The apparatus may be configured to receive a first indication of a CFR associated with at least one of an MCCH or an MTCH for a plurality of RedCap UEs in one of an inactive or idle state supporting a first capability having a first maximum bandwidth that is different from a second capability having a second maximum bandwidth that is greater than the first maximum bandwidth. The apparatus may also be configured to monitor the CFR indicated in the first indication for at least one of broadcast traffic or multicast traffic. The apparatus may be configured to output, for transmission to the plurality of RedCap UEs, the first indication and output, for transmission to the plurality of RedCap UEs, at least one of an MCCH communication or an MTCH communication via the CFR indicated in the first indication for at least one of broadcast traffic or multicast traffic.

The apparatus may be configured to receive a first indication of a CFR associated with at least one of an MCCH or an MTCH for a plurality of RedCap UEs in one of an inactive or idle state supporting a first capability having a first maximum bandwidth that is different from a second capability having a second maximum bandwidth that is greater than the first maximum bandwidth. The apparatus may also be configured to monitor the CFR indicated in the first indication for at least one of broadcast traffic or multicast traffic. The apparatus may be configured to output, for transmission to the plurality of RedCap UEs, the first indication and output, for transmission to the plurality of RedCap UEs, at least one of an MCCH communication or an MTCH communication via the CFR indicated in the first indication for at least one of broadcast traffic or multicast traffic.

A transmit network node (14, 20) is configured for use in a wireless communication network (10). The transmit network node (14, 20) tunnels packets (18) from the transmit network node (14, 20) to a receive network node (20, 14) in the wireless communication network (10). The transmit network node (14, 20) also transmits, to the receive network node (20, 14), signaling (26) that indicates which tunneled packets (18) carry application layer data from the same application layer packet (16), how many tunneled packets (18) carry application layer data from the same application layer packet (16), and/or a size of an application layer packet (16). Based on the signaling (26), the receive network node (20, 14) in some embodiments schedules transmission of the tunneled packets (18) from the receive network node (20, 14) and/or allocates radio resources for transmission of the tunneled packets (18) from the receive network node (20, 14) towards a wireless device (12) served by the receive network node (20, 14).

A transmit network node (14, 20) is configured for use in a wireless communication network (10). The transmit network node (14, 20) tunnels packets (18) from the transmit network node (14, 20) to a receive network node (20, 14) in the wireless communication network (10). The transmit network node (14, 20) also transmits, to the receive network node (20, 14), signaling (26) that indicates which tunneled packets (18) carry application layer data from the same application layer packet (16), how many tunneled packets (18) carry application layer data from the same application layer packet (16), and/or a size of an application layer packet (16). Based on the signaling (26), the receive network node (20, 14) in some embodiments schedules transmission of the tunneled packets (18) from the receive network node (20, 14) and/or allocates radio resources for transmission of the tunneled packets (18) from the receive network node (20, 14) towards a wireless device (12) served by the receive network node (20, 14).

Various embodiments comprise a wireless communication network to proactively notify user devices in response to uplink data congestion. The wireless communication network comprises an access node and a wireless user device. The access node wirelessly exchanges user data with a wireless user device and exchanges the user data with a network user plane. The access node detects a data queue for uplink user data transferred by the wireless user device and indicates the data queue to the wireless user device. The wireless user device receives the indication and schedules additional uplink data transmissions based on a data priority. The access node wirelessly exchanges additional user data with the wireless user device and exchanges the additional user data with the network user plane.

Various embodiments comprise a wireless communication network to proactively notify user devices in response to uplink data congestion. The wireless communication network comprises an access node and a wireless user device. The access node wirelessly exchanges user data with a wireless user device and exchanges the user data with a network user plane. The access node detects a data queue for uplink user data transferred by the wireless user device and indicates the data queue to the wireless user device. The wireless user device receives the indication and schedules additional uplink data transmissions based on a data priority. The access node wirelessly exchanges additional user data with the wireless user device and exchanges the additional user data with the network user plane.

A method, system and apparatus are disclosed. A network node configured to communicate with a wireless device (WD) is described. The WD corresponds to a vehicle, and the network node comprises processing circuitry configured to predict a vehicle maneuver, where the prediction is based at least in part on a learning process associated with vehicle data; and schedule a resource usable at least by the WD. The scheduling is based on the predicted vehicle maneuver.

Presented are systems and methods for carrier phase positioning. A wireless communication device may receive configuration information about a reference signal for positioning from a wireless communication node. The wireless communication device may measure the reference signal for positioning. The wireless communication device may send a report including a measurement result of the reference signal for positioning to a network.

Presented are systems and methods for carrier phase positioning. A wireless communication device may receive configuration information about a reference signal for positioning from a wireless communication node. The wireless communication device may measure the reference signal for positioning. The wireless communication device may send a report including a measurement result of the reference signal for positioning to a network.

The electronic device includes: a communication circuit for transmitting or receiving data to or from a network through cellular communication; an application processor; and a communication processor to: receive, from the application processor, information about one specified application and a first delay time for the specified application to perform one specified service; determine whether to identify an average of delay times while transmitting data related to the specified service, based on comparing a delay time occurring while transmitting the data related to the specified service through at least one data radio bearer (DRB) with a first time determined based on the first delay time; identify the average of the delay times on the basis of determining to identify the average; and determine whether to transmit a measurement report including the average of the delay times and information about the DRB, based on whether the average satisfies a specified condition.