The present disclosure is directed to systems and methods of managing remote devices. The system can include a server with memory, a detection module, and a collection module. The memory can store a management information base (MIB) having a hierarchical tree of object identifiers and corresponding object values. The detection module can query devices and receive a first object identifier and its first object value, which can vary from those in the MIB; and use patterns to match the first object identifier and object value; and generate an identification of the device from the matches. The collection module can use the identification to select a collection template, which can indicate a subtree of the MIB and a collection pattern; traverse the subtree and identify a second object identifier that matches the collection pattern, and its second object value; and associate the second object value with the first object value.

An example network analysis system includes a memory storing telemetry data received from a plurality of network devices, the plurality of network devices includes extract entity information and connectivity information from the received telemetry data, wherein the entity information represents one or more network devices of the plurality of network devices and the connectivity information represents network connections between one or more devices of the plurality of network devices; and store the connectivity information and entity information as a network topology graph in a graph database, wherein the entity information is stored as nodes of the network topology graph and the connectivity information is stored as edges of network topology graph, and wherein the network topology graph represents an organization level topology of the organization network.

A network device including a first data structure storing a set of buffer profile types. Each buffer profile type is associated with one or more configuration parameters. The network device further includes a second data structure storing a set of peer device identifiers, wherein each peer device identifier of the set of peer device identifiers is associated with a buffer profile type. The network device includes a buffer management application to receive first data associated with a first peer network device coupled via a first link to an interface component of the network device, determine the first data matches a first peer device identifier stored in the second data structure, and assign a first buffer profile type to the interface component of the network device, wherein the first buffer profile type is associated with the first peer device identifier in the second data structure.

Embodiments of a device and method are disclosed. In an embodiment, a method of network diagnostic of a network deployed at a customer site involves at a cloud server connected to the network deployed at the customer site, collecting connectivity state information of the network deployed at the customer site and at the cloud server, performing a network diagnostic operation based on the connectivity state information.

Three-dimensional (3D) visualization of multi-layer networks include receiving data associated with a network, wherein the network includes interconnected network elements that operate at a plurality of levels that include any of network layers and encapsulations; displaying a plurality of three-dimensional icons each represent one of a plurality of network elements of the interconnected network elements; and displaying links between the plurality of three-dimensional icons each link representing one of a network layer connection and an encapsulation connection.

Embodiments of a device and method are disclosed. In an embodiment, a method of automatic network service initiation involves pairing a first network device of a network service block (NSB) with an installer device at a customer site, at the first network device of the NSB, obtaining first network service configuration information from the installer device, performing automatic network service initiation of the first network device of the NSB based on the first network service configuration information, at a second network device of the NSB that is connected with the first network device of the NSB, obtaining address information of a cloud server from the first network device of the NSB, at the second network device of the NSB, obtaining second network service configuration information from the cloud server based on the address information, and performing automatic network service initiation of the second network device of the NSB based on the second network service configuration information.

Technologies for cross-device shared web resource caching include a client device and a shared cache device. The client device scans for a shared cache device in local proximity to the client device and, in response to the scan, registers with the shared cache device. After registering, the client device requests a cached web resource from the shared cache device. The shared cache device determines whether a cached web resource that matches the request is installed in a shared cache. The shared cache device may determine whether an origin of the request matches the origin of the cached web resource. If installed, the shared cache device sends a found response and the cached web resource to the client device. If not installed, the shared cache device sends a not-found response and the client device may request the web resource from a remote web server. Other embodiments are described and claimed.

Transmitting node (120) and receiving node (121) for handling LLDP messages in a communication network (100). The transmitting node (120) transmits a LLDP message to the receiving node (121), which LLDP message comprises security related information enabling to verify authenticity of the transmitting node (120). The receiving node (121) receives one or more LLDP messages, at least one comprising security related information enabling to verify authenticity of the transmitting node (120; 124) that transmitted the LLDP message.

Technology described herein can globally perform management of security tokens of plural nodes of a multi-node system. In an embodiment, a system can comprise an interconnected group of server nodes, and an administrator node communicatively connected to the interconnected group of server nodes and comprising a processor, and a memory that stores executable instructions that, when executed by the processor, facilitate performance of operations. The operations can comprise selecting a server node of the interconnected group of server nodes as a leader server node, resulting in a selection of the leader server node, in response, receiving, by the administrator node from the leader server node, a request for a new security token, and sending, to the leader server node, the new security token, and broadcasting, by the leader server node across a link layer discovery (LLDP) network, the new security token to additional nodes of the interconnected group of nodes.

Servers at a data center having similar hardware configurations are grouped together; a leader server is determined from members of the group. A remote network management console discovers the leader without necessarily discovering each particular server and provides a firmware update to only the leader via a communication network over which the systems management console/application and the group of servers can communicate. The leader receives the firmware update and distributes the update to the other group members. In a cluster environment where servers of a group are substantially identical to one another, a leader of the cluster may use a discovery protocol to determine a catalog of current firmware versions of cluster members and their respective peripherals. Based on the catalog, the systems management console/application determines a custom firmware update that will normalize each member of the cluster to one another and forwards the custom update to the cluster leader.