Provided are a wireless communication method and a device. The wireless communication method includes: determining a target uplink channel based on an overlapping situation of at least two types of uplink channels to be transmitted, if at least two types of uplink channels to be transmitted are overlapped, wherein the at least two uplink channels to be transmitted are respectively used for transmitting part or all of information carried by the at least two types of uplink channels; and transmitting the target uplink channel, wherein the target uplink channel is used for transmitting part or all of information carried by the at least two uplink channels to be transmitted. The at least two uplink channels to be transmitted are multiplexing channels of the at least two types of uplink channels respectively.

A gateway access method and an electronic device are provided. The gateway access method includes: determining a target ePDG based on a priority level of at least one pre-recorded evolved packet data gateway ePDG; and initiating an access procedure to the target ePDG based on pre-recorded address information; where the priority level includes a priority level that is determined based on access parameter information of the at least one ePDG; and the address information includes address information of the target ePDG.

Aspects relate to implementing a non-dropping rule for mini-slot based repetition of downlink channel data or control. In one example, cancelled repetition may be identified, non-cancelled remaining repetitions may be received, and acknowledgment feedback based on reception results may be generated. In another example, a plurality of time domain resource allocation (TDRA) candidate occasions may be identified where each occasion occurs within a different respective one of a plurality of mini-slots, each mini-slot carrying a different respective one of a plurality of downlink channel repetitions. A TDRA table may be maintained. The TDRA table may include TDRA entries such as location information of the plurality of TDRA candidate occasions associated with the plurality of downlink channel repetitions. The TDRA table may be maintained when at least one of the plurality of downlink channel repetitions is not decoded. A wireless communication device may refrain from dropping non-decoded downlink channel repetitions.

A method and a device in a node for wireless communications. A first receiver receives first information; and a first transmitter transmits a first signal in a first time-frequency resource block, the first signal carrying a second bit block; herein, a first bit block is used for generating the second bit block; the first bit block comprises a first bit sub-block and a second bit sub-block, the priority corresponding to the first bit sub-block being higher than that corresponding to the second bit sub-block; the number of REs in the first time-frequency resource block used for transmitting the second bit block is no greater than a first value, and the number of bits comprised in the first bit sub-block is used to determine the first value; the number of bits comprised in the first bit sub-block and the first information are used together to determine a second value.

This application discloses a communication method and apparatus. A first AMF device receives a first request message, where the first request message includes an identifier of a first network slice that a terminal requests to access and an identifier of a tracking area in which the terminal is located. When the first AMF device determines that the tracking area supports the first network slice, the first AMF device sends a response message, where the response message includes a first radio access selection priority index corresponding to the first network slice. The first radio access selection priority index is for selection of an access network device that supports the first network slice at the terminal. Even if an access network device currently accessed by the terminal does not support the first network slice, the terminal may re-access the access network device that supports the first network slice.

A communication method and a communications apparatus are disclosed to provide an implementation solution for measuring, in an idle state, a carrier. The method includes: initiating, in an idle state, measurement on one or more carriers when a volume of to-be-sent data exceeds a first threshold, or initiating measurement on one or more carriers when a paging message is received; and sending an obtained measurement result to a network device.

A communication method and a communications apparatus are disclosed to provide an implementation solution for measuring, in an idle state, a carrier. The method includes: initiating, in an idle state, measurement on one or more carriers when a volume of to-be-sent data exceeds a first threshold, or initiating measurement on one or more carriers when a paging message is received; and sending an obtained measurement result to a network device.

With advanced compute capabilities and growing convergence of wireless standards, there is requirement to run multiple wireless standards, e.g., 4G, 5G, and Wi-Fi, on a single hardware together. Typical solution includes reserving some computing resources for specific wireless standards. Such a resource strategy may not be optimized or efficient according to the real needs for various wireless standards. The present disclosure presents embodiments of using a unified resource controller to take multiple scheduling inputs across various wireless standards, allocate resources among a plurality of configurable processing units, and manage hardware components for data path accelerations including forward error correction, and signal processing implementation. The multiplexing multiple wireless technologies based on spectral utilization may improve the efficiency in power consumption and hardware resources utilization.

With advanced compute capabilities and growing convergence of wireless standards, there is requirement to run multiple wireless standards, e.g., 4G, 5G, and Wi-Fi, on a single hardware together. Typical solution includes reserving some computing resources for specific wireless standards. Such a resource strategy may not be optimized or efficient according to the real needs for various wireless standards. The present disclosure presents embodiments of using a unified resource controller to take multiple scheduling inputs across various wireless standards, allocate resources among a plurality of configurable processing units, and manage hardware components for data path accelerations including forward error correction, and signal processing implementation. The multiplexing multiple wireless technologies based on spectral utilization may improve the efficiency in power consumption and hardware resources utilization.

According to one configuration, a wireless network is shared amongst a hierarchal tier of users. The wireless network environment includes communication management hardware operative to receive notice of a first wireless channel allocated for use; the first wireless channel is allocated for use by the first wireless station and a second wireless station. During operation, the communication management hardware monitors use of the first wireless channel by one or more other wireless stations (such as including the second wireless station). Based on the monitored use, the controller controls wireless communications from the second wireless station.