An acoustic transducer includes: a vibration portion including: a diaphragm; and a vibrator on the diaphragm; a frame surrounding the vibration portion; and a connecting portion connecting the vibration portion and the frame. The vibrator is configured to drive the diaphragm

A microphone package and an electronic apparatus including the same are provided. The microphone package includes a substrate in which an acoustic hole and a via hole are formed; an acoustic sensor attached to a front surface of the substrate and covering the acoustic hole; a first electrode pad provided on the front surface of the substrate; a second electrode pad provided on a rear surface of the substrate and electrically connected to the first electrode pad through the via hole; and a third electrode pad on a side surface of the substrate and electrically connected to the second electrode pad.

The present disclosure provides an acoustic output apparatus. The acoustic output apparatus may include a vibration assembly and a mass element. The vibration assembly may include a piezoelectric structure and a vibration element. The piezoelectric structure may be configured to convert an electrical signal into mechanical vibrations, and the vibration element may be connected to the piezoelectric structure at a first position of the piezoelectric structure and configured to receive the mechanical vibrations to generate an acoustic signal. The mass element may be connected to the piezoelectric structure at a second position of the piezoelectric structure.

The present disclosure provides an acoustic output apparatus. The acoustic output apparatus may include a vibration assembly and a mass element. The vibration assembly may include a piezoelectric structure and a vibration element. The piezoelectric structure may be configured to convert an electrical signal into mechanical vibrations, and the vibration element may be connected to the piezoelectric structure at a first position of the piezoelectric structure and configured to receive the mechanical vibrations to generate an acoustic signal. The mass element may be connected to the piezoelectric structure at a second position of the piezoelectric structure.

An information handling system includes an outer housing and a processor and a memory disposed in the outer housing. The processor is configured to execute instructions to process information. The memory is configured to store the information. The information handling system includes a piezoelectric transducer disposed in the outer housing and mechanically coupled to a surface held by the outer housing. The information handling system includes a sensor disposed in the outer housing and configured to generate an indicator of user presence in a zone proximate to the piezoelectric transducer and above a second side of the surface. The information handling system includes a controller disposed in the outer housing and coupled to the memory. The controller is configured to selectively configure the piezoelectric transducer to be responsive to a first subsystem or to be responsive to a second subsystem according to the indicator of user presence.

An information handling system includes an outer housing and a processor and a memory disposed in the outer housing. The processor is configured to execute instructions to process information. The memory is configured to store the information. The information handling system includes a piezoelectric transducer disposed in the outer housing and mechanically coupled to a surface held by the outer housing. The information handling system includes a sensor disposed in the outer housing and configured to generate an indicator of user presence in a zone proximate to the piezoelectric transducer and above a second side of the surface. The information handling system includes a controller disposed in the outer housing and coupled to the memory. The controller is configured to selectively configure the piezoelectric transducer to be responsive to a first subsystem or to be responsive to a second subsystem according to the indicator of user presence.

A system for enhancing the separation of particles or fluids from water is disclosed. A tank or bioreactor is provided with an open submersible acoustophoretic separator. The separator captures and holds fluid droplets or particles such as cells, permitting them to coalesce or agglomerate until they are large enough and have sufficient buoyant or weight force to float/sink to the top/bottom of the tank or bioreactor. In a tank or bioreactor, the separator captures and holds particles until they are large enough that their weight causes them to settle out of the host fluid. The acoustophoretic device thus speeds up separation of the particles or droplets from the host fluid.

A vibration sensor having a moveable mass being suspended in a suspension member and being adapted to move in response to vibrations or accelerations. The moveable mass and the suspension member are rigidly connected across one or more gaps formed by respective opposing surfaces of the moveable mass and the suspension member. The vibration sensor includes a damping arrangement having a damping substance. The moveable mass is arranged to interact directly or indirectly with the damping substance in order to reduce a mechanical resonance peak of the vibration sensor.

A combined MicroElectroMechanical structure (MEMS) includes a first piezoelectric membrane having one or more first electrodes, the first piezoelectric membrane being affixed between a first holder and a second holder; and a second piezoelectric membrane having an inertial mass and one or more second electrodes, the second piezoelectric membrane being affixed between the second holder and a third holder.

The present disclosure is of a bone conduction sound transmission device. The bone conduction sound transmission device comprises a laminated structure and a base structure. The laminated structure is formed by a vibration unit and an acoustic transducer unit. A base structure is configured to load the laminated structure, and at least one side of the laminated structure is physically connected to the base structure. The base structure vibrates based on an external vibration signal, and the vibration unit deforms in response to the vibration of the base structure; and the acoustic transducer unit generates an electrical signal based on the deformation of the vibration unit.