A piezoelectric microelectromechanical system microphone comprises a support substrate, a cantilever sensing element including a piezoelectric material attached to the support substrate and configured to deform and generate an electrical potential responsive to impingement of sound waves on the cantilever sensing element the cantilever sensing element divided into a plurality of cantilevers having gaps between side edges of adjacent cantilevers, and a compliant material disposed in at least a portion of the gaps between adjacent cantilevers to improve the performance of the piezoelectric microelectromechanical system microphone.

In some embodiments, a microphone system may include a deformable element that may be made of a material that is subject to deformation in response to external phenomenon. Sensing ports may be in contact with a respective region of the deformable element and may be configured to sense a deformation of a region of the deformable element and generate a signal in response thereto. The plurality of signals may be useable to determine spatial dependencies of the external phenomenon. The external phenomenon may be pressure and the signals may be useable to determine spatial dependencies of the pressure.

In some embodiments, a microphone system may include a deformable element that may be made of a material that is subject to deformation in response to external phenomenon. Sensing ports may be in contact with a respective region of the deformable element and may be configured to sense a deformation of a region of the deformable element and generate a signal in response thereto. The plurality of signals may be useable to determine spatial dependencies of the external phenomenon. The external phenomenon may be pressure and the signals may be useable to determine spatial dependencies of the pressure.

A MEMS device and a method of manufacturing the same are provided. A semiconductor device includes a substrate; and a membrane over the substrate and configured to generate charges in response to an acoustic wave, the membrane being in a polygonal shape including vertices. The membrane includes a via pattern having first lines that partition the membrane into slices and extend to the vertices of the membrane such that the slices are separated from each other near an anchored region of the membrane and connected to each other around a central region. The via pattern further includes second lines extending from the anchored region of the membrane toward the central region of the membrane. Each of the second lines includes a length less than a length of each of the first lines.

A MEMS device and a method of manufacturing the same are provided. A semiconductor device includes a substrate; and a membrane over the substrate and configured to generate charges in response to an acoustic wave, the membrane being in a polygonal shape including vertices. The membrane includes a via pattern having first lines that partition the membrane into slices and extend to the vertices of the membrane such that the slices are separated from each other near an anchored region of the membrane and connected to each other around a central region. The via pattern further includes second lines extending from the anchored region of the membrane toward the central region of the membrane. Each of the second lines includes a length less than a length of each of the first lines.

A robust MEMS transducer includes a kinetic energy diverter disposed within its frontside cavity. The kinetic energy diverter blunts or diverts kinetic energy in a mass of air moving through the frontside cavity, before that kinetic energy reaches a diaphragm of the MEMS transducer. The kinetic energy diverter renders the MEMS transducer more robust and resistant to damage from such a moving mass of air.

A micromechanical component having a substrate which includes a micro-electromechanical microphone structure, the micro-electromechanical microphone structure encompassing at least one piezoelectric layer and at least one polymer mass as at least part of a packaging of the substrate fitted with the micro-electromechanical microphone structure, which is in contact with at least a partial outer surface of the substrate fitted with the micro-electromechanical microphone structure. A method is also described for packaging a substrate having a micro-electromechanical microphone structure encompassing at least one piezoelectric layer by developing at least a portion of a packaging of the substrate fitted with the micro-electromechanical microphone structure from at least one polymer mass, and the at least one polymer mass being applied directly on at least a partial outer surface of the substrate fitted with the micro-electromechanical microphone structure.

A micromechanical component having a substrate which includes a micro-electromechanical microphone structure, the micro-electromechanical microphone structure encompassing at least one piezoelectric layer and at least one polymer mass as at least part of a packaging of the substrate fitted with the micro-electromechanical microphone structure, which is in contact with at least a partial outer surface of the substrate fitted with the micro-electromechanical microphone structure. A method is also described for packaging a substrate having a micro-electromechanical microphone structure encompassing at least one piezoelectric layer by developing at least a portion of a packaging of the substrate fitted with the micro-electromechanical microphone structure from at least one polymer mass, and the at least one polymer mass being applied directly on at least a partial outer surface of the substrate fitted with the micro-electromechanical microphone structure.

Aspects of transducers with feedback transduction are described. One aspect is a transducer system comprising an operational amplifier having an inverting input, a non-inverting input, and an output. The transducer system also includes a piezoelectric microelectromechanical system (MEMS) transducer having a first node and a second node, wherein the first node is coupled to the inverting input of the operational amplifier, and wherein the piezoelectric MEMS transducer is configured to generate an electrical signal across the first node and the second node in response to a signal incident upon the piezoelectric MEMS transducer. The transducer system also includes an attenuator having an input and an output, wherein the input of the attenuator is coupled to the output of the operational amplifier, and wherein the output of the attenuator is coupled to the second node of the piezoelectric MEMS transducer.

A bone conduction microphone includes a housing having an opening, a microphone pad, an element support member, a piezoelectric element, and a drive plate. The microphone pad is formed in a bottomed tubular shape having a bottom portion disposed outward and a tubular portion with an outer circumference fixed to an inner circumference of the opening. The element support member has an outer circumference fixed to an inner circumference of the tubular portion, and a support portion projecting toward the bottom portion. The piezoelectric element is in a plate shape with a peripheral edge of one surface fixed to the support portion and picks up vibration. The drive plate has a diaphragm part fixed to an inward surface of the bottom portion, and the diaphragm part is provided at a center with a protrusion fixed to an element central portion on another surface of the piezoelectric element.