An aggregation router for an aircraft may include processing circuitry. The processing circuitry may be configured to receive a first channel from a first airborne radio, and receive a second channel from a second airborne radio. The first and second channels may be WAN connections to wireless communication network resources on the ground. The processing circuitry may be further configured to aggregate the first and second channels for service to LAN connections on the aircraft, which LAN connections may include one or more short range wireless communication access points.

A communication system includes a traveling cart, a wireless base station, and a communication manager. A cart controller of the traveling cart configured or programmed to transmit traveling position information indicating the traveling position of the traveling cart to the wireless base station via a cart wireless communicator. A controller of the communication manager is configured or programmed to acquire at least one recommended transmission rate from a transmission rate table stored in a storage based on the traveling position information of the traveling cart received by wired communication with the wireless base station, and generate transmission rate information. The controller is configured or programmed to transmit the transmission rate information and management side transmission information to transmit to the traveling cart to the wireless base station via a communicator. The wireless base station transmits the management side transmission information which is received, to the traveling cart at the transmission rate acquired from the transmission rate information.

According to a method of an embodiment of the present disclosure, a method for correcting a beamforming pattern of a base station by an analysis server of a base station management network may comprise the steps of: when network management information is received from a first base station, identifying whether or not the network management information indicates the occurrence of a failure in an antenna element of the first base station; when the network management information indicates the occurrence of the failure in the antenna element of the first base station, analyzing an effect of a beamforming pattern of the first base station and analyzing a change in a cell coverage; on the basis of the result of the analysis, determining a first beamforming pattern for compensating for the failure in the antenna element; and transmitting, to the first base station, information about the first beamforming pattern by including the information in management control information.

According to a method of an embodiment of the present disclosure, a method for correcting a beamforming pattern of a base station by an analysis server of a base station management network may comprise the steps of: when network management information is received from a first base station, identifying whether or not the network management information indicates the occurrence of a failure in an antenna element of the first base station; when the network management information indicates the occurrence of the failure in the antenna element of the first base station, analyzing an effect of a beamforming pattern of the first base station and analyzing a change in a cell coverage; on the basis of the result of the analysis, determining a first beamforming pattern for compensating for the failure in the antenna element; and transmitting, to the first base station, information about the first beamforming pattern by including the information in management control information.

A control device (223) according to the present disclosure is a control device connected to a plurality of processing devices (240) and a base station device (260) via a network (20). The control device (223) includes a control unit (2233). The control unit (2233) acquires information regarding processing capabilities of the plurality of processing devices (240). The control unit (2233) selects a processing device (2403) that is to execute at least one function of a core network (225) connected to the base station device (260) from among the plurality of processing devices (240) based on the acquired information regarding the processing capabilities.

Disclosed are various embodiments for interfaces for creating radio-based private networks. In one embodiment, a request is received via an interface to create a radio-based private network for a customer. The request indicates a quantity of wireless devices that will connect to the radio-based private network. A quantity of radio units to serve the radio-based private network is determined based at least in part on the quantity of wireless devices. The radio units are preconfigured to implement a radio access network for the radio-based private network. A shipment is initiated to the customer of the radio units that have been preconfigured. Resources in a cloud provider network are provisioned to function as a core network for the radio-based private network.

Examples described herein relate to configuration of access points including Internet-of-Things (IoT) radio. An access point identifier list is received from a network administration node in a network. Each access point identifier in the access point identifier list is uniquely associated with an access point, which includes an IoT radio. A first rules list is received from the network administration node. Each rule in the first rules list indicates a constraint and access point configuration values. An objective function is used to identify access point identifiers satisfying one or more of the constraints in the rules. The access points associated with the identified access point identifiers are configured with the access point configuration values as indicated in the rules.

Examples described herein relate to configuration of access points including Internet-of-Things (IoT) radio. An access point identifier list is received from a network administration node in a network. Each access point identifier in the access point identifier list is uniquely associated with an access point, which includes an IoT radio. A first rules list is received from the network administration node. Each rule in the first rules list indicates a constraint and access point configuration values. An objective function is used to identify access point identifiers satisfying one or more of the constraints in the rules. The access points associated with the identified access point identifiers are configured with the access point configuration values as indicated in the rules.

A method for radar full blockage detection includes transmitting, via a transceiver, radar signals for object detection. The method also includes determining whether an object is detected within a first threshold distance based on reflections of the radar signals that are received. In response to a determination that the object is detected within the first threshold distance, the method includes determining whether the object is detected beyond a second threshold distance, based on the reflections of the radar signals. The second threshold distance is further away from the electronic device than the first threshold distance. In response to determining that the object is within the first threshold distance and not detected beyond the second threshold distance, the method includes determining that the transceiver is fully blocked by the object. upon a determination that the transceiver is fully blocked, the method includes modifying a wireless communication operation associated with the transceiver.

A method for radar full blockage detection includes transmitting, via a transceiver, radar signals for object detection. The method also includes determining whether an object is detected within a first threshold distance based on reflections of the radar signals that are received. In response to a determination that the object is detected within the first threshold distance, the method includes determining whether the object is detected beyond a second threshold distance, based on the reflections of the radar signals. The second threshold distance is further away from the electronic device than the first threshold distance. In response to determining that the object is within the first threshold distance and not detected beyond the second threshold distance, the method includes determining that the transceiver is fully blocked by the object. upon a determination that the transceiver is fully blocked, the method includes modifying a wireless communication operation associated with the transceiver.