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.

The present disclosure generally pertains to systems and methods for autonomously detecting and correcting anomalies in position information provided to aircraft using radio-frequency signals. By enabling autonomously detecting and correcting for anomalies in the operation of a ground-based solution entirely independent of GPS, systems of the present disclosure can make the provided position information more accurate and robust, thereby enhancing the effectiveness and safety of navigation systems using the provided position information. More precisely, systems of the present disclosure may employ a series of ground-based beacon transmitters to provide radio-frequency (RF) signal pulse with a highly regular frequency. A locating receiver can detect the arrival times of these pulses and use this information to detect and report certain anomalies. These reports may then be used to autonomously correct the detected anomalies.

An aspect of the present disclosure provides a method by a user device in a wireless communication system, the method comprising: receiving physical sidelink control channels (PSCCHs) from multiple anchor nodes (ANs); and on the basis of the PSCCHs, receiving multiple first positioning reference signals (PRSs) for positioning from the multiple ANs, wherein each of the PSCCHs comprises information relating to a positioning quality indicator (PQI) of each of the multiple ANs, and the positioning is performed on the basis of multiple second PRSs selected on the basis of information on the PQI from among the multiple first PRSs.

Disclosed are techniques for communication. In an aspect, a first network entity receives an integrated access and backhaul (IAB) node information message from a second network entity, the IAB node information message including one or more parameters for at least one transmission-reception point (TRP) of a base station, wherein the at least one TRP corresponds to an IAB node, and wherein the one or more parameters are related to the at least one TRP corresponding to the IAB node, and performs one or more positioning operations based on the one or more parameters to locate a target user equipment (UE) engaged in a positioning session with a location server.

Wireless positioning accuracy of a user equipment (UE) is impacted by locations of the transmit/receive points (TRPs) and UE for wireless positioning. To improve the accuracy of estimated locations, a geometric dilution of precision (GDOP) may be determined for different groups of candidate TRPs, with the GDOP indicating a potential positioning error associated with the group of candidate TRPs. A UE may determine GDOPs for different combinations of candidate TRPs. One or more devices of a wireless network (e.g., a location server and/or a UE for positioning) may select or exclude one or more candidate TRPs from being used for wireless positioning of a UE based on the determined GDOPs. Exclusion or selection of candidate TRPs for wireless positioning may also be based on quality measurements of PRSs (such as an RSRP or SNR) or a time duration associated with measuring the PRSs from the candidate TRPs to be selected.

Disclosed are techniques for wireless communication. In an aspect, a user equipment (UE) measures one or more positioning reference signal (PRS) resources of at least one PRS instance, and processes the one or more PRS resources of the at least one PRS instance during a PRS processing gap, wherein the PRS processing gap comprises a period of time during which the UE prioritizes PRS processing over reception, processing, or both of other downlink signals and channels.

Embodiments of the present disclosure provide a signal processing method, a signal processing device, a terminal and a network node. The signal processing method includes determining to drop the SRS-Pos or the first channel on overlapped OFDM symbols according to first information in the case that OFDM symbols occupied by an uplink positioning reference signal SRS-Pos overlap OFDM symbols occupied by a first channel; the first channel includes: PUSCH and/or PUCCH; the first information includes: at least one of a resource type of the SRS-Pos, a content carried by the first channel, or indication information configured by a network node; the indication information is related to dropping a signal on the overlapped OFDM symbols.

Proposed is an operation method for a first device (100) in a wireless communication system. The method may comprise the steps of: receiving a first positioning reference signal (PRS) from a second device (200), on the basis of a first antenna (106-1), a second antenna (106-2), and a third antenna (106-3); obtaining a first time difference, on the basis of a first reception time at which the first PRS is received on the basis of the first antenna (106-2) and a second reception time at which the first PRS is received on the basis of the second antenna (106-2); obtaining a second time difference, on the basis of a third reception time at which the first RPS is received on the basis of the third antenna (106-3) and the first reception time; and obtaining the location of the first device (100), on the basis of the first time difference and the second time difference.

Systems, methods, apparatuses, and computer program products for transmitter residual carrier frequency offset compensation. The method may include receiving, at a reference user equipment, configuration for a positioning reference measurement from a network element. The method may also include estimating a transmission carrier frequency offset of the network element based on the positioning reference measurements. The method may further include transmitting the estimated transmission carrier frequency offset in a report to the network element.

Measurement gap configuration request methods performed by a base station, a location server, and a terminal are provided. The measurement gap configuration request method includes: receiving, by a base station, a measurement gap request sent by a terminal or a location server; and performing at least one of the following according to the measurement gap request: configuring a measurement gap for measurement on a downlink positioning reference signal, or sending feedback information to the terminal or the location server, where the feedback information is used to indicate whether the base station configures the measurement gap for measurement on the downlink positioning reference signal.