This invention relates to a microelectromechanical loudspeaker implemented as a system-on-chip or system-in-package. The microelectromechanical loudspeaker includes a microelectromechanical sound-generating device implemented in a microelectromechanical system (MEMS) and a microphone mounted on the cover or integrated in the cover, wherein the microphone is positioned adjacent to one of the sound outlet openings of the cover. The MEMS comprises a cavity formed between a planar cover, a planar base and circumferential sidewalls provided between the cover and the base. The MEMS further comprises a plurality of movable actuators for generating sound. The actuators are provided in the cavity between the cover and the base, and wherein the cover and the base have a plurality of sound outlet openings to emit sound in a direction transverse to the cover and the base, respectively.

The invention provides a diaphragm and a preparation method thereof, and an MEMS microphone. The diaphragm includes a intermediate vibration part and a fixed part surrounding the vibration part. The vibration part includes multiple vibration sub-parts, which are distributed stepwise along the vibration direction of the diaphragm. Multiple vibration sub-parts are distributed stepwise along the vibration direction of diaphragm. The effective area of the diaphragm is increased, and the stress can be adjusted by the height of the ladder and its inclination angle. The mechanical sensitivity of the MEMS microphone containing this diaphragm is improved, resulting in a high-performance, small-sized MEMS microphone.

One of the main objects of the present invention is to provide a silicon microphone that is reasonably designed and can effectively improve electroacoustic performance. To achieve the above-mentioned objects, the present invention provides a silicon microphone including a substrate with a back cavity; and a capacitor system attached to and insulated from the substrate. The capacitor system includes a diaphragm and a back plate spaced from the diaphragm. At least one through hole is formed in the back plate. The diaphragm includes a vibration part in a middle thereof and a fixed part surrounding and spaced from the vibration part by a first slit. An orthographic projection of the vibration part on the substrate partially overlaps with the substrate thereby forming a second slit between the vibration part and the substrate and communicating with the first slit and the back cavity, respectively.

A microphone assembly can include a microelectromechanical systems (MEMS) transducer comprising a transducer substrate, a diaphragm oriented substantially parallel to the transducer substrate and spaced apart from the transducer substrate to form a gap, and a counter electrode coupled to the transducer substrate, the counter electrode positioned between the diaphragm and the transducer substrate. The MEMS transducer can generate a signal representative of a change in capacitance between the counter electrode and the diaphragm. A back volume of the MEMS transducer can be an enclosed volume positioned between the transducer substrate and the diaphragm. The microphone assembly can include an integrated circuit that receives the signal, wherein every point within the back volume is less than a thermal boundary layer thickness from a nearest solid surface at an upper limit of an audio frequency band that the integrated circuit is monitoring.

The present invention provides a general MEMS device having a pair of quadrilateral insert and trench. An air channel/space includes a first internal wall and a second internal wall for air to flow between. A quadrilateral trench is recessed from the first internal wall, and a quadrilateral insert is extended from the second internal wall and inserted into the trench. In capacitive MEMS microphone, the spatial relationship between the insert and the trench can vary or oscillate. The quadrilateral insert & trench serve as an air flow restrictor or a leakage prevention structure which keeps the sound frequency response plot of the microphone flatter in the range of 20 Hz to 1000 Hz. The level of the air resistance may be controlled e.g. by the depth of quadrilateral trench/slot etched on the substrate.

The electronic device including the plurality of acoustic ducts according to various example embodiments may include the main body; the PCB disposed on the main body; the microphone including the microphone body connected to the PCB and the diaphragm connected to the microphone body; the main acoustic duct penetrating the main body and configured to connect the space in which the diaphragm is placed to the external space of the electronic device; and the sub acoustic duct penetrating the main body and configured to connect the external space of the electronic device to the main acoustic duct. In addition, various example embodiments are possible.

A MEMS microphone according to an embodiment comprises a substrate including an air chamber in a central portion, a back-plate disposed above the substrate and including a plurality of penetration holes through which a sound wave passes, and a vibration membrane disposed between the back-plate and the substrate, forming compressive residual stress, having a base form convexly bent toward the back-plate, and configured to vibrate a sound pressure transferred through the plurality of penetration holes.

An MEMS having a layered structure includes a cavity disposed in the layered structure and fluidically coupled to an external environment of the layered structure through at least one opening in the layered structure. The MEMS includes an interaction structure movably disposed in a first MEMS plane and in the cavity along a plane direction and configured to interact with a fluid in the cavity, wherein movement of the interaction structure is causally related to movement of the fluid through the at least one opening. The MEMS further includes an active structure disposed in a second MEMS perpendicular to the plane direction, the active structure mechanically coupled to the insulation structure and configured such that an electrical signal at an electrical contact of the active structure is causally related to a deformation of the active structure, wherein the deformation of the active structure is causally related to movement of the fluid.

A sound pickup device includes a diaphragm that vibrates according to an acoustic pressure of input sound, an acoustic member having a sound channel formed to guide sound to the diaphragm, and a Helmholtz resonator having an opening formed in a wall surface surrounding the sound channel, in which the diaphragm is disposed inside a microphone in which a sound hole is formed, the acoustic member includes: a first substrate that has a through hole formed at the same position as the sound hole, and is attached to the microphone; and a second substrate that has the sound channel formed at a position corresponding to the through hole, and is attached to the first substrate.

One of the main objects of the present invention is to provide a vibration sensor with improved sensitivity. To achieve the above-mentioned objects, the present invention provides a vibration sensor including a circuit board assembly including an installation slot; a housing fixed to the circuit board assembly for forming an accommodation space cooperatively with the circuit board assembly; and a diaphragm assembly accommodated in the accommodation space and secured to the circuit board assembly. The diaphragm assembly includes a gasket fixed to the circuit board assembly, and a first diaphragm fixed to a side of the gasket away from the circuit board assembly.