A wireless device receives a release message indicating a small data transmission (SDT) procedure, of a cell, for an inactive state of the wireless device and indicating a downlink reference signal (RS), of a plurality of downlink RSs of the cell, associated with the SDT procedure. The wireless device initiates, during the SDT procedure, a beam failure detection and recovery procedure on the cell based on a measurement quantity of the downlink RS compared with a first threshold, and based on a cell measurement quantity, of one or more downlink RSs of the plurality downlink RSs, compared with a second threshold.

A wireless device receives a release message indicating a small data transmission (SDT) procedure, of a cell, for an inactive state of the wireless device and indicating a downlink reference signal (RS), of a plurality of downlink RSs of the cell, associated with the SDT procedure. The wireless device initiates, during the SDT procedure, a beam failure detection and recovery procedure on the cell based on a measurement quantity of the downlink RS compared with a first threshold, and based on a cell measurement quantity, of one or more downlink RSs of the plurality downlink RSs, compared with a second threshold.

A radio access network (RAN) intelligent controller (RIC) and corresponding method may be implemented within RAN and in next-generation cellular networks to improve performance. The RIC comprises an interface to a RAN and further comprises a data-driven logic unit. The data-driven logic unit (i) produces, based on data received from the RAN via the interface, a representation describing a state of the RAN and (ii) based on the representation describing the state, instructs an action associated with at least one network element. The interface transmits a message based on the action instructed. The message is to be routed to the at least one network element. The representation is based on a context of the RAN. The message transmitted enabling re-configuration of the at least one network element. The re-configuration improves performance of the at least one network element within the context.

A radio access network (RAN) intelligent controller (RIC) and corresponding method may be implemented within RAN and in next-generation cellular networks to improve performance. The RIC comprises an interface to a RAN and further comprises a data-driven logic unit. The data-driven logic unit (i) produces, based on data received from the RAN via the interface, a representation describing a state of the RAN and (ii) based on the representation describing the state, instructs an action associated with at least one network element. The interface transmits a message based on the action instructed. The message is to be routed to the at least one network element. The representation is based on a context of the RAN. The message transmitted enabling re-configuration of the at least one network element. The re-configuration improves performance of the at least one network element within the context.

Procedures for using a transmission configuration indication (TCI) state in wireless communications are described. A base station may send one or more configuration parameters indicating a plurality of cells to be updated with a same TCI state. A wireless device may perform, via the plurality of cells and using one or more parameters associated with the TCI state, at least one of transmission or reception.

Procedures for using a transmission configuration indication (TCI) state in wireless communications are described. A base station may send one or more configuration parameters indicating a plurality of cells to be updated with a same TCI state. A wireless device may perform, via the plurality of cells and using one or more parameters associated with the TCI state, at least one of transmission or reception.

A method for Channel State Information (CSI) reporting includes a User Equipment (UE) receiving a Channel State Information (CSI) reporting configuration from a base station (BS) on a first Bandwidth Part (BWP), receiving a first BWP switch indication from the BS on the first BWP, switching an active BWP of the UE from the first BWP to a second BWP, reserving the CSI reporting configuration after switching the active BWP, receiving a second BWP switch indication on the second BWP or a third BWP after switching the active BWP, switching the active BWP back to the first BWP, and automatically sending a CSI report based on the CSI reporting configuration without receiving any CSI reporting activation command from the BS after switching the active BWP back to the first BWP.

Embodiments herein relate to, e.g., a method performed by a communication node for controlling one or more communication parameters of a channel between a first communication device and a second communication device in a wireless communication network. The communication node, upon obtaining an indication of a channel quality of the channel to the second communication device, uses a correction value and the indication when determining the one or more communication parameters. The correction value is based on a decoding success of one or more previous transmissions, which one or more previous transmissions are based on an obtained previous indication of a previous channel quality from the second communication device, and wherein a change of the correction value relative a previous correction value is limited.

Embodiments herein relate to, e.g., a method performed by a communication node for controlling one or more communication parameters of a channel between a first communication device and a second communication device in a wireless communication network. The communication node, upon obtaining an indication of a channel quality of the channel to the second communication device, uses a correction value and the indication when determining the one or more communication parameters. The correction value is based on a decoding success of one or more previous transmissions, which one or more previous transmissions are based on an obtained previous indication of a previous channel quality from the second communication device, and wherein a change of the correction value relative a previous correction value is limited.

A method for network control and related products are provided, which are applied to electronic device. The electronic device includes a first network module and a second network module. The first network module is configured to be connected with a first WiFi network, a second WiFi network, or the both. A target frequency band at which the first network module interferes with the second network module is determined on condition that the first network module is connected with both the first WiFi network and the second WiFi network, when the second network module is enabled. A target WiFi network interface corresponding to the target frequency band is released, where the target WiFi network interface is at least one of following: a first WiFi network interface for a first WiFi network or a second WiFi network interface for a second WiFi network. Network connection is performed through the second network module.