A method and apparatus for routing packets from a home agent to a user equipment through a first access network and a second access network. The method includes sending a first binding update message from the user equipment over the first access network to create a first binding cache entry at the home agent. The user equipment uses a home address assigned to the user equipment as a source IP address of the first binding update message. The method further includes sending a second binding update message from the user equipment over the second access network to create a second binding cache entry at the home agent. The user equipment receives packets from the home agent through the first access network and the second access network based on the first binding cache entry and the second binding cache entry.

A parallel computer includes a plurality of nodes. Each of the nodes includes a router directly or indirectly connected to each of the other nodes and a network interface connected to an external network of the parallel computer. The network interface includes a storage unit that holds detour route information indicating a detour route corresponding to a communication route from a node in which the network interface is included to another node. The network interface further includes a reception processing unit that, when the network interface receives data destined to one node of the parallel computer from the external network, sets detour route information corresponding to a communication route from the node in which the network interface is included to the destination node of the data for the data and transmits the data for which the detour route information is set to the destination node.

The invention relates to methods, IMS system, and nodes such as P-CSCF, I-CSCF and S-CSCF for bypassing a network node, such as the HSS, during a reregistration procedure. Communication links are monitored and if a probability of success of a new request to the network node is within a range, then the network node can be bypassed.

Exemplary methods include a first network device participating in an election process to determine a designated bit forwarding router (D-BFR). The methods include in response to determining the first network device is elected to be the D-BFR, performing D-BFR operations comprising determining an elected bitmask (BM) length of a BM based on maximum local BM lengths advertised by other BFRs in the network, wherein each bit of the BM will correspond to a bit forwarding egress router (BFER), and advertising the determined elected BM length to other BFRs. The methods may further include one or more of determining an elected tree type based on supported tree types advertised by other BFRs in the network, assigning one or more BM positions (BMPs) to one or more BFERs, and advertising the elected determined tree type and/or the assigned one or more BMPs.

Systems and methods that efficiently combine multiple wireless networks or devices resulting in faster, more reliable, and more secure mobile Internet. A Virtual Private Network (VPN) service application is operated to route outgoing and incoming data packets of a mobile device. The mobile device is (i) either coupled to a remote server through the VPN service application for data packets transfer between the remote server and the mobile device or (ii) performs cross-layer translation for data packets transfer between the mobile device and direct target hosts on the Internet. Concurrently using multiple channels secures data packets transfer by sending encrypted data packets over multiple channels and receiving the encrypted data packets by a single apparatus. Data packets are designated to be transferred via a Wi-Fi channel or a cellular channel, and then transferred using both the Wi-Fi channel and the cellular channel.

Concepts and technologies disclosed herein are directed to intelligent signaling routing for machine to machine (“M2M”) communications, such as communications for Internet of things (“IoT”) devices. According to one aspect of the concepts and technologies disclosed herein, a mobility management entity (“MME”) can receive an attach request or a tracking area update (“TAU”) from a device to establish a connection to a network. The MME can extract device identification information from the attach request. The device identification information can identify the device as either a UE or IoT device. The MME can determine an appropriate DIAMETER routing agent (“DRA”) of a plurality of DRAs to which to route signaling traffic associated with the device. The plurality of DRAs can include DRA and an IoT application-specific DRA. The MME can route the signaling traffic to the appropriate DRA of the plurality of DRAs.

A method for communication includes, in a first network switch that is part of a communication network having a topology, detecting a compromised ability to forward a flow of packets originating from a source endpoint to a destination endpoint. In response to detecting the compromised ability, the first network switch identifies, based on the topology, a second network switch that lies on a current route of the flow, and also lies on one or more alternative routes from the source endpoint to the destination endpoint that do not traverse the first network switch. A notification, which is addressed individually to the second network switch and requests the second network switch to reroute the flow, is sent from the first network switch.

Various embodiments implement a set of low overhead mechanisms to enable on-demand routing protocols. The on-demand protocols use route accumulation during discovery floods to discover when better paths have become available even if the paths that the protocols are currently using are not broken. In other words, the mechanisms (or “Route Optimizations”) enable improvements to routes even while functioning routes are available. The Route Optimization mechanisms enable nodes in the network that passively learn routing information to notify nodes that need to know of changes in the routing information when the changes are important. Learning routing information on up-to-date paths and determining nodes that would benefit from the information is performed, in some embodiments, without any explicit control packet exchange. One of the Route Optimization mechanisms includes communicating information describing an improved route from a node where the improved route diverges from a less nearly optimal route.

An information handling system is provided. The information handling system includes a plurality of aggregation devices configured to distribute information in a virtual link trunk and a plurality of nodes coupled to the aggregation devices. When one of the plurality of aggregation devices received a reboot command, that aggregation device is configured to transmit a first message to the nodes indicating that the aggregation device is rebooting, receive a first acknowledgement message from the nodes indicating that they will not send any information to the rebooting aggregation device. The aggregation device is then configured to reboot, receive a second message from the nodes indicating the nodes are ready to receive information from the rebooted aggregation device, transmit a second acknowledgement message to the nodes indicating that the rebooted aggregation device has rebooted and is capable of receiving information, and receive information from at least one of the nodes for transmission to at least one other node.

A uniform resource locator (URL) mapping and routing system and method for generating, routing, and managing URLs is used to route internet users to application landing pages or websites based on a URL mapping scheme. Routing instructions for the URL may route a user accessing a URL to a destination landing page or an alternate landing page depending on routing instructions in the URL mapping scheme.