Abstract: An electronic device package comprises a primary microphone having a frequency response having a first resonance frequency, and a reference microphone having a frequency response including a second resonance frequency, the primary microphone and the reference microphone configured to substantially simultaneously receive a same acoustic signal to produce a transduced signal of the primary microphone and a transduced signal of the reference microphone, the second resonance frequency of the reference microphone being different than the first resonance frequency of the primary microphone, the package having dimensions that cause the primary microphone and reference microphone to be acoustically isolated from one another at the resonance frequency of the primary microphone, there being less than 3 dB of acoustic coupling between the primary microphone and reference microphone at the first resonance frequency.

Abstract: The present application discloses a bulk acoustic wave resonance assembly and a method for manufacturing the same. The bulk acoustic wave resonance assembly of the present application includes a substrate, a first resonance assembly and a second resonance assembly which are arranged on the substrate; an interconnection region is formed between the first resonance assembly and the second resonance assembly; the first resonance assembly includes a first bottom electrode, a first piezoelectric layer, and a first top electrode which are arranged on the substrate in sequence; the second resonance assembly includes a second bottom electrode, a second piezoelectric layer, and a second top electrode which are arranged on the substrate in sequence; the first bottom electrode and the second top electrode are connected to each other in the interconnection region; and the second bottom electrode and the first top electrode are connected to each other in the interconnection region.

Abstract: A method of making an acoustic sensor (e.g., a piezoelectric sensor for a piezoelectric microelectromechanical systems microphone) includes forming or depositing one or more piezoelectric layers to define a beam extending between a proximal portion and a distal tip (e.g., unsupported free end), the beam having a width in plan view that is greater at a location distal of the proximal portion than at the proximal portion. The method also comprises attaching the beam to a substrate in cantilever form so that the proximal portion of the beam is anchored to the substrate and the distal tip is a free unsupported end of the beam. One or more electrodes are disposed on or in the proximal portion of the beam.

Abstract: An electronic device package comprises an electronic acoustic device including a primary microphone having a frequency response having a resonance frequency, and a reference microphone having a frequency response including a resonance frequency. The primary microphone and the reference microphone are configured to substantially simultaneously receive a common acoustic signal to produce a transduced signal of the primary microphone and a transduced signal of the reference microphone, the resonance frequency of the reference microphone being different than the resonance frequency of the primary microphone. An equalization module is configured to equalize the frequency response of the microphone based on the transduced signal of the microphone and the transduced signal of the reference microphone. The package defines a first back cavity of the primary microphone and a second back cavity of the reference microphone, the second back cavity being acoustically isolated from the first back cavity.

Abstract: A bulk acoustic wave device that is configured to excite an overtone mode as a main mode is disclosed. The bulk acoustic wave device can include a first electrode, a piezoelectric layer, a second electrode, and at least one temperature compensation layer. The piezoelectric layer is positioned over the first electrode. The second electrode is positioned such that the piezoelectric layer is located between the first and second electrodes. The at least one temperature compensation layer is configured to provide temperature compensation for the bulk acoustic wave device. The at least one temperature compensation layer has a thickness that is a multiple of one thirty-second of a wavelength of an acoustic wave propagating through the at least one temperature compensation layer. The bulk acoustic wave device is configured to excite the overtone mode as the main mode.

Abstract: A bulk acoustic wave device that is configured to excite an overtone mode as a main mode is disclosed. The bulk acoustic wave device can include a first electrode, a second electrode, a piezoelectric layer disposed between the first and second electrodes, and a temperature compensation layer between the first and second electrodes. A total thickness of the piezoelectric layer and the temperature compensation layer is sufficiently thick to excite the overtone mode as the main mode. Related filters, multiplexers, radio frequency modules, wireless communications devices, and methods are also disclosed.

Abstract: A microelectromechanical system microphone includes a piezoelectric diaphragm, upper inner electrodes and upper outer electrodes disposed on an upper surface of the diaphragm, and lower inner electrodes and lower outer electrodes disposed on a lower surface of the diaphragm. The diaphragm is divided into a plurality of sectors, a first of the sectors including an inner and an outer upper electrode physically disconnected from an inner and an outer upper electrode on a second sector adjacent to the first sector, and an inner and an outer lower electrode physically disconnected from an inner and an outer lower electrode on the second sector. A first via extends between and electrically couples the upper and lower inner electrodes of the first sector and a first bond pad. A second via extends between and electrically couples the upper and lower outer electrodes of the second sector and a second bond pad.

Abstract: A method of forming a monolithic integrated PMUT and CMOS with a coplanar elastic, sealing, and passivation layer in a single step without bonding and the resulting device are provided. Embodiments include providing a CMOS wafer with a metal layer; forming a dielectric over the CMOS; forming a sacrificial structure in a portion of the dielectric; forming a bottom electrode; forming a piezoelectric layer over the CMOS; forming a top electrode over portions of the bottom electrode and piezoelectric layer; forming a via through the top electrode down to the bottom electrode and a second via down to the metal layer through the top electrode; forming a second metal layer over and along sidewalls of the first and second via; removing the sacrificial structure, an open cavity formed; and forming a dielectric layer over a portion of the CMOS, the open cavity sealed and an elastic layer and passivation formed.

Abstract: According to various embodiments, there is provided a resonator device that includes a first interdigital transducer and a second interdigital transducer that is electrically connected to the first interdigital transducer. Both the first interdigital transducer and the second interdigital transducer are configured to resonate at a common frequency. At least one of an electrode width and an electrode pitch of the first interdigital transducer is different from the respective electrode width and/or electrode pitch of the second interdigital transducer such that spurious peaks of the resonator device are lower in amplitude as compared to spurious peaks of each of the first interdigital transducer and the second interdigital transducer.

Abstract: An electronic device package comprises a primary microphone having a frequency response having a first resonance frequency, and a reference microphone having a frequency response including a second resonance frequency, the primary microphone and the reference microphone configured to substantially simultaneously receive a same acoustic signal to produce a transduced signal of the primary microphone and a transduced signal of the reference microphone, the second resonance frequency of the reference microphone being different than the first resonance frequency of the primary microphone, the package having dimensions that cause the primary microphone and reference microphone to be acoustically isolated from one another at the resonance frequency of the primary microphone, there being less than 3 dB of acoustic coupling between the primary microphone and reference microphone at the first resonance frequency.

Abstract: In some embodiments, a microphone can include a piezoelectric sensor configured to provide a response to acoustic energy in a frequency band, with the response including an in-band resonance having a peak frequency within the frequency band. The microphone can further include an equalizer coupled to the piezoelectric sensor and configured to provide equalization of the response of the piezoelectric sensor, such that the equalizer removes or adjusts the in-band resonance from the response of the piezoelectric sensor.

Abstract: In some embodiments, an analog-to-digital converter (ADC) architecture can be implemented to process a signal from a charge output sensor. The ADC architecture can include a summing node for receiving a sensor signal from the charge output sensor, and an output node implemented to provide a digital signal representative of the sensor signal. The ADC architecture can further include a charge amplifier implemented to receive an analog signal from the summing node as an input analog signal and generate an output analog signal with a gain, and an ADC circuit implemented to generate the digital signal based on the output analog signal from the charge amplifier. The ADC architecture can further include a feedback circuit implemented between the output node and the summing node.

Abstract: A piezoelectric microelectromechanical system microphone assembly comprises a carrier substrate including one of a through-hole or a recess, and a package including a microelectromechanical system die having a piezoelectric microelectromechanical system microphone mounted on a microphone substrate and a lid, at least a portion of the package disposed within the one of the through-hole or recess.

Abstract: An electronic device package comprises an electronic acoustic device including a primary microphone having a frequency response having a resonance frequency, and a reference microphone having a frequency response including a resonance frequency. The primary microphone and the reference microphone are configured to substantially simultaneously receive a common acoustic signal to produce a transduced signal of the primary microphone and a transduced signal of the reference microphone, the resonance frequency of the reference microphone being different than the resonance frequency of the primary microphone. An equalization module is configured to equalize the frequency response of the microphone based on the transduced signal of the microphone and the transduced signal of the reference microphone. The package defines a first back cavity of the primary microphone and a second back cavity of the reference microphone, the second back cavity being acoustically isolated from the first back cavity.

Abstract: A side-port piezoelectric microelectromechanical system microphone package includes a microelectromechanical system die disposed on the microphone substrate and including a microphone membrane and a membrane support substrate, the microphone membrane being disposed on a wall of a membrane support substrate, and an acoustic port defined by an aperture passing through a portion of the wall of the membrane support substrate.

Abstract: A piezoelectric microelectromechanical system microphone comprises a piezoelectric element configured to deform and generate an electrical potential responsive to impingement of sound waves on the piezoelectric element, a sensing electrode disposed on the piezoelectric element and configured to sense the electrical potential, and a dummy electrode electrically unconnected to the sensing electrode and disposed on a portion of the piezoelectric element that is free of the sensing electrode, the dummy electrode configured to reduce static deformation of the piezoelectric element caused by residual stresses in the piezoelectric element.

Abstract: A piezoelectric sensor (e.g., for use in a piezoelectric MEMS microphone) includes a substrate and a cantilever beam attached to the substrate. The cantilever beam has a proximal portion attached to the substrate and extending to an unsupported distal end. An electrode is disposed on or in the proximal portion of the beam and has an outer boundary with a shape substantially corresponding to a contour line of a strain distribution plot for the cantilever beam resulting from a force applied to the cantilever beam.

Abstract: A method of making a piezoelectric sensor includes forming piezoelectric layer(s) to define a beam extending between a proximal portion and a distal end. The method also includes modeling a strain distribution on the beam based on a force applied to the beam, and defining an outer boundary with a shape substantially corresponding to a contour line of the strain distribution on the beam. The method also includes forming an electrode having said outer boundary shape, and attaching the electrode to the beam. The method also includes attaching the beam to a substrate in cantilever form so that the proximal portion of the beam is anchored to the substrate and the distal end of the beam is unsupported.

Abstract: Electronic acoustic devices and methods of operating the same include a microphone having a frequency response including a resonance frequency, a reference microphone having a frequency response including a resonance frequency, the microphone and the reference microphone configured to substantially simultaneously receive a common acoustic signal to produce a transduced signal of the microphone and a transduced signal of the reference microphone, the resonance frequency of the reference microphone being different than the resonance frequency of the microphone, and an equalization module configured to equalize the frequency response of the microphone based on the transduced signal of the microphone and the transduced signal of the reference microphone.

Abstract: A piezoelectric microelectromechanical systems microphone is provided comprising a substrate including at least one wall defining a cavity, the at least one wall defining an anchor region around a perimeter, a piezoelectric film layer forming a membrane, the piezoelectric film layer being supported at the anchor region by a spring region, and an electrode disposed over the piezoelectric film layer. A method of manufacturing such a MEMS microphone is also provided.