In modern networks, RRU and BBU equipment of an access point site typically handles traffic from a single sector. An RRU-BBU pair process that traffic (often limited to a single spectrum from a single sector) according to implemented capabilities and other equipment located further upstream perform functions that rely on information from multiple sectors. An integrated device (e.g., white box) can integrate the functionality of multiple RRU (or NR in 5G) and the functionality of multiple BBU (or DU/CU splits in 5G), which can reduce implementation footprint, costs, and can provide related services more efficiently without going upstream.

Improved computer technology is disclosed for enabling high performance stream processing on data such as complex, hierarchical data. In an example embodiment, a dynamic field schema specifies a dynamic field format for expressing the incoming data. An incoming data stream is then translated according to the dynamic field schema into an outgoing data stream in the dynamic field format. Stream processing, including field-specific stream processing, can then be performed on the outgoing data stream.

Improved computer technology is disclosed for enabling high performance stream processing on data such as complex, hierarchical data. In an example embodiment, a dynamic field schema specifies a dynamic field format for expressing the incoming data. An incoming data stream is then translated according to the dynamic field schema into an outgoing data stream in the dynamic field format. Stream processing, including field-specific stream processing, can then be performed on the outgoing data stream.

A method of operating a network subscriber comprises receiving an input-data stream containing an input-transmission frame according to a field-bus protocol, where the input-data stream is received in chronologically successive data units having a defined processing width, decoding fields of the input-transmission frame by a plurality of field-processing units arranged in series, each field-processing unit decoding a predetermined field of the input-transmission frame, and generating an output-data stream comprising an output transmission frame according to the field-bus protocol from the input-data stream.

A method of operating a network subscriber comprises receiving an input-data stream containing an input-transmission frame according to a field-bus protocol, where the input-data stream is received in chronologically successive data units having a defined processing width, decoding fields of the input-transmission frame by a plurality of field-processing units arranged in series, each field-processing unit decoding a predetermined field of the input-transmission frame, and generating an output-data stream comprising an output transmission frame according to the field-bus protocol from the input-data stream.

A technology is provided for invoking a random linear network coding (RLNC) communications protocol between a client and server in a network. In one example, a synchronize message requesting a network connection to a server can contain an indication that a client supports the RLNC communications protocol to encode and decode data packets using random linear network coding. The server can analyze the synchronize message for the indication that the client supports the RLNC communications protocol and send an acknowledge message to the client indicating that the server supports the RLNC communications protocol. Thereafter, the server can listen on a communications channel for a connection request sent by the client to communicate with the server using the RLNC communications protocol.

A technology is provided for invoking a random linear network coding (RLNC) communications protocol between a client and server in a network. In one example, a synchronize message requesting a network connection to a server can contain an indication that a client supports the RLNC communications protocol to encode and decode data packets using random linear network coding. The server can analyze the synchronize message for the indication that the client supports the RLNC communications protocol and send an acknowledge message to the client indicating that the server supports the RLNC communications protocol. Thereafter, the server can listen on a communications channel for a connection request sent by the client to communicate with the server using the RLNC communications protocol.

In some embodiments, a wireless electronic device translation system includes a translator that includes a first antenna, a second antenna, and a controlling unit coupled to the first antenna and the second antenna. The translator may be configured to receive a wireless communication signal transmitted from a first electronic device at a first frequency, interpret a communication content from the wireless communication signal using a first communication protocol, translate the first communication content to be transmitted as a wireless translated signal using a second communication protocol, and transmit the wireless translated signal at a second frequency to be received by a second electronic device.

In some embodiments, a wireless electronic device translation system includes a translator that includes a first antenna, a second antenna, and a controlling unit coupled to the first antenna and the second antenna. The translator may be configured to receive a wireless communication signal transmitted from a first electronic device at a first frequency, interpret a communication content from the wireless communication signal using a first communication protocol, translate the first communication content to be transmitted as a wireless translated signal using a second communication protocol, and transmit the wireless translated signal at a second frequency to be received by a second electronic device.

A device for service-oriented communication with a signal-based hardware architecture. The device comprises a number of service-oriented communication interfaces for communicative connection to a number of external service-oriented communication partners, a number of signal-based communication interfaces for communication with a number of external signal-based devices, and an embedded system. The embedded system is configured to communicatively connect respective signal-based communication interfaces to respective service-oriented communication interfaces according to a predefined routing logic, and to transform signal-based communication signals, provided by the respective signal-based communication interfaces, into service-oriented communication signals according to a service-oriented communication protocol, and to transform service-oriented communication signals, provided by the respective service-oriented communication interfaces, into signal-based communication signals according to a signal-based communication protocol.