The invention relates to a control device for controlling radio frequency sensing in a network (100), e.g. Zigbee or Wi-Fi network, comprising a detection area (120). The control device (110) comprises a neighboring network information providing unit (111), wherein the neighboring network (150) comprises a neighbor network device (154) neighboring a network device of the network (100), and a network controlling unit (112) for controlling a network device (103) based on the provided neighboring network information such that the network device of the network is enabled to detect a signal usable for radio frequency sensing in a detection area (170) extending outside of the detection area of the network (100) and/or for radio frequency sensing in the detection area of the network (100), wherein the detected signal is transmitted by at least one neighbor network device. This allows to improve the radio frequency detection in peripheral areas of a network.

The invention relates to a control device for controlling radio frequency sensing in a network (100), e.g. Zigbee or Wi-Fi network, comprising a detection area (120). The control device (110) comprises a neighboring network information providing unit (111), wherein the neighboring network (150) comprises a neighbor network device (154) neighboring a network device of the network (100), and a network controlling unit (112) for controlling a network device (103) based on the provided neighboring network information such that the network device of the network is enabled to detect a signal usable for radio frequency sensing in a detection area (170) extending outside of the detection area of the network (100) and/or for radio frequency sensing in the detection area of the network (100), wherein the detected signal is transmitted by at least one neighbor network device. This allows to improve the radio frequency detection in peripheral areas of a network.

Techniques are provided for reducing the network signaling associated with radio resource management (RRM) measurements and mobility procedures. An example method for performing radio resource management measurements includes receiving positioning assistance data including station location information, determining a current location and a future trajectory, and performing radio resource management measurements with one or more stations based at least in part on the positioning assistance data and the future trajectory.

Techniques are provided for reducing the network signaling associated with radio resource management (RRM) measurements and mobility procedures. An example method for performing radio resource management measurements includes receiving positioning assistance data including station location information, determining a current location and a future trajectory, and performing radio resource management measurements with one or more stations based at least in part on the positioning assistance data and the future trajectory.

Methods, systems, and devices for wireless communications are described. In a wireless communications system, a user equipment (UE) may receive control signaling indicating a first semi-static configuration for transmitting uplink signaling and a second semi-static configuration for receiving downlink signaling. In some cases, the UE may operate using half-duplex communications and may monitor for a transmission direction conflict between the first semi-static configuration and the second semi-static configuration during a transmission time interval. The UE may communicate, according to a priority rule, one of an uplink signal in accordance with the first semi-static configuration or a downlink signal in accordance with the second semi-static configuration during the transmission time interval based on the monitoring. Additionally, or alternatively, the UE may drop one of the uplink signal or downlink signal according to the priority rule.

Methods, systems, and devices for wireless communications are described. In a wireless communications system, a user equipment (UE) may receive control signaling indicating a first semi-static configuration for transmitting uplink signaling and a second semi-static configuration for receiving downlink signaling. In some cases, the UE may operate using half-duplex communications and may monitor for a transmission direction conflict between the first semi-static configuration and the second semi-static configuration during a transmission time interval. The UE may communicate, according to a priority rule, one of an uplink signal in accordance with the first semi-static configuration or a downlink signal in accordance with the second semi-static configuration during the transmission time interval based on the monitoring. Additionally, or alternatively, the UE may drop one of the uplink signal or downlink signal according to the priority rule.

Various aspects of the present disclosure generally relate to wireless communication. In some aspects, a user equipment (UE) may detect a first condition of the UE. The UE may perform one or more actions associated with coverage enhancement based at least in part on a measure of similarity between the first condition of the UE and a second condition of the UE associated with a past beam failure event. Numerous other aspects are described.

Various aspects of the present disclosure generally relate to wireless communication. In some aspects, a user equipment (UE) may detect a first condition of the UE. The UE may perform one or more actions associated with coverage enhancement based at least in part on a measure of similarity between the first condition of the UE and a second condition of the UE associated with a past beam failure event. Numerous other aspects are described.

A communication system has a plurality of LEO satellites in a specified orbital plane and a plurality of trunk satellites in a medium earth orbit. Each LEO satellite acquires satellite-specific data and includes inter-satellite links with adjacent LEO satellites. Each trunk satellite includes inter-satellite links adjacent trunk satellites. One of the trunk satellites operates as a relay trunk satellite in position to maintain optical communication with a specified ground station on the Earth. Each LEO satellite has a limited field of regard to establish optical communication with any trunk satellite. A relay LEO satellite is configured to establish optical communication with a corresponding trunk satellite. The plurality of LEO satellites relay aggregated data to the relay LEO satellite. The relay LEO satellite relays the aggregated data to the corresponding trunk satellite. The relay trunk satellite relays the received aggregated data to the corresponding ground station.

Apparatus and method for wireless communications that include RLM or BFD procedures. The apparatus measures one or more reference signals for an RLM procedure or a BFD procedure. The apparatus reduces a rate of the measuring the one or more reference signals for the RLM procedure or the BFD procedure based at least in part on at least one measurement of the one or more reference signals meeting a relaxation criteria.