A resource reselection method and apparatus, and a device and a storage medium. The method includes: transmitting to a second terminal a priority of to-be-transmitted data; receiving a resource set transmitted by the second terminal, the resource set being used to indicate a resource exclusion result obtained by a resource exclusion procedure determined by the second terminal according to the priority of the to-be-transmitted data; and when performing re-evaluation on a first selected resource, determining whether to perform reselection for the first selected resource according to the resource set. The first selected resource is a resource that has been selected by the first terminal and not indicated to another terminal via first sidelink control information.

A system described herein may provide a technique for location-based handling of discovery requests in a service-based network in which different instances of network functions (“NFs”) may be deployed in geographically diverse locations. For example, a Network Repository Function (“NRF”) may maintain location information for the various NF instances and may respond to discovery requests by identifying particular NF instances based on locations associated with the discovery requests. For example, such discovery requests may include a “preferred-locality” parameter or some other indication of location associated with the discovery request, based on which the NRF may identify one or more NF instances to provide in response to the discovery request.

A system described herein may provide a technique for location-based handling of discovery requests in a service-based network in which different instances of network functions (“NFs”) may be deployed in geographically diverse locations. For example, a Network Repository Function (“NRF”) may maintain location information for the various NF instances and may respond to discovery requests by identifying particular NF instances based on locations associated with the discovery requests. For example, such discovery requests may include a “preferred-locality” parameter or some other indication of location associated with the discovery request, based on which the NRF may identify one or more NF instances to provide in response to the discovery request.

A wireless transmitting device is configured to: obtain a compressed-mode PPDU that includes one or more SC fields, where each SC field corresponds to one MU-MIMO group of the one or more MU-MIMO groups and is indicative of a spatial stream configuration for user devices of that MU-MIMO group; and transmit the PPDU to the user devices of the one or more MU-MIMO groups over a predetermined BW. Further, a user device is configured to: receive a compressed-mode PPDU from a wireless transmitting device; and decode the PPDU to obtain a SC field corresponding to the MU-MIMO group that the user device belongs to.

A wireless transmitting device is configured to: obtain a compressed-mode PPDU that includes one or more SC fields, where each SC field corresponds to one MU-MIMO group of the one or more MU-MIMO groups and is indicative of a spatial stream configuration for user devices of that MU-MIMO group; and transmit the PPDU to the user devices of the one or more MU-MIMO groups over a predetermined BW. Further, a user device is configured to: receive a compressed-mode PPDU from a wireless transmitting device; and decode the PPDU to obtain a SC field corresponding to the MU-MIMO group that the user device belongs to.

Embodiments of the present disclosure provide a sensing method and a terminal device, capable of satisfying sensing demands of New Radio-Vehicle to Everything (NR-V2X) in a resource selection process. The sensing method includes: obtaining, by a terminal device, configuration information, wherein the configuration information includes a set of periodicity values for periodic reservation allowed for a target resource pool and/or a periodicity value for sensing by the terminal device; and performing, by the terminal device, sensing based on the configuration information.

Embodiments of the present disclosure provide a sensing method and a terminal device, capable of satisfying sensing demands of New Radio-Vehicle to Everything (NR-V2X) in a resource selection process. The sensing method includes: obtaining, by a terminal device, configuration information, wherein the configuration information includes a set of periodicity values for periodic reservation allowed for a target resource pool and/or a periodicity value for sensing by the terminal device; and performing, by the terminal device, sensing based on the configuration information.

The present disclosure includes systems, devices, and methods that provide a control signaling transmission method. One example method includes: determining a resource subset used to transmit control signaling, where the resource subset is a part of a resource pool used to transmit the control signaling; and performing one of the following operations: determining a transmission location of the control signaling in the resource subset and sending the control signaling at the transmission location, or performing blind control signaling detection in the resource subset.

The present disclosure includes systems, devices, and methods that provide a control signaling transmission method. One example method includes: determining a resource subset used to transmit control signaling, where the resource subset is a part of a resource pool used to transmit the control signaling; and performing one of the following operations: determining a transmission location of the control signaling in the resource subset and sending the control signaling at the transmission location, or performing blind control signaling detection in the resource subset.

The disclosure relates to a 5G or 6G communication system for supporting a higher data transmission rate. A method performed by an apparatus of a wireless communication system is provided. The method includes receiving, from a base station, first information related to interference among a plurality of user equipments (UEs) that are to receive a resource allocation, second information related to a number of available resources, and third information related to a resource allocation reward associated with each of the plurality of user equipments (UEs), selecting a plurality of qubits based on the first information and the second information, and generating, based on the third information, resource allocation information derived from the plurality of qubits, where the resource allocation to the plurality of UEs is based on the resource allocation information.