An object detection device includes: a transmission/reception unit that has a vibrator capable of transmitting and receiving ultrasound, that causes the vibrator to transmit transmission signals at different timings, and that receives the reception signals returning after being reflected on a circumferentially existing object; an acquisition unit that acquires a first distance to the object, based on a time difference between a transmission timing of a first transmission signal and a reception timing of a first reception signal, and that acquires a relative speed of the object, based on a frequency difference between the first transmission signal and the first reception signal; an estimation unit that estimates a second distance to the object at a transmission timing of a second transmission signal to be transmitted subsequently to the first transmission signal; and an adjustment unit that adjusts the number of waves or a transmission time of the second transmission signal.

Sensing apparatus includes a radiation source, which emits pulses of optical radiation toward multiple points in a target scene. A receiver receives the optical radiation that is reflected from the target scene and outputs signals that are indicative of respective times of flight of the pulses to and from the points in the target scene. Processing and control circuitry selects a first pulse repetition interval (PRI) and a second PRI, greater than the first PRI, from a permitted range of PRIs, drives the radiation source to emit a first sequence of the pulses at the first PRI and a second sequence of the pulses at a second PRI, and processes the signals output in response to both the first and second sequences of the pulses in order to compute respective depth coordinates of the points in the target scene.

Sensing apparatus includes a radiation source, which emits pulses of optical radiation toward multiple points in a target scene. A receiver receives the optical radiation that is reflected from the target scene and outputs signals that are indicative of respective times of flight of the pulses to and from the points in the target scene. Processing and control circuitry selects a first pulse repetition interval (PRI) and a second PRI, greater than the first PRI, from a permitted range of PRIs, drives the radiation source to emit a first sequence of the pulses at the first PRI and a second sequence of the pulses at a second PRI, and processes the signals output in response to both the first and second sequences of the pulses in order to compute respective depth coordinates of the points in the target scene.

A device and method used to increase the resolution when imaging, measuring and inspecting wells, pipes and objects located therein. The device comprises an array of acoustic transducers that both transmit and receive acoustic signals. Scan lines may be overlapped by interlacing transmission and receiving windows thus increasing either the resolution or logging speed drastically compared to conventional approaches. The sequence of the scan lines making up an imaging frame is created by stratifying physically close lines and randomly selecting from within each stratum, preventing interference from neighboring transducers, signals and acoustic artifacts that fundamentally limit logging speed and resolution using conventional methods.

A marine sonar system comprises a sonar transducer, an attitude sensor, and a processing element. The sonar transducer is configured to transmit a sonar beam into a body of water according to a transmit electronic signal, receive reflections of the sonar beam, and output a receive electronic signal according to the reflections of the sonar beam. The attitude sensor is configured to determine an attitude angle of a marine vessel with which the marine sonar system is utilized and to output an attitude electronic signal whose value varies according to the attitude angle. The processing element configured to receive the attitude electronic signal receive and, based on the attitude electronic signal, control the output of the transmit electronic signal to the sonar transducer.

A marine sonar system comprises a sonar transducer, an attitude sensor, and a processing element. The sonar transducer is configured to transmit a sonar beam into a body of water according to a transmit electronic signal, receive reflections of the sonar beam, and output a receive electronic signal according to the reflections of the sonar beam. The attitude sensor is configured to determine an attitude angle of a marine vessel with which the marine sonar system is utilized and to output an attitude electronic signal whose value varies according to the attitude angle. The processing element configured to receive the attitude electronic signal receive and, based on the attitude electronic signal, control the output of the transmit electronic signal to the sonar transducer.

A method for determining the elevation angle and/or azimuth angle of a signal received by an ultrasound sensor includes: providing an ultrasound sensor with a frequency-dependent radiation pattern; transmitting a first ultrasound wave at a first frequency; transmitting a second ultrasound wave at a second frequency different from the first frequency; receiving reflections of the first and second waves, the reflections being caused by an object; and determining the elevation angle of the first and second reflected waves based on amplitudes of the reflections of the first and second waves. Determining the elevation angle (and/or azimuth angle includes calculating a ratio between the amplitudes of received reflections of the first and second waves and mapping a calculated ratio to an elevation angle and/or azimuth angle. The mapping is based on a predetermined ratio curve or ratio dataset which associates a certain amplitude ratio to an elevation angle and/or azimuth angle.

An ultrasonic transducer array combination includes a casing and first, second, and third linear ultrasonic transducer arrays. The casing includes a first-layer housing, a second-layer housing, and a third-layer housing. The first-layer housing, the second-layer housing, and the third-layer housing are connected to each other in a stacked manner and have first, second, and third mounting surfaces in a z-shaped arrangement, respectively. The first linear ultrasonic transducer array is disposed corresponding to the first mounting surface in the first-layer housing. The second linear ultrasonic transducer array is disposed corresponding to the second mounting surface in the second-layer housing. The third linear ultrasonic transducer array is disposed corresponding to the third mounting surface in the third-layer housing, to make the first, second, and third linear ultrasonic transducer arrays spaced away from each other in the z-shaped arrangement.

An apparatus and a method are provided for detecting one or more objects under a surface of a water body. The method includes transmitting one or more ultrasonic waves into the water body according to a transmit beam pattern. The method further includes determining a bottom characteristic of a bottom of the water body and dynamically adjusting the transmit beam pattern, based on the bottom characteristic of the water body.

An apparatus and a method are provided for detecting one or more objects under a surface of a water body. The method includes transmitting one or more ultrasonic waves into the water body according to a transmit beam pattern. The method further includes determining a bottom characteristic of a bottom of the water body and dynamically adjusting the transmit beam pattern, based on the bottom characteristic of the water body.