A dynamic power reduction method and apparatus for use in an ultrasound system are described. In one embodiment, the ultrasound system comprises: a transducer assembly and imaging subsystem having a transmit data path having a transmitter to transmit acoustic signals and a receive data path having including signal acquisition circuitry with a receiver to receive acoustic signals representing echoes; a plurality of real-time signals indicative of status of imaging operations being performed by the transmit and receive paths; a clock generator to generate one or more clocks for use by the transmit and receive data paths; clock gating circuitry coupled to the clock generator and the transmit and receive paths and having circuits to gate clocks to at least one of the transmit and receive paths; and a clock gating controller coupled to the clock gating circuitry to control the circuits to gate or pass clock signals to at least one of the transmit and receive paths automatically in response to receipt of one or more signals from the plurality of real-time signals.

An ultrasonic sensor is provided with a sensor body, a cushion member, a retainer part and a waterproof seal. The sensor body has an ultrasonic microphone and a microphone support part. The cushion member covers a protrusion part of the ultrasonic microphone. The retainer part sandwiches a sandwiched part on a proximal end side between the retainer part and an outer peripheral surface of the ultrasonic microphone, while exposing an exposed part on a tip end side in the axial direction of the cushion member. The waterproof seal blocks a gap between a vehicle body component and the exposed part of the cushion member in an on-board state.

An object detection apparatus includes a sensor module including a sensor, and a controller that controls the sensor and generates output information, based on a signal that the sensor outputs; and a detector that determines presence or absence of the object, based on the output information. The detector executes a reference object detection process of detecting a reference object existing at a predetermined position within the detection range, by comparing the output information and predetermined reference information, and, when the reference object is detected, executes a correction process of correcting at least one of the output information or a parameter for the sensor, based on the reference information and reference object information that is information indicative of the reference object in the output information.

An air data sensor can include an acoustic transmitter configured to output an acoustic signal into an airflow and a plurality of acoustic transducers configured to receive the acoustic signal output by the acoustic transducer. The air data sensor can also include a light source configured to output a light beam into the airflow, and a light receiver configured to receive scattered light from the light beam. The light source and the light receiver can be bistatic such that a measurement zone is formed away from the air data sensor.

The invention generally relates to sonar devices that integrate forward-looking sensors with down-looking echosounders, side scanning sonar, or both. The invention provides a sonar system that includes a forward-looking sonar device that operates in an integrated fashion with one or more other sonar devices so that a boater can have a reliable navigation tool while also using sonar for finding fish and other features on the seafloor. The forward-looking sonar can include a transducer array that takes a three-dimensional acoustic reading of the objects and seafloor ahead. The electronics that process the acoustic data can also process data from down-looking sonar, side-scanning sonar, or both and can integrate the information to present an expansive display in the boat, revealing the contents and the floor of the sea in front of, around, and under the boat.

The invention generally relates to sonar devices that integrate forward-looking sensors with down-looking echosounders, side scanning sonar, or both. The invention provides a sonar system that includes a forward-looking sonar device that operates in an integrated fashion with one or more other sonar devices so that a boater can have a reliable navigation tool while also using sonar for finding fish and other features on the seafloor. The forward-looking sonar can include a transducer array that takes a three-dimensional acoustic reading of the objects and seafloor ahead. The electronics that process the acoustic data can also process data from down-looking sonar, side-scanning sonar, or both and can integrate the information to present an expansive display in the boat, revealing the contents and the floor of the sea in front of, around, and under the boat.

An underwater ultrasonic device is provided. The underwater ultrasonic device comprises: a setting area, wherein the setting area comprises a plurality of setting intervals in sequence, and a plurality of ultrasonic devices arranged in order along the setting area respectively corresponding to the setting intervals, wherein each of the ultrasonic devices has a signal opening angle, and the signal opening angle is greater than the arc angle of the arc interval corresponding to the ultrasonic device.

An underwater ultrasonic device is provided. The underwater ultrasonic device comprises: a setting area, wherein the setting area comprises a plurality of setting intervals in sequence, and a plurality of ultrasonic devices arranged in order along the setting area respectively corresponding to the setting intervals, wherein each of the ultrasonic devices has a signal opening angle, and the signal opening angle is greater than the arc angle of the arc interval corresponding to the ultrasonic device.

A vehicle-mounted assembly is designed to have a vehicle-mounted device attached to a plate-like vehicle body member with a through hole. The vehicle-mounted device includes a cylindrical member fit in a through-hole and a fastener which secures the cylindrical member to the vehicle body member. The cylindrical member includes a cylindrical main body extending along a center axis line, protrusions protruding from the main body in a direction crossing the center axis line. The fastener is held between the protrusions and the vehicle body member. The through-hole is equipped with a vehicle body joint which engages a device joint made of recessed and raised portions of the cylindrical member. The vehicle body joint is arranged at a given location on an inner circumference of the through-hole around a center of the through-hole.

Described herein is an ultrasound-based virus shield. The ultrasound-based virus shield may include an ultrasound sonar emitter configured to emit a first sonar signal including a header with key data, and an ultrasound sonar receiver configured to receive a second sonar signal. The ultrasound-based virus shield may include a processor configured to: calculate a distance between the ultrasound-based virus shield and a subject in response to determining that the second sonar signal includes the key data associated with the first sonar signal, and activate an ultrasound sterilizing emitter in response to determining that the distance calculated is less than a threshold distance. An ultrasound sterilizing emitter of the ultrasound-based virus shield may be configured to emit a sterilizing signal.