Abstract: Provided is a condenser microphone having a plurality of condenser microphone units connected in series to improve output sensitivity, and a simplified circuit configuration. At least one of the preceding condenser microphone units, excepting a last condenser microphone unit, and an adjacent succeeding condenser microphone unit are directly connected to transmit an audio signal obtained from the at least one of the preceding condenser microphone units to the adjacent succeeding condenser microphone unit. An impedance converter using an active element is connected to the last condenser microphone unit, and the audio signals obtained from the condenser microphone units are added and output from the impedance converter using the active element.

Abstract: The invention provides a micro-electro-mechanical device which includes a substrate, an electrode, and a diaphragm. The electrode includes plural vent holes. The diaphragm is disposed above and in parallel to the electrode, to form a capacitive sensor with the electrode. The diaphragm includes plural ribs protruding upward and/or downward from the diaphragm; the ribs are respectively disposed in correspondence to the plural vent holes and do not overlap nor contact the electrode. A method for making the micro-electro-mechanical device is also provided according to the present invention.

Abstract: A diaphragm is arranged on the upper surface of a silicon substrate so as to cover a chamber in the silicon substrate. Multiple anchors are provided on the upper surface of the silicon substrate, and the lower surfaces of corner portions of the diaphragm are supported by the anchors. Also, a fixed electrode plate is provided above the diaphragm with an air gap therebetween. In a view from a direction perpendicular to the upper surface of the silicon substrate, the entire length of the outer edge of the diaphragm located between adjacent anchors is located outward of a line segment that circumscribes the edges of the adjacent anchors on the side distant from the center of the diaphragm. Also, one or two or more through-holes are formed in the diaphragm in the vicinity of the anchors.

Abstract: An electrode extraction terminal extracting a generated current by contacting with a fixed electrode is disposed inside a unit case, and can change from a cardioid to a hyper cardioid. The electrode extraction terminal includes an electrode rod portion having a projection portion at a tip side; and a pedestal portion having a flat surface surrounded by a peripheral wall portion having a sitting height thereof same as that of the projection portion of the electrode rod portion, and facing the fixed electrode under a shape with a size showing a cardioid in directivity, wherein the flat surface is located orthogonal to an axis direction of the electrode rod portion. In a peripheral surface area of one or more sound holes of the flat surface, a minute concave-convex surface is provided to reduce an acoustic resistance value to show a hyper cardioid in directivity.

Abstract: A transducer and electronic device including the same are disclosed. In one aspect, the transducer includes a first electrode and a membrane arranged over the first electrode and spaced apart from the first electrode. The membrane at least partially overlaps the first electrode. The transducer also includes a first support member that supports the membrane. The membrane includes a vibrating portion that is movable in a direction substantially perpendicular to the membrane and a fixed portion that is supported by the first support member. The first support member is configured to adjust the distance between the fixed portion and the first electrode.

Abstract: A capacitive microphone may include a housing, a membrane, and a first backplate, wherein a first insulating layer may be disposed on a first side of the first backplate facing the membrane and a second insulating layer may be disposed on a second side of the first backplate opposite to the first side of the first backplate. A further insulating layer may be disposed on a side wall of at least one of a plurality of perforation holes in the first backplate. Each conductive surface of the first backplate may be covered with insulating material.

Abstract: A microelectromechanical systems device package includes a MEMS device mounted in flip-chip technology on a substrate. A film of non-evaporable getter material is disposed between the substrate and the MEMS device. A cover structure encapsulates the MEMS device. This invention further provides a method for manufacturing the microelectromechanical systems device package.

Abstract: Some embodiments relate to a manufacturing process that combines a MEMS capacitor of a microelectromechanical systems (MEMS) microphone and an integrated circuit (IC) onto a single substrate. A dielectric is formed over a device substrate. A conductive diaphragm and a conductive backplate are formed within the dielectric, with a sacrificial portion of the dielectric between them. A first recess is formed, which extends through the dielectric to an upper surface of the conductive diaphragm. A second recess is formed, which extends through the substrate and dielectric to a lower surface of the conductive backplate. The sacrificial layer is removed to create an air gap between the conductive diaphragm and the conductive backplate. The air gap joins the first and second recesses to form a cavity that extends continuously through the dielectric and the substrate. The present disclosure is also directed to the semiconductor structure of the MEMS microphone resulting from the manufacturing process.

Abstract: A micro electro-mechanical system (MEMS) microphone is provided. The microphone includes: a package substrate having a port disposed through the package substrate, wherein the port is configured to receive acoustic waves; and a lid coupled to the substrate and forming a package. The MEMS microphone also includes a MEMS acoustic sensor disposed in the package and positioned such that the acoustic waves receivable at the port are incident on the MEMS acoustic sensor. The MEMS acoustic sensor includes: a back plate positioned over the port at a first location within the package; and a diaphragm positioned at a second location within the package, wherein a distance between the first location and the second location forms a defined sense gap, and wherein the MEMS microphone is designed to withstand a bias voltage between the diaphragm and the back plate greater than or equal to about 15 volts.

Abstract: A top port MEMS microphone package includes a substrate having a back volume expanding aperture therein. A MEMS microphone electronic component is mounted to the substrate directly above the back volume expanding aperture such that an aperture of the MEMS microphone electronic component is in fluid communication with the back volume expanding aperture. A lid having a lid cavity is mounted to the substrate. The back volume expanding aperture couples the aperture of the MEMS microphone electronic component to the lid cavity. By coupling the lid cavity to the aperture with the back volume expanding aperture, the resulting back volume is essentially the size of the entire top port MEMS microphone package. In this manner, the noise to signal ratio is minimized thus maximizing the sensitivity of the top port MEMS microphone package as well as the range of applications.

Abstract: An acoustic transducer has a substrate having a cavity that is open at a top of the substrate, a vibration electrode film provided above the substrate so as to cover the cavity, and a fixed electrode film provided a distance above the vibration electrode film. A gap is formed between an upper surface of the substrate and a lower surface of the vibration electrode film around the cavity. In the gap across which the upper surface of the substrate and the lower surface of the vibration electrode film face each other, a narrow portion of the gap that is narrower than another portion of the gap is disposed. The narrow portion of the gap extends linearly.

Abstract: A MEMS device and a method of making a MEMS device are disclosed. In one embodiment a semiconductor device comprises a substrate, a moveable electrode and a counter electrode, wherein the moveable electrode and the counter electrode are mechanically connected to the substrate. The movable electrode is configured to stiffen an inner region of the movable membrane.

Abstract: A microphone structure of an MEMS device has a layer construction including: a base substrate; a deflectable microphone diaphragm at least partly spanning a through-opening in the substrate; a deflectable electrode of a microphone condenser system; a stationary counter-element having ventilation openings situated in the layer construction over the microphone diaphragm and acting as a bearer for a stationary electrode of the microphone condenser system. The diaphragm is bonded into the layer construction on the substrate via a flexible beam. The otherwise free edge region of the diaphragm is curved in a pan shape, so that it extends both vertically and also in some regions laterally beyond the edge region of the through-opening, and the edge region of the through-opening forms a lower stop for the diaphragm movement.

Abstract: An acoustic transducer has a vibrating film and a fixed film formed above an opening portion of a substrate, and at least a first sensing portion and a second sensing portion that detect sound waves using change in capacitance between a vibrating electrode provided in the vibrating film and a fixed electrode provided in the fixed film, convert the sound waves into electrical signals, and output the electrical signals. In the first sensing portion and the second sensing portion, the fixed film is used in common, and the vibrating electrode is divided into a first sensing region and a second sensing region that respectively correspond to the first sensing portion and the second sensing portion. In the first sensing portion, a protrusion portion that protrudes toward the vibrating electrode is provided on a region of the fixed film that opposes the first sensing region.

Abstract: Embodiments show a method for fabricating a cavity structure, a semiconductor structure, a cavity structure for a semiconductor device and a semiconductor microphone fabricated by the same. In some embodiments the method for fabricating a cavity structure comprises providing a first layer, depositing a carbon layer on the first layer, covering at least partially the carbon layer with a second layer to define the cavity structure, removing by means of dry etching the carbon layer between the first and second layer so that the cavity structure is formed.

Abstract: A microphone unit includes a microphone substrate. A plurality of diaphragm units are disposed on the microphone substrate. Each of the diaphragm units includes a diaphragm. A plurality of partition walls are disposed on the microphone substrate. Each of the partition walls surrounds the diaphragm so as to define a first area. A signal processor is disposed at a second area outside the first area and is configured to process signals output from the diaphragm units.

Abstract: This disclosure provides example methods, devices, and systems for a two dimensional material-based pressure sensor. A sensor device is provided that includes a substrate having a back electrode, a conductive layer in communication with the back electrode, and an insulating layer coupled to the conductive layer. The insulating layer includes one or more cavity regions. A sensor membrane comprising a two-dimensional material is disposed adjacent to the insulating layer and covering at least one of the one or more cavity regions. A first sensing electrode is in electrical communication with a first region of the sensor membrane, and a second sensing electrode is in communication with a second region of the sensor membrane. The sensor membrane is configured to respond to pressure changes exerted on the sensor device.

Abstract: A capacitance-type transducer has a substrate having a cavity, a vibrating electrode plate disposed above the substrate, a back plate disposed on the substrate, a fixed electrode plate disposed on the back plate opposite the vibrating electrode plate, a plurality of holes formed in the back plate and the fixed electrode plate, and a protrusion disposed on the back plate at a location opposing the vibrating electrode plate. In a view from a direction perpendicular to an upper surface of the substrate, a shortest distance from a cross-sectional center of the protrusion to an edge of a hole adjacent to the protrusion is larger than a shortest distance from a center of a region that is surrounded by the holes but not provided with the protrusion to an edge of a hole in the periphery.

Abstract: A capacitive micro-electromechanical system (MEMS) microphone includes a semiconductor substrate having an opening that extends through the substrate. The microphone has a membrane that extends across the opening and a back-plate that extends across the opening. The membrane is configured to generate a signal in response to sound. The back-plate is separated from the membrane by an insulator and the back-plate exhibits a spring constant. The microphone further includes a back-chamber that encloses the opening to form a pressure chamber with the membrane, and a tuning structure configured to set a resonance frequency of the back-plate to a value that is substantially the same as a value of a resonance frequency of the membrane.

Abstract: A MEMS acoustic transducer, for example, a microphone, includes a substrate provided with a cavity, a supporting structure, fixed to the substrate, a membrane having a perimetral edge and a centroid, suspended above the cavity and fixed to the substrate the membrane configured to oscillate via the supporting structure. The supporting structure includes a plurality of anchorage elements fixed to the membrane, and each anchorage element is coupled to a respective portion of the membrane between the centroid and the perimetral edge of the membrane.

Abstract: A micromechanical structure for a MEMS capacitive acoustic transducer, has: a substrate made of semiconductor material, having a front surface lying in a horizontal plane; a membrane, coupled to the substrate and designed to undergo deformation in the presence of incident acoustic-pressure waves; a fixed electrode, which is rigid with respect to the acoustic-pressure waves and is coupled to the substrate by means of an anchorage structure, in a suspended position facing the membrane to form a detection capacitor. The anchorage structure has at least one pillar element, which is at least in part distinct from the fixed electrode and supports the fixed electrode in a position parallel to the horizontal plane.

Abstract: In accordance with an embodiment, an interface circuit includes a variable voltage bias generator coupled to a transducer, and a measurement circuit coupled to an output of the transducer. The measurement circuit is configured to measure an output amplitude of the transducer. The interface circuit further includes a calibration controller coupled to the bias generator and the measurement circuit, and is configured to set a sensitivity of the transducer and interface circuit during an auto-calibration sequence.

Abstract: A microphone has a package, and an acoustic sensor, an under surface of which is fixed to an inner face of the package. The acoustic sensor has a substrate having a plurality of hollows penetrating the substrate from a top surface to an under surface, and a capacitor structure made by a movable electrode plate and a fixed electrode plate disposed above each of the hollows. A package sound hole is opened in the package in a position opposed to the under surface of the acoustic sensor. A dent which is communicated with each of the hollows and open below the under surface side of the substrate is formed below the under surface of the substrate. A height of the dent measured from the under surface of the substrate is equal to or less than half of a height of the hollow.

Abstract: A manufacturing method of a sensor device integrated with ultrasonic transducer and microphone is to form a first support structure, a back plate, a second support structure, a membrane and electrodes on a substrate. The substrate is divided into a first region and a second region. The first electrode, the third electrode, a part of the back plate, a part of the second support structure and a part of the membrane that are above the first region form the ultrasonic transducer. The first support structure, the second electrode, the fourth electrode, a part of the back plate, a part of the second support structure and a part of the membrane that are above the second region form the microphone. The ultrasonic transducer and the microphone are simultaneously manufactured.

Abstract: A microphone includes an interposer, a lid, and a base. The interposer includes at least one wall portion that forms a cavity. The wall portion includes a first side and a second side that are opposite from each other. The lid is coupled to the first side of the interposer and the base is coupled to the second side of the interposer such that the lid and the base enclose the cavity. A microelectromechanical system (MEMS) device is disposed in the cavity. The interposer structurally supports one or both of the lid and the base. The interposer includes a plurality of plated regions that are configured to electrically connect the lid and the base. The plated regions are configured to at least partially be exposed and open to the cavity.

Abstract: An acoustic apparatus includes a substrate, micro electro mechanical system (MEMS) die, and an integrated circuit. The substrate includes a permanent opening that extends there through. The micro electro mechanical system (MEMS) die is disposed over the permanent opening and the MEMS die includes a pierce-less diaphragm that is moved by sound energy. A first temporary opening extends through the substrate. The integrated circuit is disposed on the substrate and includes a second opening. The first temporary opening and the second opening are generally aligned. A cover that is coupled to the substrate and encloses the MEMS die and the integrated circuit. The cover and the substrate form a back volume, and the diaphragm separates the back volume from a front volume. The first temporary opening is unrestricted at a first point in time to allow gasses present in the back volume to exit through the temporary opening to the exterior and the pierce-less diaphragm prevents the gasses from passing there through.

Abstract: A MEMS device and a method of making a MEMS device are disclosed. In one embodiment a semiconductor device comprises a substrate, a moveable electrode and a counter electrode, wherein the moveable electrode and the counter electrode are mechanically connected to the substrate. The movable electrode is configured to stiffen an inner region of the movable membrane.

Abstract: A MEMS backplate enables MEMS microphones with reduced parasitic capacitance. The MEMS backplate includes a central area and a perforation in the central area. A suspension area surrounds the central area at least partially. An aperture is disposed in the suspension area.

Abstract: A silicon condenser microphone is disclosed. The silicon condenser microphone includes a substrate having a top surface, a lower surface opposed to the top surface, and a recess concave from the top surface toward the lower surface. The recess includes a bottom for carrying a chip thereon. The microphone further includes a transducer spanning the recess. By virtue of this configuration, the size of the microphone is reduced, and acoustic performance of the microphone is accordingly improved.

Abstract: A microphone structure is disclosed. The microphone structure comprises a substrate penetrated with at least one opening chamber and having an insulation surface. A conduction layer is arranged on the insulation surface and arranged over the opening chamber. An insulation layer is arranged on the conduction layer and having a opening to expose a part of the conduction layer as a vibration block arranged over the opening chamber. At least two first patterned electrodes are arranged on the insulation layer and arranged over the vibration block. At least two second patterned electrodes are arranged over the opening chamber, arranged on the vibration block and separated from the first patterned electrodes by at least two first gaps. When the vibration block vibrates, the vibration block moves the second patterned electrodes whereby the second patterned electrodes and the first patterned electrodes perform differential sensing.

Abstract: An electronic device is formed by depositing polyimide on a glass substrate. A conductive material is deposited on the polyimide and patterned to form electrodes and signal traces. Remaining portions of the electronic device are formed on the polyimide. A second polyimide layer is then formed on the first polyimide layer. The glass substrate is then removed, exposing the electrodes and the top surface of the electronic device.

Abstract: A microphone system has a base forming a base aperture, and a lid coupled to the base to form a package having an interior chamber. The system also has a member coupled with the base within the interior chamber, and a microphone die coupled to the member within the interior chamber. The member is positioned between the base and the microphone die and has a member aperture that is laterally offset from the base aperture. The member aperture, member, and base together form an acoustic path between the base aperture and the microphone die.

Abstract: A module includes a sensor device, a mounting substrate that has a plurality of mounting faces, a portion between the mounting faces adjacent to each other being foldable, a supporting member having fixing faces, wherein the sensor device is mounted on at least one of the mounting faces, each of the mounting faces is disposed along each of the fixing faces, and the sensor device is disposed on the supporting member side.

Abstract: A MEMS acoustic transducer is provided, which includes a substrate, a MEMS chip, and a housing. The substrate has a first opening area and a lower electrode layer disposed over a surface of the substrate, wherein the first opening area includes at least one hole allowing acoustic pressure to enter the MEMS acoustic transducer. The MEMS chip is disposed over the surface of the substrate, including a second opening area and an upper electrode layer partially sealing the second opening area, wherein the upper electrode layer and the lower electrode layer, which are parallel to each other and have a gap therebetween, form an induction capacitor. The housing is disposed over the MEMS chip or the surface of the substrate creating a cavity with the MEMS chip or the substrate. In addition, a method for fabricating the above MEMS acoustic transducer is also provided.

Abstract: MEMS devices with a rigid backplate and a method of making a MEMS device with a rigid backplate are disclosed. In one embodiment, a device includes a substrate and a backplate supported by the substrate. The backplate includes elongated protrusions.

Abstract: Example acoustic bandgap devices provided that can be fabricated in a semiconductor fabrication tool based on design check rules. An example device includes a substrate lying in an x-y plane and defining an x-direction and a y-direction, an acoustic resonant cavity over the substrate, and a phononic crystal disposed over the acoustic resonant cavity by generating the phononic crystal as a plurality of unit cells disposed in a periodic arrangement. Each unit cell include: (a) at least one higher acoustic impedance structure having a longitudinal axis oriented in the y-direction and a thickness in the x-direction greater than or about equal to a minimal feature thickness of the semiconductor fabrication tool, and (b) at least one lower acoustic impedance material bordering at least a portion of the at least one higher acoustic impedance structure and forming at least a portion of a remainder of the respective unit cell.

Abstract: Provided are an acoustic sensor and a method of manufacturing the same. The acoustic sensor includes a substrate including an acoustic chamber, a first hole, and a second hole, penetrating the substrate, a lower electrode pad extended onto a top surface of the substrate while covering a sidewall of the first hole, a diaphragm pad extended onto the top surface of the substrate while covering a sidewall of the second hole, a lower electrode provided on the acoustic chamber and connected to the lower electrode pad, and a diaphragm above the lower electrode while being separated from the lower electrode and connected to the diaphragm pad.

Abstract: Embodiments of the invention include a microphone assembly having a microphone soldered on a bottom side of a bottom ported microphone flex circuit carrier, and a rigid coupler soldered on the top side of the carrier, opposite to the microphone. The coupler is inserted into and sealed to a microphone boot made out of a soft material. The top of the boot may be sealed to an electronic audio device into which the assembly is integrated. Acoustic openings through the housing, boot, coupler and carrier allow acoustic signals to reach the microphone. However, the seals between the housing, boot, coupler, carrier and microphone provide sound isolation, as well as a moisture and dust seal between the ambient and the inside of the electronic device. Such seals may include rings, grooves, threads, O-rings between the boot and coupler; or a reinforcing ring around the soft material of the boot.

Abstract: The present invention refers to a flat back plate, e.g. for MEMS capacitors e.g. for MEMS microphones. For that the back plate comprises a tensile element that exerts a horizontal tensile stress on its environment.

Abstract: There is provided a process for assembly of a capacitor microphone. The capacitor microphone has a frame and a counterpart electrode. The counterpart electrode is positioned in the frame and held. Adhesive is applied so that the counterpart electrode is glued directly to the frame.

Abstract: A microphone has a base substrate having a main surface, an acoustic sensor mounted on the main surface, and a circuit element that processes a signal output from the acoustic sensor. The acoustic sensor has a sensor substrate having a first surface opposed to the base substrate, a second surface on a side opposite to the first surface, and a cavity formed while piercing the sensor substrate from the first surface to the second surface, and a movable electrode that covers the cavity from the second surface side. A through-hole is formed in the base substrate while piercing the base substrate in a thickness direction to communicate with the cavity. The through-hole overlaps the sensor substrate when viewed in the thickness direction of the base substrate.

Abstract: The electroacoustic transducer according to the invention has at least one diaphragm and at least one counterelectrode. In that case the diaphragm and/or the counterelectrode each have at least two electrically mutually insulated segments. In that arrangement the segments are so adapted that different electric signals are supplied or that different electric signals are delivered in response to exposure to sound of the sound transducer.

Abstract: Methods and apparatus to collect media identifying data are disclosed. An example method includes collecting audio data through a sound hole. The sound hole has a chamfered opening. The sound hole has an effective length-to-width ratio which is equal to or less than about 1.25 and analyzing the audio data to obtain media identifying data.

Abstract: A cost-effective and extremely space-saving module approach is provided for at least two micromechanical sensor elements having the same packaging requirements. The sensor module described here includes at least two micromechanical sensor elements whose sensor function is based on the direct or indirect impact of a measuring medium. The at least two sensor elements are situated in a shared housing having at least one access opening for the measuring medium, and the at least two sensor elements are stacked with one component back side on one component front side, so that the upper sensor element at least partially covers the active area of the lower sensor element, while still ensuring the impact of the measuring medium, which is used for the sensor function, on the active area of the lower sensor element.

Abstract: An improved method for manufacturing an MEMS microphone with a double fixed electrode is specified which results in a microphone which likewise has improved properties.

Abstract: A method for fabricating MEMS device includes providing a silicon substrate. A structural dielectric layer is formed over a first side of the silicon substrate. Structure elements are embedded in the structural dielectric layer. The structure elements include a conductive backplate disposed over the silicon substrate, having venting holes and protrusion structures on top of the conductive backplate; and diaphragm located above the conductive backplate by a distance. A chamber is formed between the diaphragm and the conductive backplate. A cavity is formed in the silicon substrate at a second side. The cavity corresponds to the structure elements. An isotropic etching is performed on a dielectric material of the structural dielectric layer to release the structure elements. A first side of the diaphragm is exposed by the chamber and faces to the protrusion structures of the conductive backplate. A second side of the diaphragm is exposed to an environment space.

Abstract: A microphone has a base substrate comprising a main surface, an acoustic sensor mounted on the main surface, and a circuit element stacked on the acoustic sensor. A hollow space is formed between the acoustic sensor and the circuit element. The acoustic sensor has a sensor substrate having a first surface opposed to the base substrate, a second surface on a side opposite to the first surface, and a cavity formed while recessed with respect to the second surface, and a movable electrode that covers the cavity from the second surface side. A through-hole is formed in the base substrate while piercing the base substrate in a thickness direction. A communication hole is formed in the sensor substrate while piercing the sensor substrate from the first surface to the second surface. The communication hole causes the through-hole and the hollow space to communicate with each other.

Abstract: The present invention provides a unidirectional microphone by adding an output from an omnidirectional condenser microphone unit and an output from a bi-directional ribbon microphone unit together. A condenser microphone unit 10 and a ribbon microphone unit 20 are connected in series via a step-up transformer 30, and the respective sound signals from the microphone units 10 and 20 are added together and are output from a source S of an FET 14.

Abstract: The present invention relates to a MEMS microphone and a method of manufacturing the same, the MEMS microphone comprising: a monolithic silicon chip incorporating an acoustic sensing element and one or more conditioning CMOS integrated circuits; a silicon-based carrier chip having an acoustic cavity; a substrate for surface mounting the assembly of the monolithic chip and the silicon-based carrier chip thereon; a conductive cover attached and electrically connected to the substrate to accommodates the assembly of the monolithic chip and the silicon-based carrier chip; and an acoustic port formed on either the conductive cover or the substrate for an external acoustic wave to reach the acoustic sensing element, wherein the monolithic silicon chip, the silicon-based carrier chip and the acoustic port are configured in such a way that the diaphragm of the acoustic sensing element can be vibrated by the external sound wave from one side thereof.

Abstract: A rigid, flat plate diaphragm for an acoustic device is illustrated. The internal supporting structure of the diaphragm provides a combination of torsional and translational stiffeners, which resemble a number of crossbars. These stiffeners brace and support the diaphragm motion, thus causing its response to not be adversely affected by fabrication stresses and causing it to be very similar in dynamic response to an ideal flat plate operating in a frequency range that extends well beyond the audible.