Abstract: Apparatuses, methods, and systems are disclosed for SCell Beam Failure recovery. One apparatus includes a transceiver that communicates with a SCell in a wireless communication network. The apparatus includes a processor that receives a SR configuration from a wireless communication network, the SR configuration comprising a set of PUCCH resources, where the SR configuration corresponds to one or more logical channels. The processor detects that beam failure procedure has been triggered for the SCell. The processor triggers a scheduling request for SCell beam failure recovery in response to determining that there are no UL-SCH resources available for a new transmission for the transmission of a beam failure MAC CE. The processor transmits SR on the PUCCH resources of the SR configuration in response to triggering the scheduling request for SCell beam failure recovery.

Abstract: Apparatuses, methods, and systems are disclosed for indicating a sidelink resource conflict using a feedback channel. One apparatus includes a receiver that receives SCI from a peer UE on a first resource of a PSCCH, where the SCI contains information indicating future resources reserved for future transmissions. The apparatus includes a processor that determines whether there is a resource conflict, said resource conflict including an expected collision on the future resources. The apparatus includes a transmitter that transmits feedback to the peer UE on a feedback resource, where the feedback includes an indication of whether there is a resource conflict.

Abstract: Apparatuses, methods, and systems are disclosed for inter-UE coordination when using SL discontinuous reception (“DRX”). One apparatus includes a transceiver and a processor that determines a DRX configuration that is to be used towards a peer UE, where the DRX configuration includes an active time during which sidelink data is exchanged with the peer UE. The processor determines a set of resources for sidelink communication and identifies an intersection of the active time and the set of resources. The transceiver transmits to the peer UE an indication of the identified intersection of the active time and the set of resources.

Abstract: Apparatuses, methods, and systems for configuring resources corresponding to discontinuous reception. One method (600) includes receiving (602), at a user equipment, a sidelink grant from a network entity allocating sidelink resources. The method (600) includes determining (604) whether the sidelink resources allocated by the sidelink grant are within a discontinuous reception active time of the user equipment. Determining whether the sidelink resources allocated by the sidelink grant are within the discontinuous reception active time of the user equipment includes determining whether the allocated resources are within the discontinuous reception active time of any receiving user equipment that the user equipment has data available for transmission.

Abstract: Apparatuses, methods, and systems are disclosed for reporting power headroom. One apparatus includes a processor and a transceiver that transmits to a User Equipment (“UE”) a configuration for a transmission occasion for autonomous uplink (“AUL”) transmission on an unlicensed serving cell and receives a power headroom report (“PHR”) Medium Access Control (“MAC”) Control Element (“CE”) with an AUL transmission. The processor identifies timing information corresponding to the PHR, wherein the timing information indicates a time when power headroom information was generated, where receiving the PHR MAC CE includes receiving an indication of the timing information.

Abstract: Apparatuses, methods, and systems are disclosed for collecting MBS measurements in a communication network. One apparatus includes a processor and a transceiver that sends a first message to a communication device and receives a second message from the communication device. Here, the first message includes a configuration for logging MBS measurements and the second message includes a set of logged measurement results for at least one MBS service of interest. The processor controls MBS operation in a communication network based on the logged measurement results collected from the communication device.

Abstract: Apparatuses, methods, and systems are disclosed for configuring logical channel (“LCH”) mapping restriction for small-data transmission. One apparatus includes a transceiver that receives a configuration with LCH mapping restrictions for an LCH. The apparatus includes a processor applies a first set of LCH mapping restrictions for uplink transmissions when the first apparatus is in a Radio Resource Control (“RRC”) connected state and applies a second set of LCH mapping restrictions for uplink transmissions when the first apparatus is in a RRC inactive state, where the LCH mapping restrictions of the first set are different than the LCH mapping restrictions of the second set.

Abstract: Apparatuses, methods, and systems are disclosed for determining data available for transmission. One method includes associating a packet data convergence protocol entity with a first radio link control entity and a second radio link control entity belonging to two different cell groups. The method includes determining an amount of data available for transmission, the amount of data available for transmission including packet data convergence protocol data and radio link control data pending for initial transmission in the first radio link control entity and the second radio link control entity. The method includes comparing the amount of data available for transmission with a threshold. The method includes submitting the packet data convergence protocol data to a first radio link control entity in response to the amount of data available for transmission being below the threshold.

Abstract: Methods, apparatuses, and systems are disclosed for managing hybrid automatic repeat request buffers for sidelink configured grants. A method (400) includes transmitting (405) a transport block (“TB”) from a transmitting user equipment (“UE”) device to a receiving UE device using configured grant resources during a period of a sidelink configured grant. A method (400) includes receiving (410), at the transmitting UE device during the period, feedback from the receiving UE device over a physical sidelink feedback channel (“PSFCH”) indicating whether the TB was successfully received. A method (400) includes, in response to the feedback indicating that the receiving UE device successfully received the TB, stopping (415) transmissions of the TB on subsequent configured grant resources of the sidelink configured grant within the same period.

Abstract: Apparatuses, methods, and systems are disclosed for remapping traffic between network slices during handover. One apparatus includes a processor and a transceiver that receives a first message indicating that a first connection is not supported in a target RAN. Here, the first connection is established with a first network slice and the first message indicates that buffering-and-forwarding of data traffic of the first connection is supported. The transceiver transmits a request to establish a second connection with a second network slice over the Target RAN and receives a second message from the Target RAN for establishing the second connection, where the second message includes an identifier of the first connection. The processor communicates at least one buffered data packet of the first connection over the second connection.

Abstract: A WUS monitoring configuration can be received (1210) from a network. A DRX mode configuration comprising at least an active period can be received (1220). At least one CSI reporting configuration can be received (1230). The at least one CSI reporting configuration can configure transmission occasions for transmission of at least one CSI report to the network outside the active period. A time offset configuration for CSI transmission outside the active period can be received (1240). A CSI report can be transmitted (1250) on a transmission occasion of the configured transmission occasions. The transmission occasion can be within the configured time offset from a WUS monitoring occasion. The WUS monitoring occasion can be outside the active period.

Abstract: Apparatuses, methods, and systems are disclosed for determining a priority order based on uplink transmission parameters. One apparatus includes a processor that: indicates uplink transmission parameters to a medium access control layer, wherein the uplink transmission parameters correspond to an uplink grant, the uplink transmission parameters comprise an indication of a numerology and an uplink transmission duration, and the numerology comprises a subcarrier spacing; and assigns, by the medium access control layer, resources allocated by the uplink grant to the logical channels based on the uplink transmission parameters and a logical channel priority of the plurality of logical channels, wherein each logical channel of the plurality of logical channels is configured with a set of numerologies allowed by the respective logical channel, a maximum uplink transmission duration, and information indicating whether a data of the respective logical channel is allowed to be transmitted on a configured grant.

Abstract: A transceiver can transmit a broadcasted system information message including a restricted operator service access indication from a serving cell of a network. A controller can perform a radio resource control connection establishment procedure to receive an attach request message.

Abstract: Apparatuses, methods, and systems are disclosed for downlink assignments for downlink control channels. One method includes determining a third set of downlink control channel monitoring occasions that comprises first downlink control channel monitoring occasions and second downlink control channel monitoring occasions, and associated search spaces correspond to two different control resource sets comprising a first control resource set and a second control resource set, wherein: demodulation reference signal ports of the first control resource set are quasi-collocated with a first set of reference signals; demodulation reference signal ports of the second control resource set are quasi-collocated with a second set of reference signals. The method includes monitoring one or more downlink control channel candidates in at least one slot of the third set of monitoring occasions if the one or more downlink control channel candidates carry the same downlink control information.

Abstract: Apparatuses, methods, and systems are disclosed for transport block transmission. One method includes determining a failure of a listen-before-talk procedure for transmission of a transport block on a configured uplink grant at a first transmission opportunity associated with a hybrid automatic repeat request process. The method includes, in response to determining the failure of the listen-before-talk procedure, not transmitting the transport block on the configured uplink grant at the first transmission opportunity corresponding to the listen-before-talk procedure. The method includes autonomously triggering transmission of the transport block in a second transmission opportunity using the hybrid automatic repeat request process, wherein autonomously triggering the transmission comprises triggering the transmission without receiving network signaling for the transmission and, the second transmission opportunity occurs after the first transmission opportunity.

Abstract: Apparatuses, methods, and systems are disclosed for sidelink HARQ operation. One apparatus includes a memory coupled to a processor, where the processor is configured to cause the second apparatus to receive a SL grant for a SL transmission using SL resources, the SL grant indicating a first HARQ process identified by a first HARQ process identifier, and to select a second SL HARQ process identified by a second SL HARQ process identifier for the SL transmission using the SL resources. The processor is configured to cause the second apparatus to transmit SCI containing the second SL HARQ process identifier and to perform the SL transmission using the SL resources.

Abstract: Apparatuses, methods, and systems are disclosed for providing fallback assistance information to a RAN node. One apparatus includes a memory coupled to a processor, the processor configured to cause the apparatus to: receive a service request indicating a service for fallback, the service request associated with a UE, where the service for fallback corresponds to a different RAT or a different system generation; and transmit, to a network entity, an indication of a fallback requirement or a target system, or both, based on a service type associated with the service request or a network configuration, where the service type corresponds to a different RAT or a different system generation, where a handover or redirection is performed based on the transmitted indication.

Abstract: Apparatuses, methods, and systems are disclosed for activating a bandwidth part. One apparatus includes a transceiver that receives a control element from a base unit associated with an active serving cell. The first apparatus includes a processor that determines an ‘activation/deactivation’ status of a set of BWPs configured in the active serving cell using the control element. The processor selectively activates a first BWP from the set of BWPs in the active serving cell based on the determined activation/deactivation status.

Abstract: Apparatuses, methods, and systems are disclosed for random access skip configuration. One method includes receiving a handover command message from a first cell, wherein: the handover command message includes first information that indicates a configuration of a second cell, random access channel resources on the second cell, and a first reference signals associated with the second cell; each of the first reference signals is associated with a random access channel resource; second information indicates skip configurations and second reference signals are associated with the second cell; and each of the second reference signals is associated with a random access skip configuration. The method includes receiving a first set of downlink reference signals and a second set of downlink reference signals. The method includes, selecting a first downlink reference signal and determining whether to perform a random access procedure.

Abstract: A method and apparatus are provided, in which a service link path delay relative to a first leg of a communication path of a communication between the user equipment and a network entity via a relay entity is estimated (602), where the first leg corresponds to a portion of the communication path between the user equipment and the relay entity. A feeder link path delay relative to a second leg of the communication path is determined (604), where the second leg corresponds to a portion of the communication path between the relay entity and the network entity, based upon at least a received signaling indication. A timing advance value is calculated (606), based upon the service link path delay and the feeder link path delay. An uplink transmission timing of the user equipment is adjusted (608), based upon the calculated timing advance value.