A Radio Network Node (RNN) and a method for enabling an improved reception of Positioning Reference Signals (PRSs) at a communications device. The RNN and the communications device are operable in a wireless communications network. The RNN selects a first precoder and a second precoder for forming a first beam and a second beam, respectively, and obtains a precoding switching pattern relating to when the first precoder is to be applied to one or more first PRS symbols and when the second precoder is to be applied to one or more second PRS symbols. Further, the RNN transmits, to the communications device, the one or more first PRS symbols to which the first precoder is applied; and in accordance with the obtained precoding switching pattern, the RNN transmits, to the communications device, the one or more second PRS symbols to which the second precoder is applied.

An information processing apparatus includes a memory, and a processor coupled to the memory and configured to obtain location information indicating locations of a wireless transmitter and a wireless receiver, simulate a first power of a first reception signal at the wireless receiver in a condition that a radio signal is transmitted from the wireless transmitter, identify a first probability distribution model in accordance with the first reception signal, identify a first parameter of the first probability distribution model in accordance with the first power and a propagation environment defined by the locations of the wireless transmitter and the wireless receiver indicated by the location information, and based on the first probability distribution model using the first parameter, simulate a second power of a second reception signal at around the wireless receiver.

The present invention is enclosed in the area of wireless communication systems, generally towards the problem of multipath interference, and specifically towards mitigating the effect of standing wave in indoor positioning systems.

The present invention includes a standing wave cancellation wireless transmitter configured to, for each signal with wavelength to be transmitted, transmit a first wave with wavelength and a second wave with wavelength and a shift equal to half the wavelength .

It is also part of present invention a standing wave cancellation wireless receiver configured to perform the average of a first wave with wavelength and a second wave with wavelength and a shift equal to half the wavelength , creating a single received signal and,

a system comprising at least one of said wireless transmitters and at least one of said wireless receivers and a method implemented by the said transmitter and receiver.

Some demonstrative embodiments include apparatuses, devices, systems and methods of one-sided location measurement. For example, an apparatus may include circuitry and logic configured to cause a wireless station to transmit an announcement element to announce a Non-Data Packet (NDP) sounding transmission including a plurality of sounding preambles, the announcement element including at least a measurement type field to indicate a type of a one-sided location measurement, and one or more configuration fields including configuration information to configure the one-sided location measurement based on the NDP sounding transmission; and to transmit the NDP sounding transmission subsequent to the announcement element.

The present disclosure relates to building management. Various embodiments may include methods for determining a current position of mobile objects in buildings including: transmitting a referenced item of position information to a mobile object; transmitting a building plan to the mobile object for display thereon; and providing a calibration calculation for determining the current position of the mobile object on the plans displayed on the mobile object based on the position information. The position information is unambiguously associated with the transmitting device and thus corresponds to a current location of the mobile object in the building. Transmission of the position information or of the reference thereto takes place within a directional radio emitting region.

Example systems, devices, media, and methods for tracking movable objects and presenting virtual elements on a display in proximity to the movable objects. Ultra-wideband (UWB) transmitters are mounted to each movable object in an environment including at least two synchronized UWB receivers. The receivers calculate current locations of movable objects. Portable electronic devices, including eyewear devices, are paired with the receivers in a network. A localization application determines a current location of each eyewear device. A rendering application presents virtual elements on a display as an overlay relative to the current movable object location and in relative proximity to the current eyewear location. The physical environment is represented by a static mesh. A time synchronized tracking application identifies moving items that are not coupled to a UWB transmitter. The rendering application presents the virtual elements on the display in accordance with the static mesh and the moving items.

A mobile device is interoperable with a backpack system having a case body defining an interior cavity in which to carry articles and an exterior shell, having a mass and volume when fully loaded with articles suitable for an individual to carry; an inflatable floatation aid fixed to the exterior shell; and, an inflator in communication with the inflatable floatation aid, for inflation of the inflatable floatation aid. The mobile device includes: a locator beacon, including a communications transmitter capable of signaling a remote party and a geo-locating apparatus; sensors producing sensor outputs indicative of plural environmental parameters of the mobile device; and a processor having outputs for communication with the locator beacon in the mobile device and the inflator in the backpack system.

The disclosure is directed to systems and methods for collision avoidance of aerial vehicles. More particularly, the disclosure is directed to systems and methods for avoiding collisions between manned aerial vehicles and unmanned aerial vehicles. The unmanned aerial vehicle includes a low power RF beacon which transmits signals over a predefined frequency monitored by manned aerial vehicles.

A location system, comprises multiple nodes, each of which receiving and transmitting signals from and to user equipment. The system further comprises a processor configured to determine a location of the user equipment in a space having at least one node. The system is configured to interprets the location of the user equipment based on power of at least one signal transmitted to at least one of the nodes, a received signal strength of the user equipment at one of the nodes, and distances between the user device and at least two nodes.

A localization system comprising a plurality of wireless reference nodes for detecting a location of a mobile device within an environment. Each node transmits localization beacon signals to be detected by the mobile device, and/or listens for localization beacon signals from the mobile device. Further, the system also provides or contributes to providing another utility into the environment (e.g. each node being a luminaire); and transmits and/or listens for control-related signals, other than localization beacon signals, related to controlling the provision of said utility, the control related signals being communicated on a same or overlapping frequency band as the localization beacon signals, one or more controllers are configured to control the transmission of and/or listening for the control-related signals to be time-multiplexed into different time slots than the transmission and/or listening for the localization beacon signals, between the time-slots of the control-related signals.