Methods for configuring a monitoring device to communicate with a service server are provided. The method includes the monitoring device sending a message including a code used for authentication of the monitoring device to a control server, receiving one or more addresses of a service server associated with the monitoring device from the control server in response to the monitoring device being authenticated by the control server, storing the one or more addresses retrieved by the control server, and establishing a connection between the monitoring device and the service server using at least one of the one or more addresses received from the control server.

A computer readable storage medium, system and method for improving automated testing systems to include a first and second behavioral data. The first behavioral data is collected periodically and the second behavioral data is collected in real time. The receipt of the first behavioral data and a second behavioral data are followed by the receipt of a system configuration template. A test case is updated based on the first and second behavioral data, and an automated test environment is reconfigured based on the first behavioral data, second behavioral data, and the system configuration template. The test executes in the automated test environment producing a test result.

A method and a node identification system for identifying at least one unknown mobile node in a communications network using details related to at least one known mobile node and organization of the details related to the at least one known mobile node. The method includes capturing details related to the at least one unknown mobile node and identifying an organization of the captured details related to the at least one unknown mobile node, comparing the details related to the at least one known mobile node and the organization of the details related to the at least one known mobile node with the captured details related to the at least one unknown mobile node and the organization of the captured details related to the at least one unknown mobile node, and determining a type of the at least one unknown mobile node based on the comparing.

Some organizations have a deployed and functional “controllerless” EVPN VxLAN Fabric in their data centers. Eventually, however, the organization may deploy a controller within the network. In one example, this disclosure describes a method that includes configuring a controller to communicate with each of a plurality of elements in a network; determining, by the controller, an initial operational state of the network; translating, by the controller, the initial operational state of the network to an intent-based configuration; pushing, by the controller, the intent-based configuration to the network to reconfigure each of the plurality of elements in the network in a manner consistent with the intent-based configuration; determining, by the controller and after pushing the intent-based configuration, an updated operational state of the network; and comparing, by the controller, the initial operational state of the network with the updated operational state of the network.

Some organizations have a deployed and functional “controllerless” EVPN VxLAN Fabric in their data centers. Eventually, however, the organization may deploy a controller within the network. In one example, this disclosure describes a method that includes configuring a controller to communicate with each of a plurality of elements in a network; determining, by the controller, an initial operational state of the network; translating, by the controller, the initial operational state of the network to an intent-based configuration; pushing, by the controller, the intent-based configuration to the network to reconfigure each of the plurality of elements in the network in a manner consistent with the intent-based configuration; determining, by the controller and after pushing the intent-based configuration, an updated operational state of the network; and comparing, by the controller, the initial operational state of the network with the updated operational state of the network.

Systems and methods for building management utilizing adaptive edge processing are disclosed. The building system can store gateway components on storage devices. The gateway components can facilitate communication with a cloud platform and facilitate communication with a physical building device. The building system can identify a computing system of the building that is in communication with the physical building device. The physical building device can store one or more data samples. The building system can deploy the gateway components to the computing system responsive to identifying that the computing system is in communication with the physical building device. The gateway components can cause the computing system to communicate with the physical building device to receive the one or more data samples and cause the computing system to communicate the one or more data samples to the cloud platform.

Systems and methods for building management utilizing adaptive edge processing are disclosed. The building system can store gateway components on storage devices. The gateway components can facilitate communication with a cloud platform and facilitate communication with a physical building device. The building system can identify a computing system of the building that is in communication with the physical building device. The physical building device can store one or more data samples. The building system can deploy the gateway components to the computing system responsive to identifying that the computing system is in communication with the physical building device. The gateway components can cause the computing system to communicate with the physical building device to receive the one or more data samples and cause the computing system to communicate the one or more data samples to the cloud platform.

A method and a system for forming a network of network devices, the method including providing a plurality of network devices in a physical environment, each of the plurality of network devices being controllable by a mobile network module connectable to the network devices. A network configuration device with a memory unit for storing device configuration data connects a mobile network module to the network configuration device. The mobile network module reads out the device configuration data stored in the memory unit of the network configuration device. The mobile network module connects to a network device and configuring the network device, based on the device configuration data.

A persistent version-controlled is provided the enables automated configuration of VNFs/CNFs following deployment or re-deployment of VNF/CNF instances throughout the life cycle of the VNFs/CNFs. Immutable copies of NF configurations for a VNF/CNF are stored in the version controlled data storage 100. Multiple versions of a NF configuration can be associated with a common configuration reference (e.g., URL). Metadata associated with the different versions of a NF configuration indicates which of two or more different versions is the current version. The collection of different versions of a NF configuration associated with the same stable reference provide a complete history of the NF configuration, thus allowing rollback to any previous version of the NF configuration by simply modifying the metadata to mark that version as the current version. If a VNF/CNF needs to be re-deployed, the same configuration reference used during the initial deployment is used to download the most recent version of the NF configuration based on the metadata.

There is provided a method of operating a Service Communication Proxy, SCP, node (608, 1000) in a communication network as a proxy network repository function, NRF, for a first network function, NF, producer node in the communication network. The first NF producer node (602, 1100) is to migrate from a direct communication mode with a first NF consumer node (606) to an indirect communication mode with the first NF consumer node (606) via the SCP node (608, 1000). The SCP node (608, 1000) discovers a NF profile for the first NF producer node (602, 1100), wherein the NF profile for the first NF producer node (602, 1100) is stored by a first network repository function, NRF, node (604) in the communication network, and the NF profile comprises a service address for the first NF producer node (602, 1100); receives a registration request from the first NF producer node (602, 1100), wherein the registration request is a request to register a NF profile for the first NF producer node (602, 1100) at a NRF node (604), wherein the registration request indicates the service address for the first NF producer node (602, 1100); and, in response to the received registration request, sends an update request to the first NRF node (604) to update the NF profile for the first NF producer node (602, 1100) stored by the first NRF node (604) to replace the service address of the first NF producer node (602, 1100) with a first service address of the SCP node (608, 1000) that is associated with the service address of the first NF producer node (602, 1100).