Methods, systems, and storage media are described for multi-transmission time interval (TTI) physical uplink shared channel (PUSCH) transmissions. In particular, some embodiments relate to downlink control information (DCI) enhancements to support dynamic switching between single-TTI scheduling and multi-TTI scheduling. Other embodiments may be described and/or claimed.

Provided are a method for paging, a network device, and a terminal device. The method for paging comprises: a network device determining a target synchronization signal block (SSB) in a plurality of SSBs of a current bandwidth carrier; and the network device sending a paging message of the terminal device to the terminal device at a frequency domain location where the target SSB is located. In embodiments of the present invention, a target SSB is determined in a plurality of SSBs of a current bandwidth carrier, such that a network device only needs to send a paging message of a terminal device to the terminal device at a frequency domain location where the target SSB is located, effectively reducing load on the network side in the sending of paging messages.

A method and user equipment are provided. The method includes receiving a scheduling of an uplink (UL) signal on a target cell that collides with a UL signal on a source cell, determining a cancellation time for dropping the UL signal on the source cell, and dropping at least a portion of the UL signal on the source cell based on the determined cancellation time.

This application provides a data transmission method. In the method, a first access network device and a second access network device establish a data radio bearer (DRB)-based tunnel and a session-based tunnel. The second access network device sends a Packet Data Convergence Protocol (PDCP) layer data packet to the first access network device via the DRB-based tunnel; and the second access network device sends a Service Data Adaptation Protocol (SDAP) layer data packet to the first access network device via the session-based tunnel.

Techniques for content inspection in a communication network, including detecting a packet in transit between a first and second endpoint, determining that content of the packet fails a content check, modifying a payload containing the content, adjusting a sequence number to account for the modification, and injecting a response message into a corresponding stream in an opposite direction. The response message may contain information relating to a reason for the rejection.

Apparatuses, systems, and methods for implied sequence numbering of transactions in a processor-based system. The processor-based system includes a transmit circuit configured to generate an implied sequence number for each entry to be transmitted as a packet. The transmit circuit is configured to generate a packet to be transmitted based on an entry, wherein the packet including the payload information and the transmit check value based on the implied sequence number and associated with the entry. In this manner, including an individual sequence number with every transmitted packet may be reduced or avoided to reduce or avoid consuming bandwidth on the communications interface, as the bits used by the sequence number could ordinarily be used for data transmission instead. A receiver circuit is configured to receive the transmitted packet including the payload and the transmit check value, wherein the transmit check value is based on the transmit sequence number.

This application provides an acknowledgment packet transmission method and a communications device. The method includes: receiving, by a first device, data sent by a second device; sending, by the first device, the acknowledgment packet to the second device, where the acknowledgment packet includes an acknowledgment field, the acknowledgment field carries data lengths of K groups of data packets, and the data lengths vary with a data amount included in each group of data packets received/lost by the first device.

A method for determining a physical sidelink feedback channel resource and an apparatus are provided. The method includes: a first terminal device sends multicast information to at least two second terminal devices. The first terminal device determines, based on a total quantity of terminal devices in a multicast group and a resource group of physical sidelink feedback channel resources, a physical sidelink feedback channel resource corresponding to each second terminal device. The first terminal device receives, based on the physical sidelink feedback channel resource corresponding to each second terminal device, feedback information sent by each of the at least two second terminal devices. According to the foregoing method, physical sidelink feedback channel resources can be allocated to the terminal devices in the multicast group.

A method for transmitting a hybrid automatic repeat request feedback, and a communication device are provided. The method includes: generating a reception feedback frame including a reception feedback of a block in a data frame based on a reception status of the block of the data frame transmitted in blocks; and sending the reception feedback frame.

This disclosure relates to transmitting multicast information over a network, such as a wireless local area network (WLAN). A source device may transmit a multicast and a request for feedback to a plurality of sink devices. The sink devices may transmit feedback based on whether they successfully decoded the multicast. The source device may retransmit the multicast (or a portion thereof) based on the feedback.