Voice communication in hostile noisy environment is described. An example apparatus is integral with or attachable to a headgear including a multi-sensor array having a bone conduction microphone, an air conduction microphone, signal processor, a cushioned bendable material and audio output devices, such as speakers or headphones. A signal processor can be included that processes vibration signal data and tonal signal data to produce combined data representative of the vocal communication to substantially reduce or eliminate noise. A signals optimized combination process can be used to optimize the output by intelligently combining the outputs from the two different types of sensors for both to cooperate in a hostile noise environment to suppress or eliminate such noise.

A noise-reduction microphone, a noise-reduction safe earphone and a noise-reduction safe Bluetooth headset, comprising an acoustic wave concentrator which has a sound signal capturing unit at its big end used to capture sound wave signal and amplify the external sound wave signal, and then transmitted to the small end of the acoustic wave concentrator connected to the air tube, and the air tube is connected to the receiver device which receives the acoustic signal from the air tube and converts it into electrical sound signals transmitted to a voice terminal from the receiver device by a connector. The sound information is transmitted by the air tube, so the length of the air to be could be setted pretty long so that people can keep at a distance from electrical equipments with radiation, the remote air tube microphone can be separately used as microphone or mike.

The present invention discloses an advance attachment for noise abatement microphone. The assembly proposes a square shaped cavity to receive the microphone assembly where the outer shape is curved. The novel feature of assembly lies in its ease of use, portability and is universal in nature.

A microphone assembly includes a shaft element that is configured to be received in an opening defined by a base substrate layer of a headliner. The shaft element defines an air path. The microphone assembly includes a microphone element mounted on a circuit board within a housing. The microphone element is aligned with the air path such that the air path directs sound from the cabin to the microphone element. A vehicle cabin side of the headliner is covered by an acoustically transparent layer such that the microphone assembly is not visible within the vehicle cabin.

The present disclosure relates generally to providing a flexible patch and system for communicating through hard plastic masks such as CPAP/BiPAP® masks. Using electronic circuitry and novel designs, the present systems and methods can detect speech vibrations and output audible speech from hard plastic mask wearers. For example, in certain embodiments, the present systems and methods can recognize speech through a CPAP/BiPAP® mask, filter out non-human voice related noise, and output the resulting speech of the mask wearer.

A voice conversation apparatus includes a microphone configured to convert a voice of the one speaking person into a voice signal, modulation means configured to modulate the voice signal into a signal using ultrasound as a carrier wave, sound wave emission means configured to emit the signal modulated by the modulation means as a sound wave using ultrasound as a carrier wave, alignment means used by the one speaking person to make alignment so that the sound wave emission means is oriented to another voice conversation apparatus, pairing means configured to perform a pairing process of connecting the voice conversation apparatus to the other voice conversation apparatus by near-field communication, and control means configured to receive an instruction to start a conversation from the one speaking person and to, when the pairing process is successful, cause the sound wave emission means to emit the sound wave.

A MEMS device is provided that includes a piezoelectric film, a first electrode and a second electrode sandwiching the piezoelectric film, a protective film that covers at least part of the second electrode and having a cavity that opens part of the second electrode, a third electrode that contacts the second electrode at least in the cavity and is provided so as to cover at least part of the protective film, and a first wiring layer having a first contact portion in contact with the third electrode.

An electrical current generating device having a sound wave force magnifying structure in the form of a force transmission pin which is longitudinally slidable within a body bore and having a proximal end of a large area for receiving sound wave forces, and having a greatly reduced area distal end which bears on a piezoelectric element.

The present disclosure relates to electronic components and glasses comprising an electronic component. The electronic component may include a component body, a first circuit board, a second circuit board, a first microphone element, and a second microphone element. The component body may include a cavity. The first circuit board and the second circuit board may be inclined to each arranged in the cavity. The first microphone element may be arranged on a sidewall, facing the component body, of the first circuit board. The second microphone element may be arranged on a sidewall, facing the component body, of the second circuit board. A first sound conducting hole may be arranged on a sidewall, opposite to the first microphone element, of the component body. The first sound conducting hole may be configured to conduct a sound to the first microphone element. A second sound conducting hole may be arranged on the sidewall, opposite to the first microphone element, of the component body. The second sound conducting hole may be configured to conduct a sound to the second microphone element. The present disclosure may make full use of a space of the electronic component. When the electronic component is applied to an electronic device, it is beneficial to the thinness and lightness of the electronic device.

The present disclosure relates generally to providing a flexible patch and system for communicating through hard plastic masks such as CPAP/BiPAP® masks. Using electronic circuitry and novel designs, the present systems and methods can detect speech vibrations and output audible speech from hard plastic mask wearers. For example, in certain embodiments, the present systems and methods can recognize speech through a CPAP/BiPAP® mask, filter out non-human voice related noise, and output the resulting speech of the mask wearer.