One or more microphones and a controller are used to detected, transmit, and store toilet noise data. One or more speakers are used to provide user feedback based on the detected toilet noise data. Speakers, microphones, and circuitry may be located within a toilet seat of a toilet. A user device or remote device may be connected to the toilet noise detection toilet apparatus for data recording, collection, and health trend reporting.

A processor-based method of reducing loudspeaker-induced harmonic distortion in sound generated by a loudspeaker responsive to a first audio signal, the method including: attenuating a first band in the first audio signal by an attenuation gain, the first band including a fundamental frequency, wherein the attenuating dynamically adjusts the attenuation gain in accordance with, at least, a ratio between: i) an energy of the first band in the first audio signal; and ii) an energy of a second band in the first audio signal, the second band including one or more frequencies that is an integer multiple of the fundamental frequency.

An ultrasonic sensor includes: a substrate in which an opening is formed; a vibration film that is provided on the substrate so as to close the opening; a plurality of vibration elements that are disposed at positions where the vibration film and the opening overlap each other in a plan view along a thickness direction of the vibration film; a sealing plate that is disposed so as to face the vibration film, supports the vibration film, and has a surface facing the vibration film as a flat surface; and a suppressing portion that is provided between the adjacent vibration elements in the plan view, is bonded to both the vibration film and the sealing plate, and is formed of a resin material for suppressing transmission of vibration of the vibration film.

A host device may include an imaging unit configured to capture an image of a guest device, and a communication unit configured to communicate with the guest device. The host device may include circuitry configured to identify, in the image of the guest device, identification information corresponding to the guest device, the identification information being displayed on a screen included on the guest device. The circuitry may calculate, based on the identification of the identification information in the image, an arrangement position of the guest device. The circuitry may assign, based on the calculated arrangement position, assigned data to the guest device. The circuitry may transmit one or more of the calculated arrangement position and information associated with the assigned data to the guest device.

Certain embodiments herein relate to a heart-shaped locket with audio device that comprises a front member that is connected to a rear member via a hinge. The front member may comprise a cavity configured to hold contents, where an interior side of the front member is a transparent cover that extends over the cavity to keep the contents within the cavity and allow a user to view the content in the cavity when the heart-shaped locket is in the open position. An interior side of the rear member may comprise a surface that may display an engraved message. An audio device may be disposed within the rear member that comprises an output device and a user control, where the user control activates the audio device to output a message via the output device, and where the user control may be disposed on an exterior side of the rear member.

Voice-controlled devices that include one or more speakers for outputting audio. In some instances, the device includes at least one speaker within a cylindrical housing, with the speaker aimed or pointed away from a microphone coupled to the housing. For instance, if the microphone resides at or near the top of the cylindrical housing, then the speaker may point downwards along the longitudinal axis of the housing and away from the microphone. By pointing the speaker away from the microphone, the microphone will receive less sound from the speaker than if the speaker were pointed toward the microphone). Because the voice-controlled device may perform speech recognition on audio signals generated by the microphone, less sound from the speaker represented in the audio signal may result in more accurate speech recognition, and/or a lesser need to perform acoustic echo cancelation (AEC) on the generated audio signals.

An ultrasonic device includes a substrate, a transmitter disposed over the substrate, the transmitter including an ultrasonic transmitting transducer configured to generate ultrasonic signals, and a receiver disposed over the substrate, the receiver including an ultrasonic receiving transducer configured to sense ultrasonic signals. The ultrasonic device further includes a first horn-shaped acoustic channel, wherein a material of at least one portion of the first horn-shaped acoustic channel is the same as a material of at least one portion of the transmitter or the receiver.

A transducer includes a piezoelectric element that includes a piezoelectric membrane which is interposed between a pair of electrodes, a membrane body that includes a vibration membrane displaceable in a membrane thickness direction, the piezoelectric element being laminated on the vibration membrane, a package that includes an internal space which houses the piezoelectric element and the membrane body, and an abutment pad that is disposed in the internal space and limits displacement of the vibration membrane by abutting the piezoelectric element or the vibration membrane when the vibration membrane is displaced in the membrane thickness direction.

A piezoelectric microelectromechanical systems (MEMS) transducer that can operate as a microphone (e.g., contact microphone) or a speaker is presented herein. The piezoelectric MEMS transducer includes a substrate, a proof mass and folded displacement sensing structures. Each folded displacement sensing structure comprises a continuous beam, a first piezoelectric stress sensor coupled to a first portion of the continuous beam, and a second piezoelectric stress sensor coupled to a second portion of the continuous beam. The first portion of the continuous beam is coupled to a respective portion of the proof mass, and the second portion of the continuous beam is coupled to a respective portion of the substrate. The first and second portions of the continuous beam come together at an acute angle. The first and second piezoelectric stress sensors output stress information responsive to a stress induced in the continuous beam by displacement of the proof mass.

An audio/video recording and communication device configured as a doorbell has a housing with a support structure and a removable faceplate. A flexible translucent membrane of the faceplate supports a button aligned with a mechanical switch when the removable faceplate is attached to the housing such that a plurality of light emitting elements are positioned around the mechanical switch transmit light through the translucent membrane. A removable battery casing is configured to hold at least one battery and has a release button physically coupling with a detent of the support structure to retain the removable battery casing within the support structure. The removable battery casing may be removed from the device for recharging without removing the device from a surface on which it is mounted.