According to an embodiment of the present invention, an automated computer implemented method and system for network analysis for endpoint deployment comprises determining whether a Quality of Service (QoS) analysis based on a QoS allocation data meets a first predetermined threshold for the location; if the QoS analysis does not meet the first predetermined threshold, calculating a minimum required bandwidth and increasing link capacity to at least the minimum required bandwidth or modifying an operation mode; determining whether a bandwidth analysis meets a second predetermined threshold for the location; if the bandwidth analysis does not meet the second predetermined threshold, calculating a minimum required bandwidth and increasing link capacity to at least the minimum required bandwidth; and providing analysis results to a user interface.

Some of examples disclosed herein relate to classifying access points (APs). Some of the example may enable automatically classifying a set of APs based on at least one AP attribute of each AP in the set of APs, determining, based on the automatic classification, that a subset of APs in the set of APs are classified into a same class; and automatically determining a recommended configuration setting for the subset of APs.

An apparatus and a method are provided by which a packet is received, a service identification in the packet is detected, it is decided based on the detected service identification whether a tunnel protocol extension header is to be generated or not, and, when the tunnel protocol extension header is to be generated, the tunnel protocol extension header is generated, the received packet is encapsulated with the generated tunnel protocol extension header and the encapsulated packet is forwarded.

Systems and techniques for processing and/or forwarding packets are described. An ingress switch can use a QoS mapping mechanism to map a first set of Quality of Service (QoS) bits in a packet received from a customer to a second set of QoS bits for use in a Transparent Interconnection of Lots of Links (TRILL) packet which encapsulates the packet. The first set of QoS bits can be different from the second set of QoS bits. The TRILL packet can be processed and/or forwarded in the network based on the second set of QoS bits. At the egress switch, the TRILL packet can be decapsulated and the original packet with the original QoS bits (or QoS bits that are different from the original QoS bits) can be forwarded to the customer's network. In this manner, some embodiments of the present invention can preserve the QoS bits across a TRILL network.

A method is provided for regulating a Quality of Service in a local area network, including the following: a Quality of Service regulator receives at a gateway of the local area network, from at least one Quality of Service checker, a status report concerning a distributed application; the Quality of Service regulator establishes, based on the status report, traffic engineering rules pertaining to the gateway; and the Quality of Service regulator transmits the traffic engineering rules to a Quality of Service controller. A corresponding device, a corresponding computer program and a corresponding storage medium are also provided.

A device, such as a terminal device, for example, has an operating system (OS) and an application program that executes on the OS. When executing on the device, the application program configures the device to communicate packet data with a server device, and to handle service-specific traffic, and application-specific traffic, in accordance with a distributed port mapping policy.

Packet network node and method of operating packet network node. Conventional packet network nodes react to congestion in packet network by dropping packets in a manner which is perceived by users to be indiscriminate. In the described system, indiscriminate packet discards are prevented by causing packets to be discarded on lower priority flows and flow aggregates. Further action is taken to reduce the likelihood of packet discards through: (1) classification of flows that are not observable at the point in the network where flow-based packet discards are deployed, but are consuming bandwidth and signaling classification information to flow-based packet discard function or a flow-based monitoring function or network management function; (2) classification of flows making use of extended monitoring functions that are not co-located with a flow-based packet discard function, where extended monitoring functions may perform monitoring of a flow or a group of flows over a period of time.

An example method may include receiving, by a computing device, control plane signaling associated with a first service to be performed by a first communication device, wherein the computing device is within a radio access network (RAN) and is in limited communication with a core network via a backhaul connection that is constrained due to a backhaul bottleneck condition. The example method may include conditionally permitting, by the computing device, a first feature of the first service based at least in part on the backhaul bottleneck condition. Another example method may include receiving, by a computing device, control plane signaling associated with a service to be performed by a first communication device, wherein the computing device is within a RAN and is in limited communication with a core network via a backhaul connection that is constrained due to a backhaul bottleneck condition.

Embodiments provide a method for transmitting a service stream in a flexible Ethernet and an apparatus. The method includes: obtaining a to-be-transmitted service stream, where the service stream is to be transmitted by using a target virtual connection supported by a physical connection group between a transmit end and a receive end, the physical connection group includes multiple physical connections and supports at least one virtual connection, and the target virtual connection is any one of the at least one virtual connection; determining, from total bandwidth resources of the multiple physical connections and according to timeslot configuration tables used by the multiple physical connections, a timeslot bandwidth resource that belongs to the target virtual connection; and transmitting the service stream to the receive end by using the timeslot bandwidth resource that belongs to the target virtual connection.

Methods and systems for providing IP services in an integrated fashion are provided. According to one embodiment, a flow cache is established having multiple entries each identifying one of multiple VR flows through a VR-based network device and corresponding forwarding state information. A packet is received at an input port of a line interface module of the network device and forwarded to a VRE. Flow-based packet classification is performed by the VRE. An attempt is made to retrieve an entry of the flow cache based on a result of the flow-based packet classification. On a flow cache hit, one or more appropriate packet transformations are identified for application to the packet and it is determined whether to process the packet with a VSE based on the corresponding forwarding state information. On a flow cache miss, the new VR flow is added to the flow cache by performing flow learning.