An alternate venting path can be employed in a sensor device for pressure equalization. A sensor component of the device can comprise a diaphragm component and/or backplate component disposed over an acoustic port of the device. The diaphragm component can be formed with no holes to prevent liquid or particles from entering a back cavity of the device, or gap between the diaphragm component and backplate component. A venting port can be formed in the device to create an alternate venting path to the back cavity for pressure equalization for the diaphragm component. A venting component, comprising a filter, membrane, and/or hydrophobic coating, can be associated with the venting port to inhibit liquid and particles from entering the back cavity via the venting port, without degrading performance of the device. The venting component can be designed to achieve a desired low frequency corner of the sensor frequency response.

The present invention proposes a system for continuous monitoring of dynamic equipment condition through the use of vibration, temperature and/or acoustic noise sensor modules associated with wireless technology (wireless) or LTE (Long Term Evolution). The system is characterized by having vibration, temperature and/or acoustic noise sensor modules. The sensor modules of the system also have the functionality to measure the sound signature of the machines.

The optical fiber sensing system is provided. The optical fiber sensing system comprises an optical fiber measuring module, a floating module, and a containing structure. The floating module disposed in the containing structure has a plurality of floating units. Each floating unit has a mass element and a vibration absorbing structure. It is adapted to apply appropriate tensile force to the optical fiber measuring module by adjusting counterweight of the quality bodies. The vibrating influence to the optical fiber measuring system would be reduced through the vibration absorbing structure.

The optical fiber sensing system is provided. The optical fiber sensing system comprises an optical fiber measuring module, a floating module, and a containing structure. The floating module disposed in the containing structure has a plurality of floating units. Each floating unit has a mass element and a vibration absorbing structure. It is adapted to apply appropriate tensile force to the optical fiber measuring module by adjusting counterweight of the quality bodies. The vibrating influence to the optical fiber measuring system would be reduced through the vibration absorbing structure.

Passive device for broadband acoustic acquisition (3) that can communicate with a digital processing unit (4), the device including a plurality of microphone sensors (7) that can generate an electric signal (8) that is representative of an acoustic pressure (9) received, electronics for processing and digitizing (12) electric signals being able to adapt the electric signals and transform them into digital signals (13) of acoustic pressure, transfer electronics (14) being able to communicate with a digital processing unit (4) and to make possible the transfer of the digital signals of acoustic pressure to the digital processing unit. The microphone sensors and the transfer electronics are mounted on a multifunctional rigid support element (17) that incorporates the processing and digitizing electronics.

Passive device for broadband acoustic acquisition (3) that can communicate with a digital processing unit (4), the device including a plurality of microphone sensors (7) that can generate an electric signal (8) that is representative of an acoustic pressure (9) received, electronics for processing and digitizing (12) electric signals being able to adapt the electric signals and transform them into digital signals (13) of acoustic pressure, transfer electronics (14) being able to communicate with a digital processing unit (4) and to make possible the transfer of the digital signals of acoustic pressure to the digital processing unit. The microphone sensors and the transfer electronics are mounted on a multifunctional rigid support element (17) that incorporates the processing and digitizing electronics.

An electronic device includes a processor, and a memory containing instructions that, when executed by the processor, cause the electronic device to learn a sound emitted by a legacy device and to issue an output when the electronic device subsequently hears the sound. For example, the electronic device can receive a training input and extract a compact representation of a sound in the training input, which the device stores. The device can receive an audio signal corresponding to an observed acoustic scene and extract a representation of the observed acoustic scene from the audio signal. The electronic device can determine whether the sound is present in the observed acoustic scene at least in part from a comparison of the representation of the observed acoustic scene with the representation of the sound. The electronic device emits a selected output responsive to determining that the sound is present in the acoustic scene.

A method for measuring noise is disclosed. The method includes a sound pressure measurement step for measuring sound pressure information from a noise source with a sound pressure sensor. The method further includes a distance determination step for determining distance determinant information indicative of distance between the noise source and the sound pressure sensor. The sound pressure measurement step and the distance determination step are executed in an unmanned aerial measurement apparatus. The unmanned aerial measurement apparatus includes an unmanned aerial vehicle. The method includes controlling flight of the unmanned aerial measurement apparatus. A related unmanned aerial measurement apparatus is also disclosed.

A measuring apparatus (10) for determining the flow speed of a fluid (12) flowing in a conduit (14) using at least one ultrasonic transducer (18a-b) that is attached to the conduit wall (22) from the outside and has an oscillating body (34) that couples to a part region (32) of the conduit wall (22) that acts as a membrane of the ultrasonic transducer (18a-b) that can vibrate, characterized in that a coupling piece (36) whose cross-section is smaller than the cross-section of the oscillating body (34) is arranged between the membrane (32) and the oscillating body (34).

Systems and methods are disclosed for passively detecting air turbulence using one or more infrasonic sensors mounted on an aircraft. The system may include one or more infrasonic sensors that are mounted on the aircraft and configured to detect infrasound. The system may also include a processor configured to receive output signals from the one or more infrasonic sensors and detect air turbulence away from the aircraft based on the output signals received from the one or more infrasonic sensors. The detected air turbulence may include natural or man-made turbulence including wake turbulence, clear air turbulence, mountain waves, or events such as a rocket launch.