Technology for a user equipment (UE) using a self-contained scheduling resource to communicate with an eNodeB within a wireless communication network is disclosed. The UE can select, at the UE, a selected eNodeB transmission (Tx) beam and a selected UE reception (Rx) beam based on a highest power beamforming reference signal (BRS) received power (BRS-RP). The UE can signal a transceiver of the UE to transmit to the eNodeB a scheduling request (SR), using the selected Rx beam, on a scheduling request (SR) resource in a self-contained subframe according to a time and frequency location of the selected eNodeB Tx beam. The UE can process an advanced physical downlink control channel (xPDCCH), received from the eNodeB, for an uplink (UL) grant using the selected UE RX beam.

A wireless transmitting device includes a receiving circuit configured to receive a reception frame from another device, and a transmitting circuit configured to transmit a broadcast transmission frame while the receiving circuit is not receiving the reception frame, and controls the transmitting circuit to delay transmission of the broadcast transmission frame for a waiting period that starts from an end of reception of the reception frame according to a frame type of the transmission frame, including a broadcast frame, a unicast frame, and a reception acknowledgement response frame, wherein the waiting period for the broadcast frame is shorter than the waiting period for the unicast frame and longer than the waiting period for the reception acknowledgement response frame.

A method includes obtaining a first message from a client computing device, the first message including a first value indicating a change in a resource utilization. The method also includes obtaining a sequence of previous values associated with previous resource utilizations. The method also includes determining a predicted schedule of values for a field of a record indicating resource use using a neural network based on the first value and the sequence of previous values. The method also includes determining whether a set of alert criteria is satisfied based on the predicted schedule of values. The method also includes sending a second message to the client computing device in response to a determination that the set of alert criteria is satisfied.

Embodiments of the present application disclose a method for transmitting data, a terminal device, and a network device, where the method includes: receiving, by a terminal device, first indication information sent by a network device, where the first indication information indicates that data is capable of being transmitted on a semi-persistent scheduling resource within a first bandwidth part BWP of at least one BWP and where the first BWP is in an active state; determining, by the terminal device, the semi-persistent scheduling resource within the first BWP according to the first indication information; and performing, by the terminal device, data transmission on the semi-persistent scheduling resource within the first BWP with the network device. The method, the terminal device and the network device in the embodiments of the present application are beneficial to improving an accuracy of data transmission.

Control information may be used to schedule communications between a wireless device and a base station. The wireless device may monitor control channels associated with one or more cells to receive the control information.

An embodiment of the present disclosure provides a method for a first apparatus to perform long-term evolution (LTE) sidelink (SL) communication through downlink control information (DCI). The method includes: receiving DCI from a new radio (NR) base station through a physical downlink control channel (PDCCH); obtaining a first timing offset based on the DCI; and performing LTE SL communication based on the first timing offset.

Aspects relate to a method of wireless communication at a user equipment (UE). The method includes receiving a set of one or more transmissions in an assigned bandwidth part (BWP) of a set of bandwidth parts (BWPs) from a base station (BS), wherein the set of one or more transmissions includes data addressed to the UE; after missing a reception of a second set of one or more transmissions from the BS following the set, receiving a third set of one or more transmissions in the assigned BWP from the BS, wherein the third set does not include data addressed to the UE; and determining whether a fourth set of one or more transmissions from the BS in one or more unassigned BWPs of the set of BWPs includes data addressed to the UE in response to the third set not including data addressed to the UE.

There are disclosed techniques for puncturing and/or overlaying transmission in case of necessity of on-demand (e.g., urgent) commutations. In particular, transceivers, user equipments, systems, methods and non-transitory storage units are disclosed. For example, there is disclosed a transceiver of a wireless communication network, wherein the transceiver is configured to operate in a puncturing mode by puncturing a downlink, DL, transmission of payload information in a channel originally allocated to the DL transmission of payload information, to obtain, within the originally allocated channel for the DL transmission of payload information, a DL free area for an uplink, UL, transmission of a user equipment, UE, of the wireless communication network.

The present invention relates to a system that limits resources (e.g. reduces energy consumption and/or peak-to average power ratio) of a wireless communication device by limiting communication resources for the communication device from a network function of the cellular core network.

Wireless communications may use one or more devices for transmission and/or reception that may lead to potentially harmful exposure. One or more safety measures may be used for wireless communication devices, such as maximum power exposure (MPE) reporting and/or related operations. A time window may be used to detect a quantity of exposure instances. A message may be sent indicating exposure, for example, based on a quantity of exposure events during the time window satisfying a threshold.