A method for automatic configuration of a communication network includes: generating a request message, the request message including a communication address associated; transmitting the generated request message as a broadcast message to a plurality of computing devices using a predefined user datagram protocol (UDP) port, the message being broadcast with a predetermined time to live; receiving agreement messages from computing devices transmitted by the respective computing device using the predefined UDP port, each agreement message including a communication address associated with the respective computing device and a specified transmission control protocol (TCP) port; identifying at least one of the one or more agreement messages for establishment of communication; and establishing a communication connection to the computing device associated with each identified agreement message using the specific TCP port.

A device in an evolved packet core (EPC) which includes a processor and a memory. The processor effectuates operations including receiving from one or more devices residing within a customer premise equipment (CPE) portion of a telecommunications network, sensor data associated with one or more customers and in response to receiving the sensor data, generating a data request for an ecosystem status for the CPE portion of the telecommunications network. The processor further effectuates operations including obtaining customer information for the one or more customers and creating an analytics environment, using the customer information, for the one or more customers. The processor further effectuates operations including performing, within the analytics environment, analytics on the sensor data to determine a state of the CPE portion of the telecommunications network for the one or more customers and in response to performing analytics on the sensor data, optimizing the telecommunications network.

Systems and methods are provided for establishing a video conference session. The systems and methods may include receiving, from a first conference client device, a request to establish a conference session with a second conference client device; determining a first media router for forwarding, to the second conference client device, a media data stream with predetermined attributes of a plurality of first media data streams generated by the first conference client device; determining a second media router for forwarding, to the first conference client, a media data stream with predetermined media attributes of a plurality of second media data streams generated by the second conference client device; and transmitting, to the first conference client device, a first address associated with the first media router and a second address associated with the second media router.

Systems and methods are provided for establishing a video conference session. The systems and methods may include receiving, from a first conference client device, a request to establish a conference session with a second conference client device; determining a first media router for forwarding, to the second conference client device, a media data stream with predetermined attributes of a plurality of first media data streams generated by the first conference client device; determining a second media router for forwarding, to the first conference client, a media data stream with predetermined media attributes of a plurality of second media data streams generated by the second conference client device; and transmitting, to the first conference client device, a first address associated with the first media router and a second address associated with the second media router.

This application provides a network configuration method, apparatus, and system. The method includes: determining, based on a mapping relationship, that a first data node in a first YANG data model corresponds to a second data node in a second YANG data model, where the first data node and the second data node include a same indication operation, and the mapping relationship includes a correspondence between a data node in the first YANG data model and a data node in the second YANG data model; and generating a first packet based on the second data node.

Examples described here include systems and methods for configuring device settings for a number of user devices across an enterprise. A management server can provide a user interface at an administrator console for creating a profile and identifying an associated device type. The management server can then retrieve a schema file associated with the device type. Based on information in the schema file, the management server can populate the user interface at the administrator console with available configuration options pertaining to the device type. An administrator can configure the options and send instructions to the management server to deploy the profile across the number of user devices. The management server can instruct each user device to download a device configuration application from an application repository and transmit the settings information to an agent application of the user device that has permission to configure the device configuration application.

A configurable management system for a vehicle includes a receiving unit adapted to receive a message associated with a vehicle resource from a communication network of the vehicle. A control unit is adapted to determine a vehicle resource associated with the received message. An integration unit includes an external network connected to the control unit and the integration unit further includes at least one node, wherein the at least one node is configured to send an external message on the external network to the control unit. The control unit converts the external message to a suitable message that is sent to the vehicle resource.

A faulty node is identified in a cloud native environment by retrieving a topology that describes a relationship between a plurality of nodes in a network, retrieving a list of alarms in the network, determining a child node in the network located at the bottom of the topology that has a first alarm based on the alarm list, determining a parent node of the child node located above the child node and below or on an apex node of the network that has a second alarm based on the topology, determining whether the parent node is an apex node in the network based on the topology, and based on a determination that the parent node is the apex node in the network, identify the parent node as the faulty node.

An electronic device may include: a communication module; a processor operatively connected to the communication module; and a memory operatively connected to the processor and configured to store computer program code. The computer program code, when executed, enables the processor to: upon detection of execution of a first operation of a first Internet of Things (IoT) device, obtain, from the memory, a first instruction to operate the first IoT device in a second operation; transmit the first instruction to the first IoT device to operate the first IoT device in the second operation; and monitor execution of the second operation by the first IoT device.

Techniques are described for managing communications for a managed virtual computer network overlaid on a distinct substrate computer network, including for communications involving computing nodes of the managed virtual computer network that use an alternative addressing scheme to direct network packets and other network communications to intended destination locations by using textual network node monikers instead of numeric IP addresses to represent computing nodes at a layer 3 or “network layer” of a corresponding computer networking stack in use by the computing nodes. The techniques are provided without modifying or configuring the network devices of the substrate computer network, by using configured modules to manage and modify communications from the logical edge of the substrate network.