A platform for facilitating development of intelligence in an Industrial Internet of Things (IIoT) system generally includes a plurality of distinct data-handling layers having an industrial monitoring systems layer that collects data from or about a plurality of industrial entities in an industrial environment; an industrial entity-oriented data storage systems layer that stores the data collected by the industrial monitoring systems layer; and an adaptive intelligent systems layer that facilitates the coordinated development and deployment of intelligent systems in the IIoT system; wherein the adaptive intelligent systems layer includes an adaptive edge compute management system that adaptively manages edge computation, storage, and processing in the IIoT system.

A satellite monitoring system is disclosed. The system may monitor various downlink signals of various satellites. In response to user queries, the system may provide diagnostic and other data related to the characteristics of the downlink signals. In this manner, an independent verification and validation of downlink signal characteristics may be performed. Moreover, the system may take various actions in response to detected anomalies related to the characteristics of the downlink signals, such as automatically generating alerts for users and/or activating an uplink facility, such as a backup uplink facility and/or providing control signals to user devices, such as antenna controllers, to reorient user antennas in response to the characteristics of the downlink signals.

A satellite monitoring system is disclosed. The system may monitor various downlink signals of various satellites. In response to user queries, the system may provide diagnostic and other data related to the characteristics of the downlink signals. In this manner, an independent verification and validation of downlink signal characteristics may be performed. Moreover, the system may take various actions in response to detected anomalies related to the characteristics of the downlink signals, such as automatically generating alerts for users and/or activating an uplink facility, such as a backup uplink facility and/or providing control signals to user devices, such as antenna controllers, to reorient user antennas in response to the characteristics of the downlink signals.

A configuration for self interference and cross link interference (CLI) management of bidirectional smart repeaters. The apparatus transmits, to a first wireless device, a measurement configuration to measure interference. The measurement configuration comprising a first measurement occasion and a second measurement occasion. The apparatus receives, from the first wireless device, a report of measured interference at the first wireless device based on the measurement configuration. Part of the measured interference under the first measurement occasion is based at least on transmissions forwarded by a relay node.

A configuration for self interference and cross link interference (CLI) management of bidirectional smart repeaters. The apparatus transmits, to a first wireless device, a measurement configuration to measure interference. The measurement configuration comprising a first measurement occasion and a second measurement occasion. The apparatus receives, from the first wireless device, a report of measured interference at the first wireless device based on the measurement configuration. Part of the measured interference under the first measurement occasion is based at least on transmissions forwarded by a relay node.

Methods, systems, and devices for wireless communications are described that support resource utilization based event triggering. A wireless node in a wireless communications system may establish a connection with a core network via a path that includes one or more relay nodes. The wireless node may determine that a network load associated with one or more paths between the wireless node and the core network has changed, or that a difference between two or more network loads of different paths has changed. Based on such a determination, the wireless node may transmit a report to the network. In some cases, the network may receive the report from the wireless node, and may initiate a path change based on the report.

A communication system dynamically controls a User Equipment (UE) handover for multiple repeaters linked in series that include a source repeater and target repeater. The communication system determines individual UE loading for each of the multiple repeaters. The communication system modifies a handover threshold between the source repeater and the target repeater based on the UE loading for each of the multiple repeaters in the series. The communication system serves the UE over the source repeater and applies the modified handover threshold to a signal strength difference between the source repeater and the target repeater. The communication system inhibits the UE handover from the source repeater to the target repeater if the signal strength difference for the UE falls below the modified handover threshold and initiates the UE handover from the source repeater to the target repeater if the signal strength difference for the UE reaches the modified handover threshold.

A relay apparatus 400 performs control to measure a first signal quality of a radio signal from a smart meter 300 and present the first signal quality to a user. The relay apparatus 400 establishes a radio connection with the smart meter 300 having a radio communication function. The relay apparatus 400 relays communication between the smart meter 300 and the power management apparatus 200.

A relay apparatus 400 performs control to measure a first signal quality of a radio signal from a smart meter 300 and present the first signal quality to a user. The relay apparatus 400 establishes a radio connection with the smart meter 300 having a radio communication function. The relay apparatus 400 relays communication between the smart meter 300 and the power management apparatus 200.

Communication is performed between a radio base station and a radio terminal via a reflector. The radio base station transmits a measurement signal including a beam ID of a transmission beam for measuring communication quality between the radio base station and the radio terminal. The reflector reflects the measurement signal incident on the reflector in multiple reflection directions to generate multiple reflected measurement signals. Moreover, the reflector modulates the incident measurement signal during reflection to add information about a reflection direction ID being different for each of the multiple reflection directions to each of the multiple reflected measurement signals. The radio terminal demodulates a reflected measurement signal received from the reflector to acquire the reflection direction ID and the beam ID. The radio terminal then evaluates the communication quality for each combination of the beam ID and the reflection direction ID based on reception state of the received reflected measurement signal.