A method for high density radio frequency identifier (RFID) scanning is provided. The method includes receiving a plurality of response signals from a plurality of RFID components. Where each of the plurality of response signals includes a part number and a serial number associated with the RFID component. The method also includes receiving, from a location device, a location of the scanning device. For each of the plurality of RFID components, the method includes determining a component location, the serial number, and the part number based on a corresponding response signal, comparing the component location to an expected location of the RFID component, determining a level of correlation between the serial number associated with the corresponding response signal and a stored serial number associated with the part number, and calculating a confidence score based on the corresponding comparison and the level of correlation.

A method for high density radio frequency identifier (RFID) scanning is provided. The method includes receiving a plurality of response signals from a plurality of RFID components. Where each of the plurality of response signals includes a part number and a serial number associated with the RFID component. The method also includes receiving, from a location device, a location of the scanning device. For each of the plurality of RFID components, the method includes determining a component location, the serial number, and the part number based on a corresponding response signal, comparing the component location to an expected location of the RFID component, determining a level of correlation between the serial number associated with the corresponding response signal and a stored serial number associated with the part number, and calculating a confidence score based on the corresponding comparison and the level of correlation.

An RF position tracking system for wirelessly tracking the three-dimensional position of a tracked object. The tracked object has at least one mobile antenna and at least one inertial sensor. The system uses a plurality of base antennas which communicate with the mobile antenna using radio signals. The tracked object also incorporates the inertial sensor to improve position stability by allowing the system to compare position data from radio signals to data provided by the inertial sensor.

A cavity sensor including: a body defining a cavity, the cavity having an opening on one end and a closed surface on other end; a reflective surface disposed in the cavity, the reflective surface being angled 45 degrees relative to a propagation direction of an incoming wave through the opening; and first and second angle probes positioned on each of two ends of the reflective surface. Also provided is a cavity sensor including: a body defining a cavity, the body having two or more conduits, each having an opening, the body having a closed surface opposing the openings, and a probe positioned in the cavity at a position common to each of the two or more conduits.

A system comprises: onboard a first craft, called host craft, a triplet of antennas comprising a transmitting and receiving antenna and two transmitting antennas, a transmission chain that can be successively coupled to each antenna of the triplet of antennas by a radiofrequency switch, a reception chain that can be coupled to the transmitting and receiving antenna, and a processing device intended to determine a relative angular position between, on the one hand, the host craft and, on the other hand, a plurality of spacecraft, called companion craft, from measurements of path differences performed and transmitted by the companion craft; onboard the companion craft, a transmitting and receiving antenna, a transmission chain and a reception chain coupled to the transmitting and receiving antenna and a measurement device intended to measure path differences between three signals originating from the three antennas of the triplet of antennas of the host craft.

An apparatus includes a directional scanner configured to receive signals from at least three RFID tags at a plurality of orientations of the directional scanner. The apparatus includes a pose estimator configured to estimate a pose of a device that includes or is coupled to the directional scanner based on orientation data indicating orientations of the directional scanner associated with determined peak signal strengths associated with the at least three RFID tags.

An example unmanned aerial vehicle includes an electromagnetic radiation (EMR) sensor. The EMR sensor detects a signal indicative of a direction of emission of the signal. The unmanned aerial vehicle also includes a nozzle to eject the substance based on the direction of emission.

Antenna apparatus and a method of operating the antenna apparatus are provided. The antenna apparatus comprises a directional antenna comprising antenna array components, RF chains connected to the antenna array components, and a transceiver connected to the RF chains. Each RF chain comprises in sequence: a switching stage having switching circuitry selectively to connect an antenna array component, a phase shifting stage having phase shifting circuitry, and a summation stage having summation circuitry, wherein at least two of the RF chains share phase shifting circuitry and at least two of the RF chains share summation circuitry. The at least partial sharing of the RF chains, an in particular of the phase shifting circuitry provides a compact and cheap antenna apparatus, which is nonetheless capable of degree of configurability in direction and beam pattern to enable it to operate in a busy and changing environment.

A route searching method used in an electronic device includes detecting decreased available power of the electronic device. When the available power of the electronic device is less than the predetermined value, determining whether a first communication device receives infrared signals transmitted by the charging device. If the infrared signals are not received, the electronic device is driven to repeatedly to continuously turn through a predetermined angle to find a moving orientation of the electronic device, driving the electronic device to move along the orientation, determining whether the first communication device receives the infrared signals transmitted by the charging device when the electronic device is moving, and driving the electronic device to move to the charging device under guidance of the infrared signals, when the first communication device receives the infrared signals transmitted by the charging device.

In an example embodiment, the orientation of a wireless device, such as an access point (AP) can be determined based on the location of neighboring wireless devices and the observed angle of arrival of signals from the wireless device at the neighboring wireless devices. For example, the angle of orientation can be determined by comparing an observed angle of arrival with the known actual angle between wireless devices. If a plurality of wireless devices measures the signal, the mean or median of the difference between observed angle of arrival of a signal from the wireless device with the actual angle for the plurality of wireless devices may be employed to determine the angular orientation.