A system and method for using a microscope to at least haptically observe a specimen in a fluid is provided. In one embodiment of the present invention, an audio frequency modulation sensing (AFMS) device is used to convert an optical signal from the specimen into an electrical signal. A haptic feedback device is then used to convert the electrical signal in at least vibrations, thereby providing a user with haptic feedback associated with the optical signal from the specimen. In another embodiment, a second electrical signal can be provided to a second haptic feedback (e.g., shaker, piezo electric, electric current inducing, etc.) device in the fluid, thereby allowing for bidirectional haptic feedback between the user and the specimen. In other embodiments, aural data can be extracted from the electrical signal and presented to the user either alone in in synchronization with video data (e.g., from a video camera).

An environmental analysis system and method. Remote sensing devices detect nonvisual information. One or more loudspeakers are each associated with one or more of the plurality of remote sensing devices to determine acoustic properties of an area. Another implementation relates to a method for environmental analysis where non-visual information is detected. The non-visual information is classified and is communicated to a server.

Provided is a directional acoustic sensor including a support member, and a plurality of resonators extending in a longitudinal direction with respect to the support member, wherein each of the plurality of resonators includes a driver configured to move based on an input sound signal, and a sensor configured to sense a capacitance change based on an air gap that changes based on a movement of the driver.

An ultrasonic detector has a housing containing a transducer, a battery or other power supply, and any other necessary electronics. At a front end of the housing is a socket into which one of a plurality of interchangeable probes can be inserted. At the rear end of the housing, there is a handle by which an operative can hold the detector in use. On the inside of the housing, extending at least partially into the handle, is an elongate chamber within which at least one probe can be stored. A cover of the handle closes a rear end of the probe storage chamber and can be removed to expose a portion of the probe storage chamber and allow a probe to be inserted or removed.

An ultrasonic detector has a housing containing a transducer, a battery or other power supply, and any other necessary electronics. At a front end of the housing is a socket into which one of a plurality of interchangeable probes can be inserted. At the rear end of the housing, there is a handle by which an operative can hold the detector in use. On the inside of the housing, extending at least partially into the handle, is an elongate chamber within which at least one probe can be stored. A cover of the handle closes a rear end of the probe storage chamber and can be removed to expose a portion of the probe storage chamber and allow a probe to be inserted or removed.

Sensor devices, systems, and methods for measuring different components of a flow are provided. A sensing arrangement includes a substrate and first and second sensor arrays on the substrate. The first sensor array sensing elements are distributed to obtain measurement data indicative of a first property of an operating environment, such as a turbulent component of a fluid flow. The second sensor array sensing elements are interspersed amongst the first sensor array and distributed to obtain measurement data indicative of a second property of the operating environment, such as an acoustic component of the fluid flow.

A detection circuit detects a signal output from an element that receives an acoustic wave. The detection circuit is configured so as not to conduct a detection operation during a period in which the element does not receive the acoustic wave.

A system and method for using a microscope to at least haptically observe a specimen in a fluid is provided. In one embodiment of the present invention, an audio frequency modulation sensing (AFMS) device is used to convert an optical signal from the specimen into an electrical signal. A haptic feedback device is then used to convert the electrical signal in at least vibrations, thereby providing a user with haptic feedback associated with the optical signal from the specimen. In another embodiment, a second electrical signal can be provided to a second haptic feedback (e.g., shaker, piezo electric, electric current inducing, etc.) device in the fluid, thereby allowing for bidirectional haptic feedback between the user and the specimen. In other embodiments, aural data can be extracted from the electrical signal and presented to the user either alone in in synchronization with video data (e.g., from a video camera).

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.

It is provided a method for classifying vibrations detected in a structure of a building. The method is performed in a vibration classifier and comprising the steps of: determining a measurement period of a vibration signal; splitting the measurement period in a plurality of sequential sub-periods; calculating, for each one of the sub-periods, a variation indicator of at least one component of the vibration signal; and classifying a source of the vibration signal based on the variation indicators.