Abstract: A microelectromechanical system includes a spacer layer, a first corrugated conductive diaphragm, and a second corrugated conductive diaphragm. The spacer layer includes counter electrode walls, slots and support walls extending along a first direction. The counter electrode walls, slots and support walls are arranged alternately in a second direction. The first corrugated conductive diaphragm includes first crests and first troughs arranged alternately in the second direction. The second corrugated conductive diaphragm includes second crests and second troughs arranged alternately in the second direction. The spacer layer is received in a cavity formed by the first and second corrugated conductive diaphragms. The support walls are respectively sandwiched between the aligned first troughs and second crests. The counter electrode walls are respectively suspended in the corresponding chambers formed between the aligned first crests and second troughs.

Abstract: The invention provides a method for manufacturing a MEMS microphone, including the steps of: providing a base and preparing a first diaphragm on a first surface of the base; preparing a back plate on a surface of the first diaphragm opposite to the first surface; forming a first gap between the first diaphragm and the back plate; preparing a second diaphragm; forming a second gap between the second diaphragm and the back plate; preparing electrodes; forming a back cavity by etching the surface opposite to the first surface.

Abstract: The disclosure relates to a MEMS sensor and an assembly including the MEMS sensor and an electrical circuit disposed in an assembly housing. The sensor includes a suspended structure (148) having a top diaphragm (118), a central electrode (120) and a bottom diaphragm (122) connected by a pillar portion (134). A peripheral portion of the suspended structure is coupled to a support structure (114), forming a low pressure cavity (130). The MEMS sensor includes a top electrode (136) disposed between the top diaphragm and the central electrode and a bottom electrode (138) disposed between the bottom diaphragm and central electrode each coupled to the support structure, wherein in the event of a sound pressure condition, the suspended structures moves up or down together, while the top electrode and the bottom electrode remain substantially stationary.

Abstract: A method, apparatus, and computer program product are provided for encoding audio events as geo-referenced audio events for use in location establishment. Methods may include: receiving first audio data from a first sensor; identifying, within the first audio data, a first audio event, where the first audio event satisfies at least one predefined criteria; identifying a location corresponding to the first audio event; encoding the first audio event in a database to correspond to the location; receiving second audio data from a second sensor; identifying, within the second audio data, a second audio event; correlating the second audio event with the first audio event; and providing the location in response to the second audio data. The at least one criteria may include a statistically significant change in amplitude in the audio data.

Abstract: A loudspeaker diaphragm (12) comprising a woven fibre body supports damping material (25), for example PVA polymer, on a rearward-facing surface (24). The woven fibre body may be formed of lengths (14) non-metallic fibre material (for example glass fibre) coating with a thin metal coating (32). The mass of the layer of damping material (25) may be less than the mass of the woven fibre body. An attractive sparkly looking loudspeaker diaphragm (12) may thus be provided which damps undesirable vibration whilst providing a flatter frequency-response curve (50).

Abstract: An MEMS microphone is provided, comprising: a first substrate; a vibration diaphragm supported above the first substrate by a spacing portion, the first substrate, the spacing portion, and the vibration diaphragm enclosing a vacuum chamber, and a static deflection distance of the vibration diaphragm under an atmospheric pressure being less than a distance between the vibration diaphragm and the first substrate; and a floating gate field effect transistor outputting a varying electrical signal, the floating gate field effect transistor including a source electrode and a drain electrode both provided on the first substrate and a floating gate provided on the vibration diaphragm.

Abstract: The present disclosure provides a radio and method for automatically adjusting, in response to ambient noise, the volume setting of a radio. The radio comprises a microphone for receiving ambient audio and generating a microphone signal; a codec for receiving the microphone signal and generating a processor signal representative of the ambient audio; and processor circuitry operable to receive the processor signal, determine an ambient audio level in response to the processor signal, and determine an adjusted radio volume to generate a radio volume control signal, wherein the adjusted radio volume is determined by calculating a difference between a baseline volume level and ambient audio level and adding a current volume level setting, wherein the codec is also operable to receive the radio volume control signal and generate an output signal to adjust the radio volume setting to maintain a net difference between the adjusted radio volume and ambient audio.

Abstract: A MEMS can include a substrate including a first side and a second side on an opposite side of the substrate from the first side. The MEMS device can include an aperture running through the substrate from the first side to the second side. The substrate can have an edge surrounding the aperture on the first side. The MEMS device can include a diaphragm located over the aperture on the first side. The MEMS device can include a support structure that extends at least partially across the aperture from the edge.

Abstract: In an embodiment a device includes a substrate including an upper substrate surface and a lower substrate surface and a membrane-layer suspended above the upper substrate surface, wherein the substrate includes a recess penetrating the substrate between the lower substrate surface and the upper substrate surface, wherein the membrane-layer spans the recess, wherein the recess includes an upper recess region, an intermediate recess region, and a lower recess region, wherein the upper recess region is a part of the recess in direct vicinity to the upper substrate surface, the intermediate recess region is a part of the recess directly below the upper recess region, and the lower recess region is a part of the recess other than the upper recess region and the intermediate recess region, and wherein a cross-sectional area of the upper recess region determined parallel to the upper substrate surface is larger than a respective cross-sectional area of the intermediate recess region.

Abstract: A method for detecting ambient noise to change the playing voice frequency and a sound playing device thereof are disclosed. The method includes the following steps: obtaining an input voice; detecting an ambient noise, and analyzing a noise frequency range of the ambient noise; determining whether a consonant frequency range of the input voice falls within the noise frequency range; if yes, adjusting the frequency of the consonant of the input voice to avoid the noise frequency range to form a modified voice; and playing an output voice, wherein the output voice includes the modified voice.

Abstract: A microelectromechanical system (MEMS) transducer for integration in a microphone assembly is designed to produce heat-generated acoustic signals. The MEMS transducer generally comprises a substrate having an aperture, a transduction element located at least partially over the aperture and coupled to the substrate, electrical contacts coupled to the transduction element, and a resistor integrated with the substrate or the transduction element. The resistor is coupled to electrical contacts that are electrically isolated from the contacts of the MEMS transducer or transduction element. The transduction element includes an insulating material coupled to the substrate. The transduction element comprises a fixed electrode and a movable electrode located at least partially over the aperture of the substrate. The fixed electrode or the moving electrode is formed on the insulating material. The resistor can be formed on the insulating material or suspended from the insulating material.

Abstract: The present disclosure relates to a sensor assembly (100) comprising: a base (102) having a host-device interface (104), a lid (108) mounted on the base (102) to form a housing (110), the lid (108) having an insulative structural core (112) between an inner metal skin (114) and an outer metal skin (116); and a transduction element (118) disposed in the housing (112). Advantageously, the lid (108) of the sensor assembly (100) can help to minimize and reduce undesirable thermo-acoustic effects produced by external environmental conditions that may result in acoustic artifacts.

Abstract: Methods and systems for performing modified reverb techniques for audio signals are described. The method may involve receiving an audio signal, a modal reverb effect to be applied to the audio signal, and an indication of a plurality of frequencies. Modes of vibration of a space simulated by the reverb effect may be separated into a set of frequencies included in the input, and a set frequencies not included in the input. The modal reverb effect may be modified by separately adjusting the separate sets of modes of vibration. The modified effect may then be applied to the audio signal.

Abstract: Disclosed is a device for introducing loudspeaker harmonic nonlinearities to a signal without outputting the signal as audio or sound through a loudspeaker and recording the output audio or sound. The device includes a resistive element and an inductive element. The resistive element includes a hollow core and a first wire wound around the hollow core in a first direction. The inductive element is inserted within the hollow core of the resistive element, and includes a metal-based core and a second wire wound around the metal-based core in an opposite second direction. A signal or current is first passed through the inductive element, creating electromagnetic distortion between the resistive element and the inductive element that simulates inductance of the loudspeaker voice-coil. The electromagnetic distortion alters the signal by introducing harmonic nonlinearities into the signal.

Abstract: An in-the-ear hearing aid device is disclosed. The device at least one electro-acoustic transducer, and at least one sensor or at least one active electronic component. The at least one electro-acoustic transducer comprises a capsule enclosing a transducer sound active part and a transducer air volume. The transducer air volume is air volume which is enclosed by said capsule and which is in fluid-connection with said transducer sound active part. At least a portion of said at least one sensor or of said at least one active electronic component is provided within said transducer air volume.

Abstract: An earphone includes a main body unit in which an outside shape of one edge portion is formed in an arc shape to be fitted into a pinna, a sound tube portion extending from the main body unit to a first surface side of the main body unit, and a supporter for covering at least the first surface side at a side of the one edge portion in the main body unit. The supporter includes a protruding portion protruded toward the first surface side in an arc shape corresponding to an arc shape of the outside shape of the one edge portion in the main body unit.

Abstract: A thermal excitation acoustic-wave-generating device includes a first acoustic wave source that includes a first heating element and a substrate that includes a main surface along which the first heating element is disposed, a second acoustic wave source that includes a second heating element and a facing body that includes a main surface along which the second heating element is disposed, and a pair of electrodes connected to the first and second heating elements. The first and second acoustic wave sources are arranged such that the first and second heating elements are separated from each other and face each other. The pair of electrodes are disposed between the first and second acoustic wave sources.

Abstract: The technology described in this document can be embodied in a computer-implemented method of controlling a wearable audio device configured to provide an audio output. The method includes receiving data indicating the wearable audio device is proximate a geographic location associated with a localized audio message, and determining that the localized audio message has a higher priority compared to at least one other localized audio message associated with another geographical location proximate to the wearable audio device. The method also includes, responsive to determining that the localized audio message has the higher priority, providing a prompt to initiate playback of the localized audio message with the higher priority to a user of the wearable audio device, and initiating playback of the localized audio message with the higher priority at the wearable audio device in response to actuation of the prompt by the user.

Abstract: System for automatic right-left ear detection for headphone comprising: first earcup and second earcup that are identical. Each of first and second earcups includes: first microphone located on perimeter of each earcup, when first earcup is worn on user's right ear first microphone of first earcup is at location farthest from user's mouth when headphone is worn in normal wear position; second microphone located on perimeter of each earcup, when first earcup is worn on user's right ear, second microphone of first earcup is at location closer than first microphone of first earcup to user's mouth; third microphone located inside each earcup facing user's ear cavity, fourth microphone located at perimeter and bottom center portion of each earcup and facing exterior of each earcup, and fifth microphone located on perimeter of each earcup above and to left of second microphone when looking at outside housing of each earcup.

Abstract: A MEMS capacitive microphone according to the present invention is configured such that a support plate 120 from which an inside thereof has been removed in a plane is attached to supports 110 each having an end fixed to a substrate 100, an anchor 130 is attached to an edge region of the support plate 120, an edge of a diaphragm 200 is supported by the anchor 130, and a “substrate-free area” includes the anchor 130 in a plan view, and pluralities of moving comb fingers 300 and stiffeners are attached to a top or bottom or a top and bottom of the diaphragm 200, and the supports 110 support the stationary comb fingers 400 arranged at predetermined intervals on both sides of the moving comb fingers 300 in a plan view.