Methods, systems, and devices for determining a subset of user devices from among a complete set of user devices based on a set of received information, i.e., attributes associated with a photograph or user device that transmitted the photograph and attributes, where the disposition of the information may be used to determine the subset and then perform facial recognition on the subset of user associated photographs in order to accurately identify each user or users present in the photograph.

Apparatuses, systems, and methods for a user equipment device (UE) to perform multiple TTI PUSCH transmissions in a wireless communication system as well as code block groups (CBGs) based retransmissions operations. A UE may perform radio resource control (RRC) signaling with a network entity to configure a data structure that may include one or more sets of physical uplink shared channel (PUSCH) transmission configurations, where each set of PUSCH transmission configurations span multiple TTIs. The wireless device may be configured to receive, from the network entity, a downlink control information (DCI) message that may include a time domain resource assignment field (TDRA) that may indicate a set of PUSCH transmission configurations included in the data structure. The wireless device may perform PUSCH transmissions spanning multiple TTIs according to the indicated set of PUSCH transmission configurations over an unlicensed band.

Apparatuses, systems, and methods for a user equipment device (UE) to perform multiple TTI PUSCH transmissions in a wireless communication system as well as code block groups (CBGs) based retransmissions operations. A UE may perform radio resource control (RRC) signaling with a network entity to configure a data structure that may include one or more sets of physical uplink shared channel (PUSCH) transmission configurations, where each set of PUSCH transmission configurations span multiple TTIs. The wireless device may be configured to receive, from the network entity, a downlink control information (DCI) message that may include a time domain resource assignment field (TDRA) that may indicate a set of PUSCH transmission configurations included in the data structure. The wireless device may perform PUSCH transmissions spanning multiple TTIs according to the indicated set of PUSCH transmission configurations over an unlicensed band.

Systems and methods are described for electronically transmitting adaptively collapsible data across a network, whereby a baseline hierarchy of relationships based on precedence is generated for a set of data fields for data generated at an electrical system, and selecting one or more data fields for inclusion in a transmission package based on the hierarchy of relationships and a configurable condition, the configurable condition serving to potentially collapse (or deprecate) a data field, setting a status subfield to indicate inclusion or exclusion of the data field in a payload region of the transmission package and, when a particular data field is to be omitted, including only the status subfield for that data field and omitting the data corresponding to the data field.

A packet sending method includes, when a network element in a serial network receives a to-be-forwarded packet at a previous node from a previous network element, and when the network element needs to send a to-be-sent packet at a current node, determining whether the to-be-sent packet at the current node and the to-be-forwarded packet at the previous node can be superimposed, where the network element is an intermediate network element in the serial network; when the to-be-sent packet at the current node and the to-be-forwarded packet at the previous node can be superimposed, superimposing the to-be-sent packet at the current node and the to-be-forwarded packet at the previous node, to obtain a to-be-forwarded packet at the current node; and sending the to-be-forwarded packet at the current node to a next network element of the network element.

A packet sending method includes, when a network element in a serial network receives a to-be-forwarded packet at a previous node from a previous network element, and when the network element needs to send a to-be-sent packet at a current node, determining whether the to-be-sent packet at the current node and the to-be-forwarded packet at the previous node can be superimposed, where the network element is an intermediate network element in the serial network; when the to-be-sent packet at the current node and the to-be-forwarded packet at the previous node can be superimposed, superimposing the to-be-sent packet at the current node and the to-be-forwarded packet at the previous node, to obtain a to-be-forwarded packet at the current node; and sending the to-be-forwarded packet at the current node to a next network element of the network element.

This application discloses an information transmission method and an apparatus, and a communication device. The information transmission method of embodiments of this application includes: performing, by a first protocol layer entity, a first operation, where the first operation includes at least one of the following: sending first information to a second protocol layer entity, where the first information is used for requesting information about a data object associated with a data object of the first protocol layer entity from the second protocol layer entity; and receiving second information from the second protocol layer entity, where the second information is a first response message to the first information, or the second information includes related information of a data object of the second protocol layer entity; where the first protocol layer entity and the second protocol layer entity are located in a same communication device.

This application discloses an information transmission method and an apparatus, and a communication device. The information transmission method of embodiments of this application includes: performing, by a first protocol layer entity, a first operation, where the first operation includes at least one of the following: sending first information to a second protocol layer entity, where the first information is used for requesting information about a data object associated with a data object of the first protocol layer entity from the second protocol layer entity; and receiving second information from the second protocol layer entity, where the second information is a first response message to the first information, or the second information includes related information of a data object of the second protocol layer entity; where the first protocol layer entity and the second protocol layer entity are located in a same communication device.

The present disclosure discloses a method and a system for operating a complex data packet capable of being dynamically defined, and relates to the field of chip design and verification, and software technologies. The method includes: constructing a two-dimensional data structure of a data packet based on an actual programming requirement; performing slicing processing on the two-dimensional data structure of the data packet in a slicing manner; selecting an element corresponding to a processed slice from the data packet, and performing a storage and retrieval operation on a data packet element; marking each processed slice based on the processed slice; denoting a marked slice as a segment, and performing an element access operation on the segment in the data packet by using a mark; and comparing different data packets based on marked data packets and segments.

The present disclosure discloses a method and a system for operating a complex data packet capable of being dynamically defined, and relates to the field of chip design and verification, and software technologies. The method includes: constructing a two-dimensional data structure of a data packet based on an actual programming requirement; performing slicing processing on the two-dimensional data structure of the data packet in a slicing manner; selecting an element corresponding to a processed slice from the data packet, and performing a storage and retrieval operation on a data packet element; marking each processed slice based on the processed slice; denoting a marked slice as a segment, and performing an element access operation on the segment in the data packet by using a mark; and comparing different data packets based on marked data packets and segments.