A terminal according to an aspect of the present disclosure includes: a reception section that receives downlink control information for triggering feedback of a one-shot HARQ-ACK; and a control section that controls feedback of HARQ-ACKs each corresponding to one of a plurality of service types or HARQ-ACKs having different priorities by using different codebooks in a case where the feedback of the HARQ-ACK is performed on the basis of the downlink information.

According to an example embodiment, an example method may include determining, by a network node in a wireless network, whether a size of a data packet is greater than a threshold size; transmitting, by the network node, the data packet via a frequency interlace if the size of the data packet is less than or equal to the threshold size; transmitting, by the network node, the data packet via contiguous wideband frequency resources if the size of the data packet is greater than the threshold size.

Apparatuses, methods, and systems are disclosed for transmitting SL CSI using an uplink channel. One apparatus includes a transceiver that receives a first SL-CSI value from a RX UE via one of a plurality of unicast links. The apparatus includes a processor that generates a SL-CSI report comprising the first SL-CSI value, wherein the first SL-CSI value is tagged with an identifier that identifies the RX UE. The processor controls the transceiver to transmit the SL-CSI report using an uplink channel.

The present technology relates to a wireless communication apparatus and a wireless communication method that make it possible to achieve an improvement in the number of multiplexing on a non-orthogonal axis.

The wireless communication apparatus transmits a signal including information for setting of an occupancy period of a wireless transmission path on a basis of extraction processing time required for processing, which includes interference cancellation processing in communication using non-orthogonal multiplexing, to extract desired data from a received signal. The present technology is applicable to a wireless communication system.

A terminal includes: a receiving unit receiving single control information for scheduling a plurality of cells; and a control unit receiving a transport block from the plurality of cells, based on the control information, in which the control unit: receives different transport blocks in each of the plurality of cells; receives a same transport block in each of the plurality of cells; or receives a part of a transport block in each of the plurality of cells.

Embodiments of the present disclosure provide a solution for sensing sidelink resources. In a method for communication, in accordance with receiving, at a terminal device from a network device, a first higher layer parameter indicating that partial sensing is enabled for the terminal device, the terminal device determines a candidate resource for performing a sidelink transmission in a target slot. The terminal device determines, for the partial sensing, a sensing window with a configured time length before the target slot. The terminal device determines, in the sensing window, a set of slots based on the configured time length of the sensing window. The terminal device determines a reservation state of the candidate resource by monitoring the set of slots. With the embodiments of the present disclosure, a feasible partial sensing procedure is provided for a terminal device to perform a sidelink transmission in the 5G NR, and thus the performance of sidelink transmissions can be improved.

A communications method for determining a transmission scheme according to at least one temporal parameter includes providing a communication device, a first transceiver, and a second transceiver, acquiring the at least one temporal parameter, establishing a first link between the communication device and the first transceiver during a first time slot according to the at least one temporal parameter, and establishing a second link between the communication device and the second transceiver during a second time slot according to the at least one temporal parameter. The first time slot and the second time slot are non-overlapped.

Provided are an electronic device and a method for wireless communication, and a computer-readable storage medium. The electronic device comprises: a processing circuit configured to: determine that a physical layer problem occurs during transmission by a user equipment which uses a pre-configured resource in a pre-configured resource pool to execute the transmission; and determine, according to a transmission quality requirement of a data packet to be sent, the length of time during which the user equipment can continue using the pre-configured resource.

This application relates to a scheduling method, an apparatus, and a system. A first communications apparatus sends first signaling on a first resource, where the first signaling is used to indicate N communications apparatuses. The first communications apparatus sends second signaling on a second resource, where the second signaling is used to schedule the N communications apparatuses to send or receive first data, and the first resource has an association relationship with the second resource. In addition, the first resource has the association relationship with the second resource. In this case, a receive end of the first signaling and the second signaling may determine the second resource after determining the first resource, so that the second signaling is only detected on the second resource, and blind detection does not need to be performed on too many resources.

Methods, systems, and devices for wireless communication are described to support reducing conflicts with between scheduling request opportunities and downlink resources. A base station may configure a user equipment (UE) with a scheduling request periodicity and offset for identifying scheduling request opportunities. The UE and base station may apply the periodicity and the offset to a first subset of time periods of a set of multiple time periods, where the first subset of time periods may include scheduling request opportunities that do not overlap with resources allocated for downlink transmissions. Based on applying the offset and periodicity to the first subset of time periods, the UE may identify a scheduling request opportunity, in a first time period of the first subset, and may transmit a scheduling request to the base station via the scheduling request opportunity.