Abstract:
According to various examples, a processing system is described comprising a plurality of hardware circuit components, each hardware circuit component configured to provide a processing functionality, a data path leading through the plurality of hardware circuit components, at least one programmable circuit and a controller configured to select one of the hardware circuit components to be replaced by the at least one programmable circuit, program the programmable circuit to provide the processing functionality provided by the selected hardware circuit component and configure the data path to lead through the programmable circuit instead of the selected hardware circuit component.
Abstract:
An architecture to allow the spatial separation of information sources, information processing, and information consumption using objects and tags, including in mobile/multi-access edge computing (MEC) communication environments, is disclosed. In an example, a request for information provided to a network entity (such as a MEC entity) results in the receipt of an object and a tag, as a device operates in an operational area of an information service. The object provides data for the information service, and the tag provides the metadata related to a context of the information service and the object from another entity, for another entity located within the operational area of the location service. The use of this object, including in the form of an application, data, or user object type, allows a transfer and use of data and context for the information service that is independent from the access network.
Abstract:
A mobile small station including a transceiver, a processor, and a memory having instructions for execution by the processor to exchange measurement information with a macro station, provide a wide area network connection and act as a relay for a small station moving network with the mobile small station, and perform handover of relay responsibilities to another mobile small station in the small station moving network.
Abstract:
The disclosure relates to systems, methods, and devices for protecting Vehicle-to-Everything (V2X) communications (also known as intelligent transport systems (ITS) communications) from spurious emissions of nearby wireless devices operating in near-band or adjacent frequency bands. The system detects radio signals of a nearby ITS communication device, determines its radio communication parameters, and determines an interference condition based on whether the wireless device may interfere with the ITS communication device. The system also requests a change, based on the interference condition, in the radio subsystem communication parameters of the wireless device. The system also determines a geographic location of the wireless device, and, based on whether the requested change complies with a regulatory requirement of the determined geographic location, implements the requested change.
Abstract:
A mobile small station including a transceiver, a processor, and a memory having instructions for execution by the processor to exchange measurement information with a macro station, provide a wide area network connection and act as a relay for a small station moving network with the mobile small station, and perform handover of relay responsibilities to another mobile small station in the small station moving network.
Abstract:
Some demonstrative embodiments include apparatuses, devices, systems and methods of predicting a channel condition. For example, A User Equipment (UE) may include a radio to communicate over a millimeter Wave (mmWave) band with at least one network (NW) element of a network controlled by a cellular node, and to receive from the NW element topology information corresponding to a topology at a location of the UE; and a channel estimator to predict a channel condition of a channel between the UE and the cellular node based on the topology information.
Abstract:
Technology for downlink signaling between an enhanced Node B (eNB) and user equipment (UE) with a selected cyclic prefix (CP) for the UE is disclosed. In an example, a user equipment (UE) can include circuitry configured to: estimate a delay spread for a corresponding channel between the eNB and the UE; communicate the estimated delay spread from the UE to the eNB to enable the eNB to determine a selected cyclic prefix (CP) length for downlink signaling; receive the selected CP length from the eNB for a transmission time interval (TTI); and process received downlink data for the TTI using the selected CP length.
Abstract:
Traffic engineering functionalities are described in a heterogeneous network that includes an anchor base station serving a cellular macro cell and booster base stations serving mmWave enabled small cells. The described functionalities are designed to cope with dynamic changes in the heterogeneous environment such as loss of a backhaul link between the anchor base station and the booster base station, loss of a link between a terminal and one of the base stations, and loss of beam forming in a mmWave link between the terminal and the booster base station.
Abstract:
An architecture to allow the translation or conversion of short-range direct communications between devices with different radio access, such as in a V2X (vehicle-to-everything) communication context, is disclosed. In an example, a translation process, such as is performed by a mobile/multi-access edge computing (MEC) communication entity, includes: obtaining or accessing, at a translation function, a communication message (e.g., IP message) provided from a first device operating with a first radio access technology (e.g., LTE C-V2X), the message addressed to a second device operating with a second radio access technology (e.g., IEEE 802.11p or DSRC/ITS-G5); converting the communication message, with the translation function, into a format compatible with the second radio access technology; and initiating a transmission of the translated communication message, from the translation function, to the second device using the second radio access technology.
Abstract:
An architecture to allow the translation or conversion of short-range direct communications between devices with different radio access, such as in a V2X (vehicle-to-everything) communication context, is disclosed. In an example, a translation process, such as is performed by a mobile/multi-access edge computing (MEC) communication entity, includes: obtaining or accessing, at a translation function, a communication message (e.g., IP message) provided from a first device operating with a first radio access technology (e.g., LTE C-V2X), the message addressed to a second device operating with a second radio access technology (e.g., IEEE 802.11p or DSRC/IS-G5); converting the communication message, with the translation function, into a format compatible with the second radio access technology; and initiating a transmission of the translated communication message, from the translation function, to the second device using the second radio access technology.