Abstract: A microelectromechanical system includes a lower membrane including a plurality of troughs and crests arranged alternately, an upper membrane including a plurality of troughs and crests arranged alternately, and a spacer layer disposed between the lower membrane and the upper membrane. The spacer layer includes counter electrode walls and support walls made of nitride, the counter electrode walls being provided with conductive elements. Chambers are formed between the troughs of the lower membrane and the crest of the upper membrane and the counter electrode walls are suspended in the chambers respectively. The support walls are sandwiched between the crests of the lower membrane and the troughs of the upper membrane with a space formed between adjacent support walls. The spaces between adjacent support walls may be empty or filled with oxide. Unwanted capacitance between the upper and lower membranes is reduced significantly.

Abstract: An MEMS device, including: a substrate having a back cavity; a diaphragm connected to the substrate and covers the back cavity, the diaphragm includes first and second membranes arranged oppositely, and accommodation space is formed therebetween; a counter electrode in the accommodation space and includes annular beams and first spokes, the annular beams are successively arranged at intervals, and the first spokes extend radially outward from an axis of the counter electrode, an end of the first spokes is connected to the substrate, and two adjacent first spokes and two adjacent annular beams jointly form a first through hole; and a support arranged corresponding to the first through hole, and opposite ends of the support are respectively connected to the first and second membranes. This configuration is more sensitive to sound pressure and is conducive to realizing low-noise microphone while optimizing sensitivity.

Abstract: An MEMS diaphragm and an MEMS sensor. The MEMS diaphragm includes: a main diaphragm including a main body sensing portion and beam portions, and the beam portions are connected to an outer edge of the main body sensing portion; an additional material layer provided on the beam portions or provided on both an edge of the main body sensing portion and on the beam portions. The intrinsic tensile stress of the additional material layer is greater than an intrinsic tensile stress of the main body sensing portion. An additional material layer is provided, which mechanically reinforces the diaphragm region experiencing high stress during a pressure pulse, and the intrinsic tensile stress of the additional material layer is greater than the main body sensing portion, thereby ensuring the compliance of the main diaphragm.

Abstract: Provided is an electrostatic clutch. The electrostatic clutch includes: multiple arrays of HIN electrodes, a respective pass-through channel being formed between any two arrays of the multiple arrays of HIN electrodes; and multiple arrays of biased electrodes, each array of the multiple arrays of biased electrodes moving back and forth in the respective pass-through channel such that electrostatic force is generated between the multiple arrays of biased electrodes and the multiple arrays of HIN electrodes. Such configuration allows microphone performance over a wide range of atmospheric pressures which is likely expected by applications. This is achieved electrostatically in a purely passive way having advantages over other designs which require complex electronics and active control. Physically decoupling the membrane and sense structure simplifies design of the sense structure as only small AC perturbations of the rotor is considered with no DC changes in rotor position.

Abstract: Provided is a MEMS device. The MEMS device includes: substrate having back cavity passing through; diaphragm connected to the substrate and covers the back cavity, the diaphragm comprises first and second membranes, and accommodating space is formed between the first and second membranes; supports arranged in the accommodating space, and opposite ends of the support are connected to the first and second membranes; counter electrode arranged in the accommodating space, the first and second membranes each include conductive and second regions, ventilation slots are annularly spaced on the diaphragm along circumferential direction and penetrate through the first and second membranes, the electrode region extends from center of the first and second membranes toward but does not reach the ventilation slots. Through design of the first and second membranes and the electrode region, sensitivity of the microphone is increased.

Abstract: A microphone chip and a microphone. The microphone chip includes: a base including an inner cavity; a diaphragm including a diaphragm inner part and a diaphragm outer part that are connected to the diaphragm inner part, the diaphragm being supported on the base by means of the diaphragm outer part, and the diaphragm inner part being arranged to be opposite to the inner cavity; and a limiting member supported on the base and located at two opposite sides of the diaphragm along a vibration direction of the diaphragm, the limiting member being spaced apart from the diaphragm, and the limiting member being configured to limit an amplitude of the diaphragm inner part. When the diaphragm inner part moves to a certain displacement, the limiting member can limit further movement of the diaphragm inner part, thereby reducing a damage risk caused by excessive displacement of the diaphragm under high sound pressure.

Abstract: Provided is an MEMS device, including: a base, a rear cavity; a vibrating diaphragm, the vibrating diaphragm including an upper diaphragm and a lower diaphragm, and an accommodation space being formed between the upper and lower diaphragms; a counter electrode arranged in the accommodation space; and supporting members concentrically arranged and spaced apart. The supporting members are arranged between the upper and lower diaphragms and are spaced apart from the counter electrode, two opposite ends of each supporting member are connected to the upper and lower diaphragms, and at least one of the supporting members is provided with first cavities. An upper ventilation hole and a lower ventilation hole are respectively formed at a position of the upper diaphragm and a position of the lower diaphragm corresponding to one of the first cavities; and the upper ventilation hole, the first cavity and the lower ventilation hole communicate with each other.

Abstract: Provided is a MEMS condenser microphone, including a base plate, a spacer and a membrane. The membrane is supported above the base plate by the spacer. The base plate, the spacer, and the membrane enclose a vacuum cavity. An end of the membrane close to the vacuum cavity is connected, by means of a connecting rod, to an electrostatic clutch. The electrostatic clutch is connected to a capacitive sensing structure. The microphone has the advantage of allowing microphone performance over a wide range of atmospheric pressures which is likely expected by customers. This is achieved electrostatically in a purely passive way which has an advantage over other designs which require complex electronics and active control. Physically decoupling the membrane and sense structure simplifies the design of the sense structure as only small AC perturbations of the rotor need to be considered with no DC changes in rotor position.

Abstract: Provided is a MEMS device. The MEMS device includes: substrate having back cavity passing therethrough; diaphragm connected to the substrate and covers the back cavity, the diaphragm comprises first and second membranes, and accommodating space is formed between the first and second membranes; supports arranged in the accommodating space, and opposite ends of the support are connected to the first and second membranes; counter electrode arranged in the accommodating space, the first and second membranes each include conductive and second regions, the second region is formed by semiconductor material without doping conductive ions. Through design of the first and second membranes as the first region and the second region, respectively, the second region is formed by semiconductor material without doping conductive ions, and the first region is formed by doping conductive ions in the semiconductor material, so that the compliance performance is improved and not at risk of delamination.

Abstract: Provided is an electrostatic clutch. The electrostatic clutch includes: multiple arrays of HIN electrodes, a respective pass-through channel being formed between any two arrays of the multiple arrays of HIN electrodes; and multiple arrays of biased electrodes, each array of the multiple arrays of biased electrodes moving back and forth in the respective pass-through channel such that electrostatic force is generated between the multiple arrays of biased electrodes and the multiple arrays of HIN electrodes. Such configuration allows microphone performance over a wide range of atmospheric pressures which is likely expected by applications. This is achieved electrostatically in a purely passive way having advantages over other designs which require complex electronics and active control. Physically decoupling the membrane and sense structure simplifies design of the sense structure as only small AC perturbations of the rotor is considered with no DC changes in rotor position.

Abstract: Provided is a MEMS condenser microphone, including a base plate, a spacer and a membrane. The membrane is supported above the base plate by the spacer. The base plate, the spacer, and the membrane enclose a vacuum cavity. An end of the membrane close to the vacuum cavity is connected, by means of a connecting rod, to an electrostatic clutch. The electrostatic clutch is connected to a capacitive sensing structure. The microphone has the advantage of allowing microphone performance over a wide range of atmospheric pressures which is likely expected by customers. This is achieved electrostatically in a purely passive way which has an advantage over other designs which require complex electronics and active control. Physically decoupling the membrane and sense structure simplifies the design of the sense structure as only small AC perturbations of the rotor need to be considered with no DC changes in rotor position.

Abstract: Provided is a MEMS device. The MEMS device includes: substrate having back cavity passing through; diaphragm connected to the substrate and covers the back cavity, the diaphragm comprises first and second membranes, and accommodating space is formed between the first and second membranes; supports arranged in the accommodating space, and opposite ends of the support are connected to the first and second membranes; counter electrode arranged in the accommodating space, the first and second membranes each include conductive and second regions, ventilation slots are annularly spaced on the diaphragm along circumferential direction and penetrate through the first and second membranes, the electrode region extends from center of the first and second membranes toward but does not reach the ventilation slots. Through design of the first and second membranes and the electrode region, sensitivity of the microphone is increased.

Abstract: Provided is a MEMS device. The MEMS device includes: substrate having back cavity passing therethrough; diaphragm connected to the substrate and covers the back cavity, the diaphragm comprises first and second membranes, and accommodating space is formed between the first and second membranes; supports arranged in the accommodating space, and opposite ends of the support are connected to the first and second membranes; counter electrode arranged in the accommodating space, the first and second membranes each include conductive and second regions, the second region is formed by semiconductor material without doping conductive ions. Through design of the first and second membranes as the first region and the second region, respectively, the second region is formed by semiconductor material without doping conductive ions, and the first region is formed by doping conductive ions in the semiconductor material, so that the compliance performance is improved and not at risk of delamination.

Abstract: Provided is an MEMS device, including: a base, a rear cavity; a vibrating diaphragm, the vibrating diaphragm including an upper diaphragm and a lower diaphragm, and an accommodation space being formed between the upper and lower diaphragms; a counter electrode arranged in the accommodation space; and supporting members concentrically arranged and spaced apart. The supporting members are arranged between the upper and lower diaphragms and are spaced apart from the counter electrode, two opposite ends of each supporting member are connected to the upper and lower diaphragms, and at least one of the supporting members is provided with first cavities. An upper ventilation hole and a lower ventilation hole are respectively formed at a position of the upper diaphragm and a position of the lower diaphragm corresponding to one of the first cavities; and the upper ventilation hole, the first cavity and the lower ventilation hole communicate with each other.

Abstract: Provided is a MEMS device and an electro-acoustic transducer. The MEMS device includes: a substrate having a cavity passing through the substrate; a diaphragm connected to the substrate and covers the cavity. The diaphragm includes oppositely arranged first and second membranes. The first membrane is on one side of the second membrane facing away from the cavity and includes a first protrusion extending away from the second membrane, the first protrusion has a first groove opening towards the second membrane. The second membrane includes a second protrusion extending away from the first membrane and opposite to the first protrusion, the second protrusion has a second groove opening towards the first membrane. By providing first and second protrusions on first and second diaphragms to form a corrugated diaphragm, the internal stress and stiffness of the diaphragm decreases, which effectively increases the mechanical sensitivity of the MEMS device.

Abstract: Provided is an MEMS device, including: a substrate having back cavity passing thererthrough; a diaphragm connected to the substrate and covers the back cavity, the diaphragm includes first and second membranes, and accommodating space formed therebetween; a counter electrode; and support loop members arranged concentrically. Opposite ends of the support loop member are connected to the first and second membranes. The support loop members are arranged at intervals. Each support loop member has first sections concentrically arranged as a loop member at intervals. A first notch is formed between two adjacent first sections. In at least one support loop member, the first section has second sections concentrically arranged as a loop member at intervals. A second notch is formed between two adjacent second sections. By a larger first section, distance between adjacent first sections is larger, the technical problem that large number of slots required for counter electrode is solved.

Abstract: A microelectromechanical system includes an enclosure defining a cavity and an opening communicating with the cavity; a membrane mounted at the opening; a cantilever located within the cavity, the at least one cantilever comprising a first end, a second end and a fulcrum located between the first end and the second end; a plunger positioned between the membrane and the cantilever and configured to transfer displacement of the membrane to the first end of the cantilever; and a sensing member connected to the second end of the cantilever. The distance between the first end and the fulcrum is less than that between the second end and the fulcrum. The microelectromechanical system has the advantages of high SNR, small package size and high sensitivity. The membrane has a stiffness order of magnitude higher than a conventional membrane, which avoids mechanical collapse and large DC deformation under 1 atm.

Abstract: An MEMS microphone includes a substrate including a back volume provided inside the substrate and an opening provided at an upper surface of the substrate to communicate the back volume; a sensing device provided at an inner side wall of the back volume; a first cantilever provided inside the back volume and including end portions coupling with the sensing device; a first membrane provided at the opening; a second membrane provided inside the back volume; and second cantilevers, each of which includes a first end mechanically supporting the first cantilever, and a second end connected to the second membrane. By suspending the first cantilever on the second cantilevers, the end portions of the first cantilever always couple with a preset position of the sensing device. Thus, the DC offset of the displacement of the membrane can be prevented.

Abstract: Provided is a micro-electro-mechanical system and an electro-acoustic conversion device having the micro-electro-mechanical system. The micro-electro-mechanical system includes: first and second membranes arranged opposite to each other; support members arranged between the first and second membranes; and an opening provided on the first and/or second membranes. Each support member includes support walls, and opposite ends of each of the support walls are connected to the first and second membranes. The first and second membranes, and two adjacent support walls in one support member are enclosed to form a first chamber. The opening is configured to link the first chamber with the outside. By arranging a supporting member composed of support walls and providing an opening on the first and/or second membranes, the compliance of the first or second membrane is increased, and the inter-plate capacitance therebetween is reduced.

Abstract: A comb drive for MEMS device includes a stator and a rotor displaceable relative to the stator in a first direction. The stator includes stator comb fingers and the rotor includes rotor comb fingers. The stator comb fingers are coupled to two high impedance nodes to form high impedance node domains arranged in the first direction. The rotor comb fingers are coupled to two oppositely biased electrodes to form oppositely biased domains. Pairs of capacitors with opposite acoustic polarity are respectively formed between the high impedance node domains and the oppositely biased domains. The comb drive of the present invention has increased electrostatic sensitivity for a given unit cell cross-sectional area whilst maintaining an acceptable capacitance and linearity of voltage signal vs displacement. Extra force shim unit cells may be used, which allows for the stiffness between the rotor and stator to be controlled and reduced to zero for a particular displacement range, without impacting sensitivity.