In an example, a computer-readable medium may store executable instructions. The executable instructions may be to detect an inoperative network device in a communication network managed by a controller, determine a network switching function assigned to the inoperative network device, and provide the network switching function through the controller itself instead of the inoperative network device.

In one embodiment, a method according to the present disclosure includes receiving a topology change advertisement at a remote core edge node and performing a network address information removal operation. The topology change advertisement is received from a core edge node that is in communication with an access network. The topology change advertisement indicates that a topology change has occurred in the access network. The network address information removal operation removes network address information stored by the remote core edge node. The network address information is used by the remote core edge node in participating in communications with the core edge node.

An information handling system may include at least one processor; and a memory; wherein the information handling system is configured to manage a network that includes a first virtual link trunking (VLT) node, a second VLT node, and a plurality of devices that are communicatively coupled to the first VLT node via a first set of links and to the second VLT node via a second set of links, wherein the managing includes: detecting that the first VLT node has malfunctioned; detecting that the first VLT node has recovered; and after the first VLT node has recovered, preventing traffic over the first set of links until determining that all information needed to forward the traffic has been synced between the first VLT node and the second VLT node.

A self-organizing network (SON) and an operating method of the SON. An operating method of a base station in the SON includes receiving a parameter setting message including a first version identification (ID) and setting values of parameters, storing the setting values to match the first version ID, and setting parameters of the base station based on the setting values.

A method to enable defining of a profile of a service through manipulation of graphical representations of abstractions of resources in a data center is disclosed. The profile of the service is accessed. A graphical representation of an abstraction of the first resource type is presented. A graphical representation of an abstraction of a second resource type is presented. A manipulation of the graphical representation of the abstraction of the second resource type is detected with respect to the graphical representation of the abstraction of the first resource type. Based on the manipulation, a correspondence between the abstraction of the second resource type and the profile of the service is identified and a relationship between the abstraction of the second resource type and the abstraction of the first resource type is identified. The profile of the service is updated to include information identifying the correspondence and the relationship.

Implementations are described herein for provisioning a device such as a DCN with configuration data for operation on a process automation network using an “out-of-band” communication channel. In various implementations, a temporary out-of-band communication channel may be established between a first and second DCNs. The out-of-band communication channel may be distinct from a process automation network through which the first DCN is to be communicatively coupled with other process automation nodes of a process automation system. Provisioning data may be transmitted from the second DCN to the first DCN over the temporary out-of-band communication channel. The provisioning data may include: information technology (IT) configuration data and operational technology (OT) configuration data. Subsequent to the transmitting, the temporary out-of-band communication channel may be closed.

The present disclosure relates to End-to-End (E2E) Quality of Service (QoS) monitoring for strict E2E performance requirements in 5G networks including Network Slices (NSs) or Network Sub Slices (NSSs). The present disclosure provides a a control plane entity for obtaining NS Instance (NSI) data for analytics from a management plane entity, and a management plane entity to provide NSI data to a control plane entity. The control plane entity is configured to request NSI topology information from the management plane entity, obtain at least one first set of Key Performance Indicators (KPIs) or at least one set of measurements, and generate the data for analytics based on the requested NSI topology information and at least one of the obtained first set of KPIs or the obtained one at least one set of measurements.

First device information, which is information independent from settings of a device or functions of a device, is obtained from a device in bulk; second device information, which is information that depends on settings of a device or functions of a device, is obtained; and the obtained first and second device information are stored in a storage unit. A device connected through communication is then specified on the basis of the obtained first device information.

A spacecraft network management system includes five functional entities, namely, attendant, accessor, collector, logic, and logic watchdog in a distributed architecture configured with both in-band and out-of-band data paths. Management data is structured so that it can travel over either in-band or out-of-band and be identified as such; user data travels over in-band paths. These five entities are distributed over the units of the design and then a modified set of otherwise standard elements are assigned to each entity depending on the nature of its function. These elements include managers, management agents, device agents, device management information base, and manager management information base that enable the entities to perform their respective functions.

In accordance with embodiments disclosed herein, an exemplary system or computer implemented method for implementing the virtualization of access node functions may include, for example: a memory to store instructions for execution; one or more processors to execute the instructions; a control plane interface to communicably interface the system with an access node over a network, in which the access node is physically coupled with a plurality of broadband lines; a virtualized module to provide a virtualized implementation of a plurality of functions of the access node at the system, in which the virtualized module executes on a virtualized computing infrastructure; the control plane interface of the system to receive current operational data and current operating conditions for the plurality of broadband lines from the access node; the virtualized module to update the virtualized implementation of the plurality of functions of the access node at the system according to the current operational data and the current operating conditions received from the access node; an analysis module to analyze the current operational data and the current operating conditions received from the access node; an instruction module to generate control parameters to affect operation of the access node based on the analysis of the current operational data and the current operating conditions received; and the control plane interface to send the control parameters to the access node for adoption at the access node. Other related embodiments are disclosed.