A method for transmitting data through a multi-media communication network includes converting transmission entities into data symbols at a first communication device, transmitting the data symbols from the first communication device to a second communication device through at least two different types of communication media using only lower PHY layers of the at least two different types of communication media, and converting the data symbols into transmission entities at the second communication device. A network implementing a universal data link includes a first communication device configured to convert transmission entities into data symbols, a second communication device configured to convert the data symbols into transmission entities, at least a first communication medium and a second communication medium communicatively coupled between the first communication device and the second communication device, and a first physical-layer translator configured to translate data symbols without converting the data symbols into transmission entities.

A pervasive realtime framework supports the execution of realtime software applications with high-level functions that significantly reduce the effort and time needed to develop realtime software applications in a new operating environment paradigm in which realtime connections between network nodes are pervasive. The pervasive realtime framework handles the complex tasks of connecting to communicants, virtual areas, and other network resources, as well as switching those connections in response to user inputs and thereby enables software application developers to focus on developing high-level realtime software application functionality.

A pervasive realtime framework supports the execution of realtime software applications with high-level functions that significantly reduce the effort and time needed to develop realtime software applications in a new operating environment paradigm in which realtime connections between network nodes are pervasive. The pervasive realtime framework handles the complex tasks of connecting to communicants, virtual areas, and other network resources, as well as switching those connections in response to user inputs and thereby enables software application developers to focus on developing high-level realtime software application functionality.

Techniques for policy management and enforcement using semantic data modeling are provided. A first declarative policy is received at a network node from a controller. A first semantic data query protocol (SDQP) transaction is generated by retrieving a first semantic data model associated with the network node, where the first semantic data model describes a configuration domain of the network node, and parsing the first declarative policy based on the first semantic data model to generate the first SDQP transaction. The first declarative policy is then implemented by executing the first SDQP transaction against a semantic database.

A method for network hardware table management includes: obtaining, by a network device table manager of a network device, a first feature table entry of a first feature table, where the first feature table entry comprises a first prefix and a first action to take for a first feature; obtaining, by the network device table manager, a second feature table entry of a second feature table, where the second feature table entry comprises a second prefix and a second action to take for a second feature; making a first determination that the first prefix and the second prefix include a common portion and that the common portion is an entirety of each of the first and second prefixes; and in response to the first determination, adding a combined feature table entry to a combined feature table.

Systems and methods for providing a middleware application for user-interface-driven applications include receiving, at the middleware application, queries from different dynamic user interface modules associated with respective front-end applications. The front-end applications are authenticated using authentication data included in the query and verification data external to the middleware application. In response to each query, the middleware application receives data from different external data sources, each being a separate instance of the same back-end service. The data is used to generate objects declaring instances of user interface elements, which are sent by the middleware application to the requesting dynamic user interface module for rendering at the associated front-end application.

A centralized unit of a communication network adopting a high layer split architecture acquires an abstractive model of a plurality of antenna line devices from a distributed unit of the communication network. The centralized unit operates the plurality of antenna line devices by communicating with the distributed unit by using the abstractive model. The distributed unit can perform elementary control of the plurality of antenna line devices based on the communication with the centralized unit.

The present disclosure is directed to systems and methods for managing on-site communications of a machine with a latency-dependent application installed. The method includes, for example, (i) receiving geographical information associated with a work site; (ii) receiving historical communications information associated with the work site; (iii) analyzing the historical communications information and the geographical information; (iv) generating an instruction for implementing the latency-dependent application of the machine based on a latency requirement of the latency-dependent application; and (v) implementing the latency-dependent application of the machine based on the instruction. The historical communications information includes a communications event, a duration of the communications event, and a frequency of the communications event.

Systems, software, and methods for managing traditional (i.e., TCP/IP-based), non-traditional, and traditional-non-traditional hybrid networks of connected electronic devices are described. In one example, network management policy and network management applications are downloaded automatically upon detection and identification of a new device, application or service on a network. In another example, information related to at least one aspect of the network is obtained by a network management device through connection to a non-TCP/IP network, or by way of a gateway device or application, at least one applicable management policy is identified, and the identified policy is used to manage at least one aspect of the network's operation. In another example, devices, applications or services presenting various behaviors under various scenarios are evaluated and placed under management.

High-speed control of disaggregated network systems is implemented. A control device includes a main memory and an interface. The main memory shares management information contained in memory spaces possessed by a plurality of respective component devices connected and stores the management information as integrated management information. When the management information is to be updated, the interface transmits an update signal for updating the management information to the component devices and receives a response signal to the update signal from the component devices.