IMPLEMENTING AN OPTICAL/TDM VIRTUAL PRIVATE NETWORK - A technique for implementing an optical virtual private network is disclosed. In one particular exemplary embodiment, the technique may be realized by a method comprising the steps of managing at least one client edge-virtual private network at a client edge by a service provider; and supporting a set of client edge-users at each client edge-virtual private network at each client edge wherein each client edge provides at least one virtual private network service to each client edge-user; wherein each client edge determines connectivity associated with each client edge-user and the service provider establishes the connectivity determined by each client edge. | 12-18-2014 |