Methods and apparatuses for noise management are disclosed. In one example, a method includes receiving a plurality of noise level measurements taken at a plurality of headsets. The method includes receiving a plurality of location data, including receiving a location data associated with each headset in the plurality of headsets. In one example, the method further includes adjusting an environmental parameter utilizing the noise level measurements. In one example, the method further includes providing location services to a user directing the user to a geographical area having a lower noise level.

The present invention discloses an acoustic camera which comprises an array of arranged microphones. The microphone arrangement can be organized in planar or non-planar form. The device can be handheld, and it comprises a touch screen for interacting with the user. The acoustic camera measures acoustic signal inten-sities in the pointed direction and simultaneously takes an optical image of the measured area, and shows the acoustic signal strengths with the taken image on the screen. The device analyzes the acoustic signals and makes a classification for the sound based on the analysis. If necessary, an alarm is given by the acoustic camera. Besides the handheld manual use, the device can be fixed on a immobile structure or fixed to a movable or rotatable device or a vehicle, such as to a drone.

A handheld acoustic imaging tool and method of imaging acoustic signals includes receiving acoustic signals from a scene, identifying a subset of the acoustic signals based on a predetermined condition of an acoustic parameter of the acoustic signals, and generating a display image using electromagnetic image data representative of electromagnetic radiation from the scene. The display image visually indicates a location in the scene corresponding to the subset of the acoustic signals. Generating the display image may further include using acoustic image data representative of the subset of the acoustic signals, wherein the electromagnetic image data and the acoustic image data are shown together in the display image. In some cases, the acoustic image data in the display image may be palettized according to the acoustic parameter, for example according to an amount, an amount of change, or a rate of change, of the acoustic parameter.

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 system and method for using a microscope to aurally observe a specimen in a fluid is provided. In one embodiment of the present invention, the microscope is modified to include a first beam splitter, splitting a visual of the specimen magnified by the objective lens. A first beam is then provided to an audio frequency modulation sensing (AFMS) device, whose function is to sense photoacoustic modulation of the specimen and to extract aural data, allowing sound energy to be observed by a user (e.g., displayed on screen, played on a speaker, etc.). The second beam is provided to a second beam splitter, allowing visuals to be provided to the eyepiece and to at least one other sensor, where a second visual of the specimen is captured. The second visual can then be displayed on a screen in time synchronization with aural data provided by the AFMS device.

A system for acoustic behavior feedback includes a light emitter and a microphone. Ambient sound data from the microphone may be compared to a threshold sound level, and one of a plurality of settings for the light emitter may be selected based at least in part on the comparison between the ambient sound data and threshold sound level. Each of the plurality of settings corresponds to a respective sound level alert as feedback for at least one person proximate the microphone and the light emitter.

A method of predicting a far-field radiated acoustic field of an object in a fluid is provided. The method includes providing an array of acoustic sensors, wherein the array is a linear array, positioning the array in the fluid proximate to the object, radiating into the fluid, by the object, one or more acoustic signals, measuring, by the acoustic sensors, the acoustic signals, and predicting, by one or more processors, the far-field radiated acoustic field of the object using the measurements of the acoustic signals. The positioning of the array includes orienting the array in a direction that is substantially parallel to a longitudinal axis of the object and positioning the array in a near-field region of the object.

Systems and methods directed toward acoustic analysis can include a plurality of acoustic sensor arrays, each including a plurality of acoustic sensor elements, and a processor in communication with the plurality of acoustic sensor arrays. The processor can be configured to select one or more of the plurality of acoustic sensor arrays based on one or more input parameters, and generate acoustic image data representative of an acoustic scene based on received acoustic data from the selected one or more acoustic sensor arrays. Such input parameters can include distance information and/or frequency information. Different acoustic sensor arrays can share acoustic sensor elements in common or can be entirely separate from one another. Acoustic image data can be combined with electromagnetic image data from an electromagnetic imaging tool to generate a display image.

Systems and methods directed toward acoustic analysis can include an acoustic sensor array comprising a plurality of acoustic sensor elements, an electromagnetic imaging tool, and a processor in communication with the acoustic sensor array and the electromagnetic imaging tool. The processor can be configured to analyze acoustic data to extract one or more acoustic parameters representative of acoustic signals at one or more locations in an acoustic scene and generate a display image that includes electromagnetic image data and acoustic image data. The display image can further include information indicative of the one or more acoustic parameters at one or more locations in the acoustic scene, such as including acoustic image data in the display image at locations in the scene at which the one or more acoustic parameters satisfies a predetermined condition.

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.