A signal receiving method, a signal transmission method, UE, and a network device are provided. The signal receiving method includes: determining a frequency domain position and/or spatial domain position for receiving a signal, wherein the frequency domain position includes one or more of a plurality of frequency domain positions, and the spatial domain position includes one or more of a plurality of spatial domain positions; and receiving the signal at the determined frequency domain position and/or spatial domain position. The signal is one or more of a pre-indication signal, information carried in a PDCCH, and a paging message.

A signal receiving method, a signal transmission method, UE, and a network device are provided. The signal receiving method includes: determining a frequency domain position and/or spatial domain position for receiving a signal, wherein the frequency domain position includes one or more of a plurality of frequency domain positions, and the spatial domain position includes one or more of a plurality of spatial domain positions; and receiving the signal at the determined frequency domain position and/or spatial domain position. The signal is one or more of a pre-indication signal, information carried in a PDCCH, and a paging message.

A data transmitting method, a data receiving method, a terminal device, and a network device are provided. The method includes: determining, by a terminal device, a target resource based on a time index and/or configuration information; and transmitting, by the terminal device, data to a network device on the target resource. The terminal device can control resource granularity of the target resource to meet transmission requirements of the terminal device, and can further avoid an actual data transmission process from occurring only on a same frequency domain resource and can further improve the frequency diversity gain in the non-slot transmission. In addition, randomness of interference can be enhanced as much as possible to avoid a same user from always or frequently being in conflict, so when a DMRS of the terminal device conflicts with that of other terminals, performance of user identification can be effectively improved.

The embodiments of the present disclosure provide a data transmission method and apparatus, and a terminal. The method includes a terminal sending a first preamble to a base station and receiving a first random access response message sent by the base station. The method further includes the terminal acquiring an uplink transmission resource based on the first random access response message and transmitting first uplink data on the uplink transmission resource. The size of the uplink transmission resource supports the transmission of the first uplink data.

The embodiments of the present disclosure provide a data transmission method and apparatus, and a terminal. The method includes a terminal sending a first preamble to a base station and receiving a first random access response message sent by the base station. The method further includes the terminal acquiring an uplink transmission resource based on the first random access response message and transmitting first uplink data on the uplink transmission resource. The size of the uplink transmission resource supports the transmission of the first uplink data.

Techniques discussed herein can facilitate SON (Self Organizing Network) functions for 5G (Fifth Generation) NR (New Radio) systems. One example embodiment comprises an apparatus configured to be employed in a SON (Self Organizing Network) function, comprising: a memory interface; and processing circuitry configured to: collect one or more performance measurements associated with at least one of a RAN (Radio Access Network) or CN (Core Network); analyze the one or more performance measurements; and generate one or more actions to control the behavior of at least one of the RAN or the CN, based on the analyzing of the one or more performance measurements.

An apparatus is provided in a communications device. The apparatus comprises at least one processor and at least one memory including computer code for one or more programs. The at least one memory and the computer code are configured, with the at least one processor, to cause the apparatus to determine that at least one of a plurality of logical channels configured for packet duplication is to be deactivated; and determine an allocation of one or more cells associated with the at least one deactivated logical channel to one or more active logical channels of said plurality of logical channels configured for packet duplication.

A method, a device, and a non-transitory storage medium are described in which a polymorphic algorithm-based network slice orchestrator service is provided. The service may manage network slices based on radio access network performance metrics, core network performance metrics, network slice performance metrics, a machine learning framework, and polymorphic algorithms. The service may be applied to a multi-tier network. The service may include management of a data network access point of the network slice on a per-tier basis.

A method, a device, and a non-transitory storage medium are described in which a polymorphic algorithm-based network slice orchestrator service is provided. The service may manage network slices based on radio access network performance metrics, core network performance metrics, network slice performance metrics, a machine learning framework, and polymorphic algorithms. The service may be applied to a multi-tier network. The service may include management of a data network access point of the network slice on a per-tier basis.

A knowledge base of cell information can be built and made available to one or more mobile devices. A mobile device with access to this cell information may proactively perform a radio signal scan at a frequency of an expected cell(s) that is/are indicated in the cell information (e.g., if the expected cell is associated with a serving cell and/or with a geolocation that corresponds to the current Global Positioning System (GPS) location of the mobile device). After performing the radio signal scan, the mobile device may store measurement information (e.g., signal strength) about the expected cell(s) in local memory of the mobile device, and, upon receiving an instruction from the serving cell, the mobile device may access the stored measurement information from its local memory, and may send the measurement information to the requesting serving cell.