The method for localizing a beacon consists in transmitting, by a first transceiver, an initiation signal, which is received by second and third transceivers, in calculating, by means of said initiation signal, errors between a reference frequency of the first transceiver and reference frequencies of the second and third transceivers, in transmitting, by the beacon, a first pulsed signal, which is received by the first, second and third transceivers, in transmitting, by the first transceiver, a second pulsed signal, which is received by the second and third transceivers, in calculating differences in the times-of-flight of the first and second pulsed signals, each time-of-flight difference being calculated in a time base provided by a local oscillator of the first transceiver by means of reference frequency errors, and in calculating a beacon position by means of the times-of-flight.

The method for localizing a beacon consists in transmitting, by a first transceiver, an initiation signal, which is received by second and third transceivers, in calculating, by means of said initiation signal, errors between a reference frequency of the first transceiver and reference frequencies of the second and third transceivers, in transmitting, by the beacon, a first pulsed signal, which is received by the first, second and third transceivers, in transmitting, by the first transceiver, a second pulsed signal, which is received by the second and third transceivers, in calculating differences in the times-of-flight of the first and second pulsed signals, each time-of-flight difference being calculated in a time base provided by a local oscillator of the first transceiver by means of reference frequency errors, and in calculating a beacon position by means of the times-of-flight.

A method for locating at least one receiver in a positioning system. The system includes: at least two generators, each generator emitting, on a single carrier, at least two signals that each have a different code, and a receiver configured to detect the signals emitted by the generators. In the method: the receiver measures, for each generator, the phase difference between both signals emitted by the generator, and at least one geometric size, representing the position of the receiver in relation to the generators, is calculated on the basis of the measurements of the phase difference in order to locate the receiver in the positioning system.

Sounds, alarms or other indications of conditions of potential interest that are produced by appliances and other household devices are detected by one or more sensors to trigger a notification signal that is sent to a remotely located user. The signals produced by the sensors are advantageously compared with a database of signals representing conditions of potential interest produced by known appliances and devices, producing the appropriate notification signal when a match is found. Notifications may be relayed to one or more selected users only when predetermined conditions are satisfied.

Techniques are described herein for imaging static or semi-static objects in a wireless power delivery environment and tracking non-static objects contained therein. More specifically, embodiments of the present disclosure describe techniques for determining the relative locations and movement of non-static objects in a wireless power delivery environment. Additionally, the techniques describe methods and system for generation of motion-based maps such as heat (or dwell maps) and flow maps.

Systems and methods for navigating an aerial vehicle are provided. One example aspect of the present disclosure is directed to a method for navigating an aircraft. The method includes receiving, by one or more processors, one or more first geographic coordinates via an interface configured to receive geographic coordinates from a satellite transmission. The method includes receiving, by the one or more processors, one or more second geographic coordinates via an interface configured to receive geographic coordinates from a ground transmission. The method includes determining, by the one or more processors, that the one or more first geographic coordinates and the one or more second geographic coordinates are inconsistent. The method includes updating, by the one or more processors, a flight plan using the one or more second geographic coordinates when the one or more first geographic coordinates are inconsistent with the one or more second geographic coordinates.

A locator beacon, method and system for identifying a first-in-line device, including: a first antenna configured to send a first signal; a second antenna configured to send a second signal and spaced apart from the first antenna such that a delta value between a first Received Signal Strength Indicator (RSSI) value of the first signal and a second RSSI value of the second signal measured at a predefined location, is within a range of values; a receiver for receiving wireless signals configured to receive an authentication signal from a mobile device adapted to measure the first and second RSSI values, the authentication signal including authentication data related to the measured RSSI values; and a processing unit, configured to determine whether the mobile device is the first-in-line device based on whether a delta value between the first RSSI value and the second RSSI value is within a predefined value range.

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.

Utilizing a series of beacons deployed within an urban environment to support Location Based Services (LBS). Each beacon emits a beacon signal comprising LBS supporting information within an identification portion of the beacon signal. The emitted beacon signal is received by any mobile device, decoded, the LBS supporting information is extracted from the signal and acted upon accordingly. The information can provide the recipient with information, initiate a link to another device, initiate a LBS, etc. The information can be relayed using intermediary mobile devices. The identification portion can include information for location, beacon ID, marketing, emergencies, services, traffic, etc. A sensor can be integral with the beacon to provide additional benefits.

A method of designing bandwidth-efficient ranging waveforms provides waveforms usable in non-contiguous spectral bands that have low SNR thresholds and are usable at low and moderate SNR's. A set of allowed frequencies in the desired spectral region is divided into bands. A first group of band combinations is selected having a required accuracy at high SNR. Those band combinations in the first group that have the smallest autocorrelation secondary peaks are selected as a second group. Finally, waveforms are selected that occupy band combinations from the second group and have desired factors such as simultaneous or sequential transmission, a desired order of sequential transmission, and/or a desired modulation of the individual bands. Multiple simultaneous transmissions can share a set of bands, and individual transmitters can employ different modulating waveforms with good cross-correlation. In embodiments, waveforms having 4-6 bands provide a SNR threshold only 6-9 dB lower than conventional waveforms.