Abstract: A method of sending measurement information from a user equipment includes: measuring a reference signal; producing a measurement report payload based on measurement of the reference signal; encoding the measurement report payload in accordance with ASN.1 (Abstract Syntax Notation One) encoding, and in accordance with a lower-layer protocol to produce an encoded payload, the lower-layer protocol being either a physical-layer protocol or a MAC-layer (Medium Access Control layer) protocol; and sending a lower-layer message based on the encoded payload from the user equipment to a network entity.

Abstract: Disclosed are various techniques for wireless communication. In an aspect, a user equipment (UE) may determine a plurality of measurement gap (MG) configurations, each MG configuration defining one or more MGs. The UE may send, to a serving base station, a request to use a first MG configuration from the plurality of MG configurations, and may receive a response to the first request. The UE then measures positioning signals using an MG configuration indicated by the response. Based on measurements of the first set of positioning signals, the UE may select a second MG configuration, send a second request to use the second MG configuration, and receive a response to the second request. The UE then measures a second set of positioning signals using an MG configuration indicated by the response to the second request.

Abstract: In an aspect, an LMF component may determine to trigger positioning-related action(s) at a UE. The LMF component may request that a serving BS of the UE trigger the positioning-related action(s). The serving BS may transmit a DCI communication with a CSI request field (e.g., that triggers at least CSI reporting, or triggers positioning-related action(s) only). The CSI request field may further be associated with positioning-related information including at least one PRS configuration, at least one positioning measurement request, at least one location reporting request, or a combination thereof. The UE may perform the positioning-related action(s) based on the positioning-related information.

Abstract: Techniques are provided for herein for down selecting positioning reference signals with a user equipment (UE). An example method for measuring and reporting positioning reference signals includes receiving positioning reference signal measurement and accuracy requirements, measuring one or more positioning reference signals based on the measurement and accuracy requirements, and reporting one or more positioning reference signal measurement results based on the measurement and accuracy requirements.

Abstract: Disclosed are various techniques for wireless communication. In an aspect, a user equipment (UE) may receive, from a network entity, first information identifying positioning reference signal (PRS) resources. The UE may receive, from a base station, second information identifying sounding reference signal (SRS) resources. The UE may select, from PRS resources identified by the first information, PRS resources that satisfy a PRS-SRS proximity requirement with regard to at least one SRS resource identified by the second information. The UE may use the selected PRS resources at least for performing UE Rx-Tx measurements. In another aspect, a network entity may transmit, to a UE, first information identifying PRS resources. The network entity may transmit, to the UE, second information specifying a number of PRS resources to be used by the UE at least for performing UE Rx-Tx measurements.

Abstract: A method of facilitating position determination of a user equipment includes: receiving, at the user equipment, a first plurality of positioning reference signal portions having a corresponding plurality of frequency sub-bands; processing, at the user equipment, one or more of the first plurality of positioning reference signal portions to determine position information; and at least one of: transmitting a capability message, to a network entity, indicating a processing capability of the user equipment to process, in combination, positioning reference signal portions having different frequency sub-bands to determine the position information; or transmitting a signal-combination indication, to the network entity, indicating a second plurality of positioning reference signal portions, of the first plurality of positioning reference signal portions, processed by the user equipment in combination to determine the position information.

Abstract: In an aspect, a network entity transmits, to a UE, a PRS configuration that configures a plurality of PRS measurement occasions (MOs)) of one or more PRS resources associated with a transmission reception point (TRP), wherein each PRS MO is transmitted on a different time instance on the same bandwidth. The UE performs one or more measurements at each of the plurality of PRS MOs of the same PRS resource of the one or more PRS resources. The UE transmits, to the network entity, a single measurement report comprising measurement information associated with the one or more measurements derived on the same PRS resource from two or more of the plurality of PRS MOs.

Abstract: A UE receives a first configuration for at least one RRM measurement gap. The UE receives one or more PRSs prior to the at least one RRM measurement gap. The UE identifies whether a processing availability of the UE during the at least one RRM measurement gap is sufficient to process the one or more PRSs. The UE processes the one or more PRSs, where in response to the processing availability of the UE during the at least one RRM measurement gap, the one or more PRSs are processed during the at least one RRM measurement gap; and in response to lack of the processing availability of the UE sufficient to process the one or more PRSs during the at least one RRM measurement gap, the one or more PRSs are processed, at least in part, outside of the at least one RRM measurement gap.

Abstract: A signal measuring method includes: receiving, at a user equipment, first positioning assistance data having a first area of applicability and a first positioning assistance data profile; storing the first positioning assistance data at the user equipment; determining, at the user equipment, that second positioning assistance data correspond to the first positioning assistance data based on the first area of applicability including a second area of applicability, of the second positioning assistance data, and based on a second positioning assistance data profile of the second positioning assistance data corresponding to the first positioning assistance data profile; and measuring, at the user equipment, a positioning signal corresponding to the second area of applicability using the first positioning assistance data in response to determining that the second positioning assistance data correspond to the first positioning assistance data.

Abstract: The present invention relates to an improved microdialysis method utilizing an ultrafiltration module comprising of a plurality of hollow fiber microtubular membranes for In-Vitro Release Testing (IVRT) of dispersed dosage forms, such as but not limited to solutions, emulsions, suspensions, liposomes, nanodispersions, nanocrystals and polymeric nanocarriers. The invention further relates to a microdialysis based method providing an increase permeability area for faster release of an agent, which enables the substantial or near complete drug release in a shorter duration of time. The invention further relates to a system for in-vitro release testing of a dosage form with increased permeability area for faster release of an agent which enables the near complete or substantial release of a drug.

Abstract: Disclosed are techniques for wireless positioning. In an aspect, a user equipment (UE) engages in a positioning procedure with a location server, transmits a recommendation to a network entity to transition to or remain in a first radio resource control (RRC) state for the positioning procedure, receives, in response to the recommendation, a configuration from the network entity to transition to or remain in the first RRC state, transitions to or remains in the first RRC state to perform the positioning procedure based on the configuration, and performs one or more positioning operations associated with the positioning procedure while in the first RRC state.

Abstract: Methods and systems for detecting threats using threat signatures loaded in a computing device.

Abstract: A method and system for data synchronization in a multi-tenant data synchronization system is provided.

Abstract: A user equipment (UE) uses downlink positioning reference signals (PRS) beams for position measurements. The PRS beams may be transmitted using beamforming and transmitted in a beam-sweeping manner. The UE receives assistance data that includes PRS configuration information including the azimuth and elevation angles and beam width information for each PRS beam. The beam width information may include the beam width, bore sight direction uncertainty, beam width uncertainty, and side lobe/back lobe beam information. The UE may select or adapt the receive (Rx) antennas based on the beam width information to reduce power consumption, for example, by reducing the number of Rx antennas used to receive wide PRS beams, and selecting a larger number of Rx antennas when the PRS beams are narrow.

Abstract: Aspects of the present disclosure relate to identifying and quantifying relationships between entities. Data sources can be queried to receive data regarding a party. Entities can be extracted from the data to receive a set of entities, wherein the party is a first entity of the set of entities. An ontological structure can be built that interrelates entities within the set of entities. An initial relationship strength can be determined between the first entity and a second entity based on co-occurrence between the first and second entities, wherein the second entity is a second party. A relationship score can be calculated between the first and second entities based on the initial relationship strength and at least one additional factor.

Abstract: A user equipment (UE) may define the classes of a plurality of path delay detection algorithms that the UE may use to identify line-of-sight positioning signals and reject non-line-of-sight positioning signals. The UE may receive a capabilities request from a location server and transmit, to the location server, a capability report indicating the classes of the plurality of path delay detection algorithms supported by the UE. The UE receives a location information request from a location server, and selects a path delay detection algorithm, which is used to perform measurements of one or more positioning signals received by the UE. The UE provides an indication of the selected path delay detection algorithm along with the positioning measurements to the location server. The location server determines or verifies a location of the UE based on the path delay detection algorithm selected by the UE and the positioning measurements.

Abstract: The present disclosure provides methods for treating viral infections, in particular treating coronavirus infections in a subject with auranofin.

Abstract: In an aspect, a wireless node (e.g., UE or BS) determines timing information associated with a first one or more reference signals for positioning or with a first one or more measurements derived using the first one or more reference signals for positioning, the first timing information including a transmit or receive hardware group delay, timing error, timing calibration error, or a combination thereof. The wireless node further determines that the first one or more reference signals or the first one or more measurements are associated with one of a plurality of timing groups at least based on the first timing information. The wireless node transmits (e.g., to a position estimation entity) an indication of the associated timing group in association with the first one or more reference signals for positioning or with the first one or more measurements derived using the first one or more reference signals for positioning.

Abstract: A mobile device supports positioning with positioning reference signals (PRS) on multiple beam by dividing the PRS processing into two separate modes, an acquisition mode and a tracking mode. In acquisition mode, the mobile device performs a fast scan of all of the beams from a base station transmitting PRS using less than the full set of resources for the PRS, i.e., less than the full bandwidth and/or less than the full number of repetitions of the PRS. The mobile device may select the best beams to use for positioning, e.g., based on signal strength metric. In tracking mode, the mobile device tracks the PRS from only the selected beams using the full set of resources for the PRS. The mobile device may return to acquisition mode after a predetermined number of positioning occasions or if the selected beams are no longer valid due to movement or change in conditions.

Abstract: Disclosed are techniques for wireless positioning. In an aspect, a user equipment (UE) receives a positioning reference signal (PRS) configuration indicating one or more PRS resources transmitted on one or more antenna ports of at least one antenna panel of a base station, measures the one or more PRS resources over a set of angles, wherein the UE is configured to search for the one or more PRS resources over the set of angles based on the PRS configuration, and determines an angle of the set of angles over which at least one PRS resource of the one or more PRS resources was measured as a downlink angle-of-departure (DL-AoD) between the base station and the UE.