A method of forming a coherent acoustic beam in a marine environment includes directing each of a plurality of source nodes deployed in the marine environment to move in a respective stationary orbit, transmitting an acoustic source signal from each source node; operating a first control loop to adjust a position of each of the plurality of source nodes within the marine environment; and operating a second control loop to adjust characteristics of the acoustic source signals transmitted by each of the source nodes to form a coherent acoustic beam in the far field of a transmitting array formed by the plurality of source nodes. An acoustic beamforming system configured to operate in a marine environment is also provided.

Systems and methods are provided for vibrations detection in a scene. Systems comprise at least one coherent light source configured to illuminate the scene, an optical unit configured to focus scattered light from the scene onto a pixelated detector, the detector configured to provide pixel intensity signals, and a processing unit configured to analyze the pixel intensity signals over the pixels of the detector to derive a vibration spectrum of elements in the scene that correspond to the pixels. The signal modulation at each pixel may be used to indicate the vibrations of the scene element(s) that corresponds to the pixel(s). Vibration information concerning the scene may be used to direct other methods of vibration measurements, such as speckle interferometry, according to derived vibration images of the scene.

The defect inspection device is provided with a sound wave excitation unit for exciting a sound wave having a time waveform represented by a continuous periodic function to a prescribed position on the surface of an object to be measured, a displacement amount measurement unit for measuring a periodically varying displacement amount generated by the propagation of the sound wave from the prescribed position through the surface at at least three different phases of the periodic variation, and a periodic function acquisition unit for determining a periodic function expressing the periodic variation of the physical quantity on the basis of the displacement amount at the at least three different phases.

A method for the spatial tomography of sound includes the following steps: contactlessly capturing a physical parameter for a first and a second multitude of local regions in space along a first and a second laser beam as well as calculating a voxel model of the sound pressure over time per local region of the first and second multitudes based on the captured physical parameter.

A system for simultaneously detecting audio-characteristics within a body over multiple body surface locations comprising a coherent light source directing at least one coherent light beam toward the body surface locations, an imager acquiring a plurality of defocused images, each is of reflections of the coherent light beam from the body surface locations. Each image includes at least one speckle pattern, each corresponding to a respective coherent light beam and further associated with a time-tag. A processor, coupled with the imager, determines in-image displacements over time of each of a plurality of regional speckle patterns according to said acquired images. Each one of the regional speckle patterns is at least a portion of a respective speckle pattern. Each regional speckle pattern is associated with a respective different body surface location. The processor determines the audio-characteristics according to the in-image displacements over time of the regional speckle patterns.

Optical fiber based acoustic sensors are provided herein. The optical fiber based acoustic sensors described herein include acoustically responsive optical structures configured to detect and receive acoustic signals, including ultrasound signals, and provide associated optical signals to a system for processing and interpretation to implement tracking, location, and imaging capabilities. Optical fiber based sensors provided herein may be disposed at ends of or along the length of optic fibers. Optical fiber based sensors may be included within various devices, including, for example, medical devices. Optical fiber based sensors may provide a compact technology with high sensitivity to visualize and track objects and provide anatomical imaging.

A diagnostic apparatus includes: a storage unit that stores information on a vibration phenomenon in association with a video of a vibration phenomenon for each of kinds of vibration phenomena that can occur in a machine; a video display unit that displays the video of a vibration phenomenon of each of the kinds of vibration phenomena, the video being read by a video reading unit; a phenomenon selection unit that receives a selection result indicating the video of a vibration phenomenon selected by a user from the video of each of the plurality of kinds of vibration phenomena; a diagnosis unit that reads, from the storage unit, the information on a vibration phenomenon stored in association with the video corresponding to the selection result, and outputs the information on a vibration phenomenon that is read as a diagnostic result; and a diagnostic result display unit that displays the diagnostic result.

The present disclosure provides a system, method, and apparatus for compressing and extracting features. The method involves transmitting at least one ultrasound signal into an object at a plurality of different locations on the object. Each of the locations is denoted by an x location and a y location. The method further involves receiving at least one waveform response signal. Also, the method involves generating a three-dimensional (3D) data cube with an X dimension, a Y dimension, and a time dimension. At least one waveform response signal is stored within the 3D data cube at the x location and the y location that is associated with the waveform response signal(s). Further, the method involves transforming at least one waveform response signal of the 3D data cube to produce at least one transformed signal.

This disclosure relates generally to an optical strobing based multi-frequency vibration measurement, and more particularly to systems and methods for autonomous stroboscopic machine inspection for multi-point and multi-frequency vibration measurement. Embodiments of the present disclosure provide for an optical strobing based multi-frequency vibration measurement by selecting a strobe frequency, obtaining one or more image frames, obtaining a marker position, calculating a fast fourier transformation, obtaining one or more peak prominent frequencies, obtaining a product set of the one or more peak prominent frequencies, optimizing the strobing frequency where the value of the product set of the one or more peak prominent frequencies is not equal to an optimum pre-defined system value and detecting and measuring a plurality of vibrations of multiple frequencies by applying a chinese remainder theorem on the product set and the strobe frequency set.

An acoustic wave acquiring apparatus is used that includes: an array light source including a plurality of elements emitting measurement light; a controller controlling the wavelength of the measurement light, for each of or the plurality of elements; a Fabry-Perot interferometer including a first mirror upon which the measurement light is incident and a second mirror upon which an acoustic wave from a subject is incident; an optical sensor measuring a light quantity of reflected light by the first and the second mirror; and a processor acquiring an intensity of the acoustic wave on the basis of a change of the light quantity of the reflected light, which is a distance between the first mirror and the second mirror, occurring due to the incidence of the acoustic wave.