Disclosed herein are methods and calculators for configuring traffic allocations for service classes with different Quality of Service (QoS) in a router. Example embodiments involve setting allocations at a router based on traffic rate values and/or traffic weight values provided by a user. The router may monitor actual traffic rates to ensure that traffic is not being dropped due to improper rate allocations and to provide historical data for optimizing traffic allocations. In addition, the router may automatically adjust traffic allocations to avoid dropping high(er) priority traffic. The router may also transmit alarms to the user and/or to other network devices to prompt traffic re-routing and/or re-allocation of traffic rates. Example methods and apparatus ensure appropriate traffic allocation to meet certain QoS metrics.

Implementations of discovery functionalities in accordance with the present invention are characterized by being exceptionally minimalistic. A primary reason and benefit for such minimalistic implementations relate to these discovery functionalities being implemented via a management processor and associated resources of a system on a chip (SoC) unit as opposed to them being implemented on data processing components of a cluster of nodes (i.e., central processing core components). By focusing on such a minimalist implementation, embodiments of the present invention allow discovery functionalities to be implemented on a relatively low-cost low-power management processor coupled to processing cores that provide for data serving functionality in the cluster of nodes.

Embodiments of the present disclosure include methods and apparatuses for enabling data path selection. In an EPG, ILNP mobility signaling is received. The ILNP signaling may include a destination locator for a BNG. A signaling message is sent to the BNG in response to the received ILNP signaling. An acknowledgement is received from the BNG. Traffic is tunneled between a mobile device and a RGW over a LTE interface. In a BNG, a signaling message is received. A message is sent to a SDN controller. A notification is received from the SDN controller that configuration of a RGW to tunnel traffic over a LTE interface is complete. An acknowledgement is sent to an EPG. In a RGW, a message is received from a SDN controller. Traffic is tunneled between a NAS and an EPG over a LTE interface based on the message received from the SDN controller.

The invention relates to a method for generating a load sharing vector indicating a plurality of communication targets for load sharing in a communication network. The method comprises providing a target distribution vector comprising a first number of entries indicating a first communication target, and comprising a second number of entries indicating a second communication target, and generating the load sharing vector upon the basis of active entries of the target distribution vector, the active entries indicating the communication target of the first or the second communication target which is available for load sharing in the communication network.

A hybrid routing—application network fabric apparatus is presented where a fabric apparatus has multiple apparatus components or resources that can be dedicated to one or more application topologies. The apparatus can receive a topology image definition file describing an application topology and the apparatus can dedicate its local components for use with the application topology. The apparatus can dedicate general purpose processing cores, dedicated routing cores, data channels, networking ports, memory or other local resources to the application topology. Contemplated application topologies include routing topologies, computation topologies, database topologies, storage topologies, or other types of application topologies. Furthermore, application topologies can be optimized by modeling or simulating the topologies on a network fabric.

A method and system are described that allow a device operating in coordination with other devices to synchronize the devices operation with the other devices. A controllable device processor may determine that a received data packet is a retransmission of an initial control command data packet. The processor may obtain from the retransmitted data packet a start value and a time indicator related to performance of the operation. A ramp rate related to the operation to be performed may be obtained. Using the time indicator, an adjusted ramp rate may be calculated. An output value for the device may be set based on the start value, the adjusted ramp rate, and the time indicator. The adjusted ramp rate may result in completing the operation at substantially the same time as though the device received the original command.

Methods and systems for finding a packet's routing path in a network includes intercepting control messages sent by a controller to one or more switches in a software defined network (SDN). A state of the SDN at a requested time is emulated and one or more possible routing paths through the emulated SDN is identified by replaying the intercepted control messages to one or more emulated switches in the emulated SDN. The one or more possible routing paths correspond to a requested packet injected into the SDN at the requested time.

Methods for enabling monitoring a network with a monitoring tool are disclosed. The method includes receiving data packets and adding metadata to the data packets, thereby forming metadata-enhanced data packets. The method also includes forwarding the metadata-enhanced data packets along a path toward the monitoring tool, wherein the metadata pertains to data employed by the monitoring tool to perform network monitoring tasks. Arrangements for performing the same are also disclosed.

A method and a first device (110) of a switched network (100), for managing data frames received, at a first port, from a second device (120) are disclosed. The first device (110) handles the first port and a second port for transfer of data frames between the first and second devices (110, 120). The first device (110) is addressable by a Media Access Control address, “MAC address”, associated with the first port. The first device (110) receives (201), from the second device (120), at least one data frame at the second port. The first device (110) sends (202), on the first port, a message including the MAC address associated with the first port.

A communication system for an organization having multiple sites uses a dual-mode device capable of both cell phone communication and telephone communication on a local area network (LAN). IP LANS are established at organization sites such that a temporary IP address is assigned to a dual-mode device that logs onto an organization LAN, and the IP address is associated at a PSTN-connected server on the LAN with the cell phone number of the communication device. The IP server notifies a PSTN-connected routing server when a device logs on to a LAN, and also provides a destination number for the IP server. Cell calls directed to the device are then redirected to the IP server and directed to the device connected to the LAN.