A network component is provided for facilitating communication of traffic between a destination server and a client over a network comprising the plurality of network paths. The network component comprising memory for storing computer-readable instructions and a processor configured to implement the computer-readable instructions. The computer-readable instructions operable to implement the following: exchange control parameters with the client via a control channel using one or more of the plurality of network control paths; encapsulate the traffic for transmission to the client; decapsulate the traffic received from the client; and schedule traffic to the client via one or more of the plurality of network paths using logic common with the client based on network parameters. A client configured to work with the network component is also described, as is a communication system including both the client and network component.

An appropriate quality of service policy is automatically selected as a function of network and business conditions. A current loading condition of an internet protocol network of devices operating, a current condition of radio frequency communications between wireless devices, and a current business condition that indicates a cost or availability of a resource used in device operation remotely controlled via data packet communications, are each determined under current network control and routing rules. If the resource cost or availability exceeds a specified market condition constraint, a special resource control rule is automatically selected to preempt a current network or routing rule to cause one or more of the internet protocol devices to reduce an amount of the resource used or distributed by the first internet protocol device while operating within the current determined internet protocol network loading and radio frequency communications conditions.

A method and an apparatus to perform multi-connection traffic analysis and management are described. In one embodiment, the method includes analyzing data packets in the first data flow of a client application for a pattern of interest, where the client application communicates data using first and second data flows. In response to the method detecting a pattern of interest in the first data flow, the method identifies the second data flow and identifies a traffic policy for the second data flow. The method applies the identified traffic policy to the second data flow. Other embodiments have been claimed and described.

An example network device includes a set of physical network interfaces and a control unit that executes a routing protocol and a traffic impact prediction module. The traffic impact prediction module determines, prior to occurrence of a topology-changing device fault, that one or more operating characteristics of the network device are indicative of a possible fault, wherein the network device is one of a plurality of network devices in a network, determines a probability of traffic loss associated with the possible fault, and determines an adjusted routing metric for routes impacted by the possible fault based at least in part on the probability of the traffic loss. The routing protocol sends, via at least one of the set of physical network interfaces, one or more interior gateway protocol update messages specifying the adjusted routing metric to at least one other network device in the network.

Provided is a method for controlling traffic of a Radio Access Network (RAN) in a wireless communication system. The method includes acquiring at least one of subscription class information of a User Equipment (UE) user and type information of an application or content; determining whether a congestion situation has occurred in the RAN; and controlling traffic for the UE based on the acquired information, if the congestion situation has occurred in the RAN.

The invention relates to a method for relocating a first function for processing data packets of a flow associated with a device, from a source to a target instance. The method is triggered by an initiated relocation of a second function for processing data packets of the flow. The method comprises initiating (710) a first phase of a relocation method for relocating the first function, before the relocation of the second function is finalized. The method also comprises determining (720) whether to initiate a second phase of the relocation method based on information related to a progress of the relocation of the second function. When it is determined (720) to initiate the second phase, the method further comprises initiating (730) the second phase of the relocation method comprising the resumption of the processing of the data packets of the flow at the target instance of the first function.

Aspects of the embodiments are directed to augmenting a control packet with an interface identifier, the interface identifier identifying an interface at a physical network forwarding element; and transmitting the control packet with the interface identifier to the physical network forwarding element. The interface identifier can be included in metadata of a network service header (NSH). The NSH is encapsulated with the control packet, which is transmitted with the control packet. The NSH can be extracted and the interface identifier used to identify a user interface (or a presenting interface) based on a metadata lookup.

Aspects of the present disclosure are directed to dynamically adjusting control plane policing throughput of low (or lower) priority control plane traffic to permit higher throughput. The drop rate for low or lower priority control plane traffic can be determined to be above a threshold value. The processor utilization can be determined to be operating under normal utilization (or at a utilization within a threshold utilization value). The control plane policing for control plane traffic for the low or lower class of service can be increased (or decreased) to permit lower class of service control traffic to be transmitted using higher class of service resources without adjusting the priority levels for the lower class of service control traffic.

A control apparatus connected to two or more first relay apparatuses which form a trunk with a first external relay apparatus and to a second relay apparatus(es) which is connected to at least one of the first relay apparatuses and which is arranged between a destination apparatus that performs a point-to-point communication and the first relay apparatuses. The control apparatus includes a first unit controlling the relay apparatuses; a second unit receiving a request for a configuration about a point-to-point communication, the request including endpoint information about the point-to-point communication; and a third unit determining, before the point-to-point communication occurs, a path(s) of the point-to-point communication, based on the endpoint information about the point-to-point communication and a packet allocation rule(s) of the first external relay apparatus, and setting a packet forwarding rule(s) for the point-to-point communication which uses the trunk in the relay apparatuses on the path(s).

A classifier network element in a service function chain system receives a classification policy and an access policy from a controller of the service function chain system. The classification policy identifies which service function path network traffic flows will traverse through the service function chain system. The access policy defines criteria for determining whether network traffic flows will be sent along a service function path of the service function chain system. The classifier network element receives an initial packet of a network traffic flow from a source endpoint directed to a destination endpoint. Responsive to a determination that the initial packet of the network traffic flow satisfies the criteria of the access policy, the classifier network element applies the access policy to the network traffic flow.