A method and apparatus for hybrid automatic repeat request (HARQ) feedback based on a communication range and location of devices is provided. A first device (e.g., receiving user equipment in sidelink) receives, from a second device (e.g., transmitting user equipment in sidelink, control information including 1) a communication range, and 2) a location of the second device. The first device determines whether to perform a hybrid automatic repeat request (HARQ) feedback based on whether a distance between a location of the first device for the control information and the location of the second device is smaller or equal to the communication range.

A method is provided that includes obtaining or holding available radio positioning support map information and geographic map information. An overlapping geographic area is covered by the radio positioning support map and the geographic map, which is dividable into a plurality of subareas. The method also includes determining, for each subarea of the plurality of subareas, a respective observed radio positioning support device density at least partially based on the radio positioning support map and a respective expected radio positioning support device density at least partially based on the geographic map. The method further includes evaluating, for each subarea of the plurality of subareas, a respective radio positioning performance in a respective subarea at least partially based on the respective observed radio positioning support device density and the respective expected radio positioning support device density. A corresponding apparatus and computer readable storage medium are also provided.

A device generates a first plurality of aerial vehicle (AV) constellations about a geographic area and determines respective positioning scores for each AV constellation. The respective positioning score is determined based at least in part on a measure of positioning accuracy for positioning enabled by the AV constellation at position(s) of interest within the geographic area. The device generates a second plurality of AV constellations based on the first plurality and the respective positioning scores by modifying one or more of the AV constellations of the first plurality using random location perturbations. The device determines respective positioning scores for each AV constellation of the second plurality. The device selects a preferred AV constellation from a group of selectable constellations based on the respective positioning score of the preferred AV constellation, the group of selectable constellations generated based at least in part on the first and/or second plurality of AV constellations.

Various aspects of the present disclosure generally relate to wireless communication. In some aspects, a user equipment (UE) may transmit, to another UE, a positioning request associated with a procedure for determining a position of the UE, wherein the positioning request comprises a first sidelink communication between a first sidelink location management component (S-LMC) of the UE and a second S-LMC of the other UE, wherein the first S-LMC and the second S-LMC comprise sub-functions associated with a vehicle-to-everything protocol layer; receive, from the other UE, a second sidelink communication associated with the procedure for determining the position of the UE; and determine the position of the UE based at least in part on the second sidelink communication. Numerous other aspects are provided.

There is described a system for tracking beacon tags comprising a communication component and a processor. The communication component receives a beacon from a beacon tag and transmit an acknowledgment of the beacon. The processor identifies a tag characteristic associated with the beacon tag and generates a tag instruction based on the tag characteristic. The tag instruction includes a beaconing rate for the beacon tag, and the acknowledgment includes the tag instruction. There is also described a beacon tag for operating with a tracking system comprising a communication component and a processor. The communication component transmits a first beacon, receive an acknowledgment associated with the beacon, and transmit a second beacon from the beacon tag based on an adjusted beaconing rate. The processor identifies a tag instruction of the acknowledgment and adjusts the beaconing rate of the beacon tag based on the tag instruction.

A server jointly tracks states of multiple vehicles using measurements of satellite signals received at each vehicle and parameters of the probabilistic distribution of the state of each vehicle. The server fuse states and measurements into an augmented state of the multiple vehicles and an augmented measurement of the augmented state subject to augmented measurement noise defined by a non-diagonal covariance matrix with non-zero off-diagonal elements, each non-zero off-diagonal elements relating errors in the measurements of a pair of corresponding vehicles. The server executes a probabilistic filter updating the augmented state and fuses the state of at least some of the multiple vehicles with a corresponding portion of the updated augmented state.

A system according to one embodiment includes a first computing device comprising ultra-wideband communication circuitry, and a second computing device comprising ultra-wideband communication circuitry configured to communicate with the ultra-wideband communication circuitry of the first computing device to determine the angle and distance of the first computing device relative to the second computing device.

Localization systems and methods for transmitting timestampable localization signals from anchors according to one or more transmission schedules. The transmission schedules may be generated and updated to achieve desired positioning performance. For example, one or more anchors may transmit localization signals at a different rate than other anchors, the anchor transmission order can be changed, and the signals can partially overlap. In addition, different transmission parameters may be used to transmit two localization signals at the same time without interference. A self-localizing apparatus is able to receive the localization signals and determine its position. The self-localizing apparatus may have a configurable receiver that can select to receive one of multiple available localization signals. The self-localizing apparatuses may have a pair of receivers able to receive two localization signals at the same time. A bridge anchor may be provided to enable a self-localizing apparatus to seamlessly transition between two localization systems.

In an aspect, an initiator transmits a positioning reference signal. The initiator receives a plurality of responder positioning reference signals sent from individual responders of a plurality of responders. The initiator transmits a measurement message comprising a first set of measurements that are determined based on the positioning reference signal and the plurality of responder positioning reference signals. The initiator receives responder measurement messages sent from the individual responders of the plurality of responders. The initiator receives updated map information from an anchor and updates pre-existing map information based on the updated map information.

According to an example embodiment, there is provided a base station apparatus configured to store an initial planned location of the apparatus, to receive first messages from a master base station, each first message comprising a first timestamp indicating a transmission time of the first message, and to transmit second messages, each second message comprising a second timestamp indicating a transmission time of the second message and a location estimate of the apparatus, to receive second messages from peer apparatuses, and to receive third messages from the master base station, and configured to to determine a location of the apparatus by performing an iterative process, wherein each iteration comprises determining an updated location estimate of the apparatus based on a received first message, received at least one second message and a received third message, and determining a quality criterion of the updated location estimate of the apparatus.