A method for performing a handover operation includes using one or more processors of a non-terrestrial node to initiate communication with a first terrestrial node of a network, the terrestrial node having a first unique node identifier and a cell identifier and store a mapping that associates the first unique node identifier with the cell identifier. The method also includes using the one or more processors to receive an indicator that the mapping is subject to change and update the mapping to associate a second unique node identifier of a second terrestrial node of the network with the cell identifier based on the received indicator.

Systems and methods for determining the performance of a driver of a vehicle based on changes, over time, in the context and environment in which the vehicle operates, and any resultant driver behavior are disclosed. A set of driver response data is created from based on an analysis of time-series data indicative of the driver's operation of the vehicle in conjunction with time-series data indicative of changes in the vehicle's context/environment. The driver response data indicates the types and magnitudes of the driver's responses to various changes in the vehicle's operating context/environment and the driver's time-to-respond for each of the responses. That is, the driver response data indicates how a driver compensated his or her behavior (if at all) in response to different changes in the vehicle's context and/or environment. The driver response data may be compared to one or more thresholds to determine the driver's performance.

The disclosure relates to a communication technique for combining, with IoT technology, a 5G communication system for supporting a data transmission rate higher than that of a 4G system, and to a system therefor. The disclosure may be applied to intelligent services (e.g., a smart home, a smart building, a smart city, a smart car or connected car, healthcare, digital education, retail business, security and safety-related service, etc.), based on a 5.sup.th generation (5G) communication technology and an Internet of Things (IoT)-related technology. The disclosure discloses a method and an apparatus for providing direct communication services.

A method and apparatus may comprise receiving zone configuration information pertaining to one or more zones having one or more zone-ids. For each zone-id of the zone-ids, the configuration information may indicate one or more of a BRS, a set of TCI states for receiving a PDSCH transmission, a search space, a CORESET configuration or uplink resources. The method may further comprise determining a zone-id of the one or more zones-ids, based on a measurement of one or more BRSs indicated via the configuration information. An indication of the determined zone-id may be transmitted to a base station using uplink resources associated with the zone-id.

A method performed by a UE is provided. The method includes receiving at least one SL-DRX configuration and a plurality of SL resource pool configurations to be configured on the first UE; performing partial sensing based on at least one of the plurality of SL resource pool configurations when an SL-DRX operation is performed based on the at least one SL-DRX configuration, each of at least one SL resource pool configured by the at least one of the plurality of SL resource pool configurations comprising one or more time slots; and performing SL-CBR measurement associated with each of the at least one SL resource pool in the one or more time slots where the partial sensing is performed.

The present application relates to a method for determining transmission resources and a terminal device. The method includes: determining, by a terminal device, a time domain position of a time unit; and determining, by the terminal device, a time domain position of a sidelink configured grant transmission resource according to the determined time domain position of the time unit and a first resource pool. The first resource pool is a resource pool associated with the sidelink configured grant.

A technique is directed to methods and systems for providing autonomous wireless coverage. In some implementations, the autonomous wireless coverage providing machine (e.g., a mobile wireless tower) can move to various locations to optimize coverage, connectivity, and/or quality. The mobile wireless tower can collect environment data of a location and determine the terrain and wireless devices requesting coverage. The mobile wireless tower can identify a location to provide network coverage to the devices based on the terrain. In some implementations, the mobile wireless tower can determine a location to provide coverage using Artificial Intelligence or Machine Learning retrieved from the network for which the mobile wireless tower provides coverage. The mobile wireless tower can have a flexible length wired or wireless backhaul capability for the mobile wireless tower to send data and retrieve data stored on the network.

Systems and methods are described for receiving a user selection indicating that a wireless network of a vehicle has been compromised; in response to receiving the user selection, causing the vehicle to be disconnected from the compromised wireless network; and while the vehicle is disconnected from the compromised wireless network performing a remedial action to enable the vehicle to navigate from a current location of the vehicle to a safe location.

Embodiments of the present disclosure disclose a TAU method and device based on a mobile IAB node to solve the problem that a terminal device in a cell provided by the mobile IAB node is prone to cause a TAU storm. The method is executable by the mobile IAB node, and includes: receiving first TAC list information; and initiating a TAU procedure based on the first TAC list information in a case that a new TAI is discovered, where the TAU procedure is used by a first AMF to update location information of the terminal device in the cell provided by the mobile IAB node.

The disclosure relates to a 5G or pre-5G communication system for supporting a higher data rate after a 4G communication system such as LTE. A method according to an embodiment of the disclosure is a control method in an edge enabler server (EES) of a mobile edge computing system, and may include subscribing to a user plane path change event at an edge application server (EAS); determining an application context relocation (ACR) based on receiving a user plane path management event notification from the mobile communication network in case of subscribing to the user plane path change event for the EAS; transmitting an ACR request message to the EAS; receiving an EAS response message from the EAS; and transmitting an application function (AF) acknowledgment message to a first node of the mobile communication network in response to receiving the EAS response message from the EAS.