Systems and methods for Wi-Fi sensing are provided. A networking device is configured to transmit a sensing trigger message including information about a plurality of fast sounding sensing signals to be transmitted. The networking device receives the plurality of fast sounding sensing signals transmitted by a sensing transmitter in response to the sensing trigger message within a transmission opportunity. The networking device performs a plurality of sensing measurements on the plurality of fast sounding sensing signals wherein the plurality of sensing measurements include measurements of Doppler frequency information associated with motion in a sensing space.

A method for classifying the height of an object by at least one vehicle ultrasonic sensor is disclosed. A computer receives at least two ultrasonic signals, calculates a first item of height information based on two items of spacing information relating to at least one vehicle ultrasonic sensor and the object, and calculates a variance of the first item of information. The computer similarly calculates a second item of height information and a variance thereof from a received further ultrasonic signal. The computer combines the items of height information as an average thereof, and the calculated variances of items of height information as an averaged variance thereof. The object is classified in a height class by calculating a probability value based on a distribution function which has as a mean value the averaged item of height information and as a variance the averaged variance of the height information.

An acoustic-based Direction of Arrival (DoA) system uses acoustic information to determine the direction of incoming sound, such as a person talking. The direction of the sound is then used to focus a laser-based time of flight (ToF) system to narrow the area of laser illumination, improving the signal to noise ratio because laser illumination is focused on the direction of the sound. The DoA system also provides elevation information pertaining to the source of the sound, to further narrow the required field of view of the laser ToF system.

Sensor receiver nulls and null steering. One example embodiment is method in which a direction from a sensor position to a noise source is determined. A coordinate rotation is applied to a first set of signal values, wherein each signal value of the first set of signal values is based on an output of a corresponding component of a three-component particle motion sensor at the sensor position. The applying generates a rotated set of signal values. The coordinate rotation comprises a coordinate rotation transforming a first set of coordinate axes to a second set of coordinate axes, wherein the first set of coordinate axes has each coordinate axis aligned with a corresponding component of the three-component particle motion sensor at the sensor position, and the second set of coordinate axes comprises a first axis pointed in a direction opposite the direction from the sensor position to the noise source.

Automotive radar systems may employ a reconfigurable connection of antennas to radar transmitters and/or receivers. An illustrative embodiment of an automotive radar system includes: a radar transmitter; a radar receiver; and a digital signal processor coupled to the radar receiver to detect reflections of a signal transmitted by the radar transmitter and to derive signal measurements therefrom. At least one of the radar transmitter and the radar receiver are switchable to provide the digital signal processor with signals from each of multiple combinations of transmit antenna and receive antenna.

The present disclosure describes a system, device, and method for assisting a user to avoid contacting surfaces with their mobile device. An environment is sensed with one or more electronic sensors. The sensor readings are analyzed. Information is then provided to a user based on the analyzed sensor readings. The sensors may be configured so their sensor cones cross at a midpoint. Readings from the sensor(s) may be grouped according detection zone(s) corresponding to one or more areas about a mobile device. A computing module may control a feedback module according to detection zone readings. The feedback module may comprise an indicator for each detection zone. The indicator may be a vibration motor. The indicator may be a light. The computing module may set the colour of a light and/or control the vibrations based on the proximity of surfaces detected within the corresponding detection zone.

In a sensor system, a monitoring ECU includes a result-transmission-instruction transmission section that transmits through a signal line a measurement result transmission instruction for transmitting distance data. The result-transmission-instruction transmission section transmits, during a new detection operation, the measurement result transmission instruction to at least one of the ultrasonic sensors engaged in a last detection operation. Upon receipt of the measurement result transmission instruction, a communication section of the ultrasonic sensors transmits a detection result during the new detection operation.

There are included: a device to be located (500) that transmits sound waves; a positioning device (100) that transmits sound waves to the device to be located (500) upon receiving the sound waves transmitted from the device to be located (500); and a positioning execution device (300) that calculates a distance between the positioning device (100) and the device to be located (500) by using required time for the device to be located (500) to receive the sound waves transmitted by the positioning device (100) after transmitting the sound waves and return delay time before the positioning device (100) transmits the sound waves to the device to be located (500) after receiving the sound waves, and calculates a location of the device to be located (500) by using the distance between the positioning device (100) and the device to be located (500).

A method for displaying a user interface on an electronic device is described. The method includes presenting a user interface. The user interface includes a coordinate system. The coordinate system corresponds to physical coordinates based on sensor data. The method also includes providing a sector selection feature that allows selection of at least one sector of the coordinate system. The method further includes providing a sector editing feature that allows editing the at least one sector.

The present invention relates to a system for collecting, lifting, and recovering seabed mineral resources, specifically, a device wherein hydrogen gas is evolved on the seabed, resources are lifted by the buoyancy of the gas to the sea surface, and the hydrogen gas which has become an excess buoyancy source during the lifting and recovering is absorbed into an organic substance including toluene, thereby yielding hydrogenated compounds including cyclomethylhexane to recover the energy required for hydrogen gas production.