The present disclosure selects a node generating a periodic time slot request in a network to construct a set of periodic time slot request generation nodes, and constructs a time slot request cycle set; selects a node generating an aperiodic time slot request in the network to construct a set of aperiodic time slot request generation nodes, and constructs a time set of the aperiodic time slot request generation nodes; calculates a time slot contention scheduling parameter of each node in the set of the periodic time slot request generation nodes; and if no aperiodic time slot request arrives, allocates a time slot to each time slot requesting node during periodic time slot scheduling; or if an aperiodic time slot request, namely, a sporadic time slot request, arrives, performs rescheduling through hybrid time slot scheduling based on arrival time of the aperiodic time slot request.

Certain aspects of the present disclosure provide techniques for group semi-persistent scheduling (SPS) for path diversity. A method that may be performed by a node includes configuring one or more groups of user equipments (UEs) with one or more SPS resources. The node sends a downlink control information (DCI) to activate one of the SPS resources for one of the groups of UEs and transmits data to the group of UEs using the activated SPS resource. A first UE may receive data from the node using the activated SPS resource and retransmit the data to the second UE. The first helping UE and the second targeted UE may be identified based on the higher layer configuration with the SPS resources, based on information in the DCI, and/or based on information sent with the data.

Methods, systems, and devices for wireless communications are described. A user equipment (UE) may receive signaling from a base station including a configuration for multiple transmission time intervals (TTIs) including uplink symbols, downlink symbols, flexible symbols, or a combination. The UE may receive a grant scheduling one or more repetitions of an uplink shared channel carrying an uplink random access message from the base station. The UE may determine available TTIs for the repetitions based on a pre-TTI evaluation of symbols according to a rule that defines types of symbols available for the uplink shared channel. The UE may transmit the repetitions on the available TTIs according to the rule.

A method (1200) by a wireless device (110) includes transmitting (1202), to a network node (160), a request for a preconfigured uplink resource, PUR, configuration. The wireless device 110 receives the PUR configuration from the network node, and the PUR configuration comprising time and/or frequency resources for transmitting on an uplink. The wireless device determines a PUR start time based on a value associated with a hyper system frame number (HSFN), a HSFN cycle, and/or a subframe number. The PUR start time measured relative to a time associated with the PUR configuration.

Certain aspects of the present disclosure provide techniques for staggering clients based on wireless network information. An example method generally includes obtaining, by a client from a modem, information associated with a wireless communication network. The method also includes transmitting, from the client to the server, at an application level, a first message including the information. The method further includes receiving, by the client from the server, data at a time determined based on the information.

Aspects of the present disclosure include methods, apparatuses, and computer readable media for determining a connected mode discontinuous reception (C-DRX) short cycle value, transmitting a C-DRX short cycle request to a base station, the C-DRX short cycle request including the C-DRX short cycle value, receiving a first confirmation indicating the base station accepting the C-DRX short cycle value associated with the C-DRX short cycle request, determining an averaging window value based on the C-DRX short cycle value, transmitting an averaging window request to the base station, the averaging window request including the averaging window value, receiving a second confirmation indicating the base station accepting the averaging window value associated with the averaging window request, and communicating with the base station based on the C-DRX short cycle value and the averaging window value.

In some aspects, multi-slot transport block (TB) configurations for communicating data between wireless devices, such as between a base station and a user equipment (UE), in a wireless communication system are described. Some examples of multi-slot configurations enable the communication of large payloads. For example, an application of a wireless device may jointly process data from a large file or other large set of packets. In such examples, the wireless device transmitting the large file may utilize a multi-slot TB including multiple TB segments corresponding to respective slots of a transmission. Similarly, a wireless device receiving the large file may utilize the multi-slot TB configuration for receiving the data.

There is provided a method performed by a wireless device for reconfiguring semi-persistent scheduling. The wireless device is configured with a first semi-persistent scheduling configuration for uplink or downlink transmissions. The method comprises: while semi-persistent scheduling is active according to the first semi-persistent scheduling configuration such that the wireless device is configured with periodic transmission or reception opportunities, receiving a semi-persistent scheduling reconfiguration message from a network node, the semi-persistent scheduling reconfiguration message comprising an instruction to reconfigure the wireless device to a second semi-persistent scheduling configuration for uplink or downlink transmissions; and determining one or more transmission or reception opportunities associated with the second semi-persistent scheduling configuration based on a semi-persistent scheduling activation time according to the second semi-persistent scheduling configuration.

Embodiments of the disclosure provide a method for transmitting data in a wireless communication network. A network device sends first configuration signaling to a terminal. The first configuration signaling is used to determine a first resource occupied by first data in a first slot. The network device also sends third configuration signaling to the terminal. The third configuration signaling is used to determine a second resource occupied by second data in the first slot and the third configuration signaling has a different type of configuration signaling from the first configuration signaling. When at least one time domain symbol in the second resource is located in the first resource in the first slot, the network device further determines, based on a preset policy, data transmitted in the first slot.

Various aspects of the present disclosure generally relate to wireless communication. In some aspects, a user equipment (UE) may determine a receive time difference (RTD) between a first base station and a second base station based at least in part on the UE using a common beam to receive transmissions from the first base station and the second base station. The UE may transmit information indicating the RTD between the first base station and the second base station, wherein the transmissions from the first base station and the second base station may be scheduled based at least in part on the RTD between the first base station and the second base station. Numerous other aspects are provided.