Techniques for integrating a device platform in a core network or MEC environment, and managing data communications associated with devices are presented. The device platform, integrated with the core network or MEC environment, can comprise a communication management component (CMC) that can manage communication of data associated with devices connected to the core network. CMC can receive data and metadata from a device, analyze the data and metadata, and, based on the analyzing and data management criteria, determine whether any, all, or a portion of the data is to be communicated to a second device associated with the core network or associated communication network. CMC can be trained, using machine learning, to learn to identify device types, communication protocols, and data payload formats of devices. Based on the analyzing and the training, CMC can determine the device type, communication protocol, and data payload format associated with the device.

In various embodiments, a method, apparatus, and computer program product are provided involving, at a first device: opening the application on the first device, performing an action utilizing an application, updating a state of the application, for being communicated with the second device; and, at a second device: utilizing the updated state of the application received from the first device, displaying an interface including: a button for opening the application utilizing the second device, and indicia that indicates that the first device has updated at least one aspect of the application, and in response to a detection of the selection of the button, accessing the application utilizing the second device such that the application is accessed so as to reflect the updated state of the application.

In various embodiments, a method, apparatus, and computer program product are provided involving, at a first device: opening the application on the first device, performing an action utilizing an application, updating a state of the application, for being communicated with the second device; and, at a second device: utilizing the updated state of the application received from the first device, displaying an interface including: a button for opening the application utilizing the second device, and indicia that indicates that the first device has updated at least one aspect of the application, and in response to a detection of the selection of the button, accessing the application utilizing the second device such that the application is accessed so as to reflect the updated state of the application.

According to certain embodiments, an electronic device comprises a first communication circuit configured to support a first communication protocol; a display; and at least one processor operatively connected to the first communication circuit and the display, wherein the at least one processor is configured to: configure a cluster with at least one external electronic based on the first communication protocol device through the first communication circuit, receive through the first communication circuit, from the at least one external electronic device, information identifying at least one short-range communication device connected to the at least one external electronic device via a second communication protocol, and control the display to display at least one indicator of the at least one short-range communication device based on the information received from the at least one external electronic device.

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.

This disclosure relates to the technical field of automobiles and software and discloses an interface circuit and a method and apparatus for interface communication thereof. In the interface circuit, a micro-control unit has an output interface connected to a first conversion unit connected to a USB HOST interface and a USB SLAVE interface and a second conversion unit connected to an HDMI interface, and is configured to control the first conversion unit to be set in a HOST mode to communicate with the USB HOST interface when receiving a trigger signal from the USB HOST interface, the first conversion unit to be set in an SLAVE mode to communicate with the USB SLAVE interface when receiving a trigger signal from the USB SLAVE interface, and the second conversion unit to output the TMDS signal to communicate with the HDMI interface when receiving a trigger signal from the HDMI interface.

A process for extending unencrypted and encrypted voice for Land Mobile Radio communication across a wider geographical area using a repeater. The solution used is based upon an approach of embedding P25 Phase II signals inside P25 Phase I signals when required to communicate with a remote terminal.

Embodiments described herein provide a method for providing a compatible backplane operation mechanism for 2.5-gigabit Ethernet. A first input of data including a first sequence-ordered set in compliance with a first interface protocol is received from a medium access control (MAC) layer. The first input of data is encoded into four outputs of encoded data including a second sequence-ordered set in compliance with a second interface protocol. The first sequence-ordered set in a first form of a sequence code followed by three bytes of data is mapped to the second sequence-ordered set in a second form of consecutive units of the sequence code followed by an encoded data byte. The four parallel outputs of encoded data are serialized into a serial output. The serial output to a linking partner is transmitted on a physical layer of an Ethernet link at a speed specified in the second interface protocol.

Embodiments described herein provide a method for providing a compatible backplane operation mechanism for 2.5-gigabit Ethernet. A first input of data including a first sequence-ordered set in compliance with a first interface protocol is received from a medium access control (MAC) layer. The first input of data is encoded into four outputs of encoded data including a second sequence-ordered set in compliance with a second interface protocol. The first sequence-ordered set in a first form of a sequence code followed by three bytes of data is mapped to the second sequence-ordered set in a second form of consecutive units of the sequence code followed by an encoded data byte. The four parallel outputs of encoded data are serialized into a serial output. The serial output to a linking partner is transmitted on a physical layer of an Ethernet link at a speed specified in the second interface protocol.

A method for concurrent execution of multiple protocols using a single radio of a wireless communication device is provided that includes receiving, in a radio command scheduler, a first radio command from a first protocol stack of a plurality of protocol states executing on the wireless communication device, determining a scheduling policy for the first radio command based on a current state of each protocol stack of the plurality of protocol stacks, and scheduling the first radio command in a radio command queue for the radio based on the scheduling policy, wherein the radio command scheduler uses the radio command queue to schedule radio commands received from the plurality of protocol stacks.