In an aspect of the disclosure, a method, a computer-readable medium, and an apparatus are provided. The apparatus receives first command or data in accordance with a first management protocol from a first device. The apparatus then translates the first command or data into second command or data in accordance with second management protocol. The apparatus further sends the second command or data to a second device. One of the first device and the second device is a first managed element managing a first host.

A disclosed apparatus may include (1) a wireless receiver that facilitates communicatively coupling to a wireless transmitter of an access point connected to a network switch of a service provider, and (2) at least one processing device of a router communicatively coupled to the wireless receiver, wherein the processing device of the router (A) activates a wireless mode that (I) causes the router to establish a wireless connection with the access point via the wireless transmitter and the wireless receiver and (II) facilitates remote configuration of the router by a remote user who has gained access to the router via the wireless connection, (B) receives, via the wireless connection, at least one command from the remote user, and (C) applies, to an out-of-band management interface of the router, the command received from the remote user via the wireless connection. Various other apparatuses, systems, and methods are also disclosed.

A monitoring device responds to status data pushed from a network device, and also manages a link with another network device, the link allowing the monitoring device to pull status data from the second network device. The monitoring device receives packets including status, the data indicating activity for one or more clock ticks. The monitoring device can compute statistical measures, rather than the network device. The monitoring device maintains the status data in a buffer. The monitoring device lags actual activity, but has is more likely to capture delayed packets. The network device sends packets as wrappers, each wrapper indicating sets of status information. When the information in a wrapper crosses a clock tick boundary, the monitoring device allocates reported activity among clock ticks, assuming that activity follows a uniform distribution.

Disclosed are various examples for managing endpoints or client devices. A client device can be managed using unified endpoint management (UEM) protocols or using an endpoint management framework. A management console can allow an administrator to perform UEM management actions as well as out-of-band management actions on managed endpoints.

The present disclosure is to propose a method and device for improving a link aggregation protocol timeout. method for improving a link aggregation timeout. The method includes the following steps: setting a timeout value and a timeout threshold count of link aggregation control protocol data unit (LACPDU) packet reception of a switch; obtaining a timeout count statistically, in response to a timeout of reception of a link aggregation control protocol data unit (LACPDU) packet from a second switch by a first switch; determining, through a network controller, in response to that the timeout count is greater than the timeout threshold count and that an aggregated link between the switches is in an out-of-band management mode, whether a port of the second switch is abnormal; and removing, in response to the port of the second switch being abnormal, the abnormal port of the second switch from the aggregated link.

A method and apparatus for remotely configuring Ethernet protocol functionality in a terminal device connected to a cellular communications network. One aspect provides a network node comprising a communications interface for communicating with the cellular communications network, a radio interface for communicating with a terminal device, and one or more processors. The network node is configured to receive, from the cellular communications network, a request to send an Ethernet configuration message to a terminal device connected to the cellular communications network, transmit the Ethernet configuration message to the terminal device and receive a response message from the terminal device.

A first component of a process control loop (e.g., a controller or I/O gateway) monitors for and detects performance degradation of a second component of the loop by sending heartbeat messages to the second component via a diagnostic channel different from a control communications channel via which the first and second components communicate control messages for controlling an industrial process. The second component utilizes its control message interpreter to return received heartbeat messages to the first component via the diagnostic channel. The first component detects degradation of the second component when the round trip time (RTT) of a heartbeat message falls outside of an acceptable range of RTTs for the second component, and may suggest or automatically initiate mitigating actions. The first component may determine the average RTT or expected response time of the second component and acceptable range of variations based on a sample number of measured RTTs.

A method supporting distributed resilient network interconnect (DRNI) in a link aggregation group at a network device is disclosed. The method starts with encapsulating a distributed relay control protocol data unit (DRCPDU) in a frame, wherein the DRCPDU includes a protocol data unit (PDU) structure. The PDU structure includes a type field indicating that the DRCPDU is for DRCP, a version field indicating a version number of the DRCP, and a set of type/length/values (TLVs) including: a terminator TLV indicating an end of the PDU structure, a portal information TLV indicating characteristics of the first portal, a portal configuration information TLV indicating configuration information of the first portal, a DRCP state TLV indicating variables associated with an intra-portal link (IPP), a home ports information TLV and a neighbor ports information TLV. The method continues with transmitting the frame encapsulating the DRCPDU from the network device to a neighbor network device.

A method for facilitating allocation of network resources to at least one slice in a communication network includes obtaining information identifying a mapping between network resource allocations and a respective quality of experience (QoE) associated with a user and obtaining information relating to a quality of service (QoS) tolerance for a particular QoE. The method includes providing to a controller for allocating at least a portion of the network resources to the at least one slice: i) the information identifying a mapping between network resource allocations and a QoE; ii) the information relating to the QoS tolerance; and iii) information identifying a current QoE and a target QoE associated with at least one user.

A method for facilitating allocation of network resources to at least one slice in a communication network includes obtaining information identifying a mapping between network resource allocations and a respective quality of experience (QoE) associated with a user and obtaining information relating to a quality of service (QoS) tolerance for a particular QoE. The method includes providing to a controller for allocating at least a portion of the network resources to the at least one slice: i) the information identifying a mapping between network resource allocations and a QoE; ii) the information relating to the QoS tolerance; and iii) information identifying a current QoE and a target QoE associated with at least one user.