A method for a user equipment to transmit information for measurement of a positioning reference signal (PRS) in a wireless communication system according to an embodiment of the present disclosure, the method comprising: receiving, from a location server, configuration information related to the PRS, receiving the PRS from a base station, and transmitting, to the location server, information for a measurement of the PRS. The configuration information includes information for an angle related to the PRS. The information for the angle related to the PRS includes information for at least one of i) an expected angle related to the PRS and/or ii) a range of angles related to the PRS.

Vehicles in traffic are expected to communicate wirelessly, to avoid collisions and facilitate the flow of traffic. Unfortunately, in 5G and 6G, the process of finding a wireless address of a specific vehicle is slow and difficult. Disclosed is a “connectivity matrix”, an emblem that vehicles can display, showing a pattern of black and white squares that forms a unique code. Another vehicle can autonomously read the code and look up the wireless address in a tabulation. The tabulation relates each code to the relevant wireless address, and optionally other information about the vehicle. The two vehicles can then transfer messages, including emergency messages, without delay. At freeway speeds, this can save lives. A central entity maintains the tabulation, ensuring that each wireless address is associated with a unique connectivity matrix code. Roadside companies and access points can also display a connectivity matrix, promote communication with prospective customers.

A user equipment includes: an interface; a memory; and a processor, communicatively coupled to the interface and the memory, configured to: receive a plurality of requests to process a corresponding plurality of positioning reference signal (PRS) groups, each of the plurality of PRS groups having respective PRS characteristics; determine a priority for processing the plurality of PRS groups according to at least one priority criterion; determine whether a total amount of the PRS characteristics of the plurality of PRS groups exceeds a PRS processing capability of the processor; select, in response to the total amount of the PRS characteristics exceeding the PRS processing capability of the processor, a subset of the plurality of PRS groups based on the priority for processing; and process the subset of the plurality of PRS groups to determine position information.

Methods, systems, and apparatuses are provided for User Equipment (UE) location reporting in a wireless communication system to facilitate efficiency in measurement reporting in Non-Terrestrial Networks (NTNs). A method for a UE in a wireless communication system comprises receiving a first configuration to trigger measurement reporting based on a first event that distance between the UE and a first reference location of a serving cell becomes larger than a distance threshold and distance between the UE and a second reference location of a first neighbor cell becomes shorter than another distance threshold, and triggering a first measurement report based on the first event, wherein measured radio condition of the first neighbor cell is omitted or not included in the first measurement report.

A positioning method in a 5G cellular network includes a UE receiving a radio resource control (RRC) release message, the RRC release message carrying positioning assistance information. The positioning assistance information is used to perform positioning measurement to obtain a positioning result when the UE is in an RRC non-connected state; and the RRC non-connected state includes an RRC idle state and an RRC inactive state.

A control device and a control method that can reduce power consumption for waiting for reception of a signal are provided. The control device includes a controller configured to control a communicator such that the communicator performs wireless communication with another device. The controller controls a reception waiting time of a predetermined signal which is transmitted from the other device by the wireless communication on the basis of acquired acquisition information.

Apparatuses and methods are disclosed. A method comprising: receiving (702) one or more criteria, from a location server, related to one or more properties of at least one measurement used for position estimation; receiving (704) a measurement request to perform the at least one measurement; performing (706) the at least one measurement based on the measurement request; determining (708) whether the at least one measurement satisfies the one or more criteria; and determining (710) a measurement reporting mode based on whether the at least one measurement satisfies the one or more criteria in the absence of the location server specifying a measurement reporting mode.

A surveying system for a construction site has a restricted antenna system with a plurality of fixed location antennas each defined by a set of location data associated with a specific deployment position. The surveying system also has a computing device with a data processor and a display screen. A communications module establishes a data transfer link with the restricted antenna system over which spatial data for distances between current positions of the computing device and one or more of the plurality of fixed location antennas are received. The computing device is loadable with project drawings corresponding to the construction site and displayable on the display screen. A position marker is overlaid on the display of the project drawing at a position thereon corresponding to a computing device location value derived from the spatial data and the location data of one or more of the fixed location antennas.

An RF position tracking system for wirelessly tracking the three-dimensional position of a tracked object. The tracked object has at least one mobile antenna and at least one inertial sensor. The system uses a plurality of base antennas which communicate with the mobile antenna using radio signals. The tracked object also incorporates the inertial sensor to improve position stability by allowing the system to compare position data from radio signals to data provided by the inertial sensor.

Vehicles in traffic cannot coordinate their actions properly in 5G and 6G without knowing the location and the wireless address of the other vehicle. GNSS signals are generally too slow and too imprecise to discern vehicles in, for example, adjacent lanes. Directional wireless beams are subject to reflections from conducting surfaces, producing chaotic signals and false locations if more than one vehicle is within the transmission beam. To provide precise localization in traffic, methods are disclosed for multiple vehicles (or other mobile devices) to acquire satellite signals simultaneously, and then analyze the data differentially, thereby canceling major uncertainties (such as propagation variations, ephemeris motion, and clock jitter), and thereby determining the relative positions precisely. Unlike prior-art “precision” positioning methods, the disclosed methods do not require averaging multiple acquisitions. On the contrary, examples show how high differential precision can be obtained without averaging, using measurements acquired at the predetermined time.