An intelligent bed monitoring system and device are provided in this disclosure. The system is applied to a bed frame, and the bed frame includes a bed board. The intelligent bed monitoring system includes a first server, an intelligent bed monitoring device and an electronic device. The intelligent bed monitoring device is communicated with the first server and the electronic device. The intelligent bed monitoring device further includes a pressure sensor, a processor, and a controlling module. The processor is electrically connected with the pressure sensor and the controlling module. The pressure sensor is configured to detect a vibration signal. The processor is configured to generate a physiological information according to the vibration signal, and transmit the physiological information to the first server via a communication interface. The controlling module is configured to control the bed board to adjust the bed board into a plurality of modes.

A vehicular apparatus for active noise control may include: a sensing unit configured to sense information characterizing at least one of an environment inside of a vehicle and an environment outside of the vehicle; and a controller configured extract road roughness information characterizing road roughness from the sensed information, to calculate a convergence coefficient based on the road roughness information, to generate a control signal by applying the convergence coefficient to a control filter coefficient, and to perform active noise control using the control signal.

A vehicular apparatus for active noise control may include: a sensing unit configured to sense information characterizing at least one of an environment inside of a vehicle and an environment outside of the vehicle; and a controller configured extract road roughness information characterizing road roughness from the sensed information, to calculate a convergence coefficient based on the road roughness information, to generate a control signal by applying the convergence coefficient to a control filter coefficient, and to perform active noise control using the control signal.

Method and apparatus for detecting vibrational and/or acoustic transfers in a mechanical system A method and apparatus for detecting vibro-acoustic transfers in a mechanical system are provided. The method comprises: while operating the mechanical system, acquiring, at each of multiple input points, an input signal indicative of a mechanical load acting on the input point, and acquiring, at a response point, a response signal indicative of a mechanical response; training a neural network device using the input signals acquired at the input points and using the response signal acquired at the response point; and, for each of the input points: providing only the input signal acquired at the respective input point to the trained neural network device and obtaining, from the neural network device, a contribution signal indicative of a predicted contribution of the respective input signal to the response signal. Vibro-acoustic transfers may be detected solely based on operational data, thereby reducing time and a cost for performing a transfer analysis.

Method and apparatus for detecting vibrational and/or acoustic transfers in a mechanical system A method and apparatus for detecting vibro-acoustic transfers in a mechanical system are provided. The method comprises: while operating the mechanical system, acquiring, at each of multiple input points, an input signal indicative of a mechanical load acting on the input point, and acquiring, at a response point, a response signal indicative of a mechanical response; training a neural network device using the input signals acquired at the input points and using the response signal acquired at the response point; and, for each of the input points: providing only the input signal acquired at the respective input point to the trained neural network device and obtaining, from the neural network device, a contribution signal indicative of a predicted contribution of the respective input signal to the response signal. Vibro-acoustic transfers may be detected solely based on operational data, thereby reducing time and a cost for performing a transfer analysis.

According to one embodiment, a structure evaluation system includes an impact imparting unit, a sensor, and a structure evaluation device. The impact imparting unit applies impacts to a structure. The impact imparting unit applies the impacts at a frequency equal to or less than a frequency determined in accordance with an intensity at which the impacts are imparted. The sensor detects elastic waves. The structure evaluation device evaluates a deterioration state of the structure on the basis of the detected elastic waves.

An electromagnetic multi-function multi-purpose chordo-phone musical instrument upon which any form or style of music may be played in any position by a performer standing or seated, in a fixed location or moving throughout a performance venue. The player may initiating the vibrations of each string, any combination of strings, or all of the strings with a plectrum or the fingers of one or both hands, singly or in any combination and such vibrations will continue until their eventual natural termination unless damped and/or muted by the player using the fingers or the palm of one or both hands singly or in any combination. The shape and style of the rigid frame of the instrument is not limited by the need for frets, a fretboard, or keys.

According to one embodiment, a vibration detecting device includes a housing, a vibration sensor in the housing, a circuit board in the housing, a flexible wiring component, a first face, and a second face. The vibration sensor is housed in the housing. An electric component that processes a detection signal of the vibration sensor is provided on the circuit board. The wiring component electrically connects the vibration sensor and the circuit board. The first face is provided on the housing and is configured to be attached to an object. The second face is provided inside the housing and is inclined with respect to the first face, the vibration sensor being attached thereto.

According to one embodiment, a vibration detecting device includes a housing, a vibration sensor in the housing, a circuit board in the housing, a flexible wiring component, a first face, and a second face. The vibration sensor is housed in the housing. An electric component that processes a detection signal of the vibration sensor is provided on the circuit board. The wiring component electrically connects the vibration sensor and the circuit board. The first face is provided on the housing and is configured to be attached to an object. The second face is provided inside the housing and is inclined with respect to the first face, the vibration sensor being attached thereto.

A method determines a fluid quantity relating to a fluid flowing in a measuring device. The measuring device has a measuring tube which receives the fluid, and first and second oscillation transducers. An excitation of a total wave, which is conducted through a wall of the measuring tube, by the first and/or second oscillation transducer, by wave components which are conducted in the wall being excited by the oscillation transducers in a plurality of excitation regions. These wave components are superposed to form the total wave. A distance between the centers of the excitation regions and the excitation frequency are selected such that an oscillation mode to be attenuated is quenched by destructive interference of the wave components in a propagation direction. Excitation of a compression oscillation of the fluid by the total wave occurs. Measurement data relating to the compression oscillation is used to determine the fluid quantity.