A video audio recording system includes a video acquisition unit, an audio acquisition unit, a video recording parameter acquisition unit, and an audio emphasis unit. The video acquisition unit acquires a video signal by recording video of a subject. The audio acquisition unit acquires an audio signal by recording a sound. The video recording parameter acquisition unit acquires first information representing a video recording direction of the video acquisition unit and second information representing a positional relationship between the video acquisition unit and the audio acquisition unit. The audio emphasis unit emphasizes, based on the acquired first and second information, the acquired audio signal of the sound arriving in a predetermined direction.

A small-sized onboard device that includes a speaker and a microphone and is configured to reduce noise caused by an echo is provided. The speaker is provided inside a housing that forms a cavity inside so that a sound emission surface of the speaker faces a direction substantially orthogonal to a front surface, and a first opening is formed in a front surface of the housing. A microphone case and a sound guide member are juxtaposed on the front surface of the housing. A microphone is housed inside the microphone case. The microphone case has a sound pickup hole in a front surface of the microphone case. The sound guide member has a sound guide hole that passes through the sound guide member. The first opening is provided in a vicinity of a top surface or a bottom surface of the housing.

A sound enhancing device for improving voice reception of a smartphone microphone is attachable to the rear surface of a smartphone opposite the surface of the smartphone having a display. The device has a deflector in a sliding engagement within a cavity of a housing moveable between a stowed position and a deployed position. A reflective curved area positioned on a first surface of the deflector captures and reflects sound waves from the voice of a user toward a microphone of the smartphone.

A microphone can include an adapter housing. The adapter housing can include an opening and an outer acoustic port. The microphone can include an internal microphone assembly disposed at least partially within the adapter housing. The internal microphone assembly can include an internal housing having an internal acoustic port. The internal microphone assembly can include a plurality of contacts disposed on the internal housing. The contacts can be accessible through the opening of the adapter housing. An interior of the internal housing can be acoustically coupled to the outer acoustic port via the internal acoustic port.

A power stethoscope with integrated speaker includes a compact main body that houses a microphone, a speaker and a sound funnel. The sound funnel has a cap along the bottom end that permits the passage of sound waves for capture by the microphone. A control unit having a processor, a memory and a digital filter is communicatively linked to the microphone and speaker. The memory can record the microphone output, and a communication can transmit the same to an external device.

A microphone includes: a first substrate having one or more first penetration holes; a vibrating membrane disposed on the first substrate and covering the first penetration holes; a fixed membrane disposed at a predetermined distance over the vibration membrane and having a plurality of air intake holes; and a phase delay unit bonded by a bonding pad on the fixed membrane, having a plurality of second penetration holes connected to the one or more first penetration holes, and having a phase delay material in the second penetration holes. A method of manufacturing a microphone including a phase delay unit is also disclosed.

In at least one embodiment, a system for monitoring movement of a wireless microphone that transmits an audio signal on a stage is provided. The system includes a plurality of antennas for being positioned on stage and each being positioned on a different zone of the stage and each being configured to wirelessly receive an audio signal from a wireless microphone. The system further includes a controller that is operably coupled to each antenna. The controller is configured to determine the signal strength for the audio signal received at each antenna at least two or more times and to determine a signal strength trend for each antenna in response to determining the signal strength for the audio signal at each antenna at least two or more times.

A microphone includes a microphone unit that converts a sound into an electrical signal. A tubular housing houses the microphone unit and includes a rear opening portion in a side surface. A step portion surrounds the rear opening portion in an inner surface of the housing. A plate-like shielding member is attached to the step portion from an inner surface side of the housing, and a circuit board housed in the housing in contact with the shielding member includes a ground pattern its side surface and in a contact position between the circuit board and the shielding member.

Disclosed are a method of manufacturing a microphone, a microphone, and a control method thereof. The method includes forming a sound sensing module on a main substrate including a first sound aperture such that the sound sensing module is connected to the first sound aperture. The method further include forming a cover for receiving the sound sensing module formed therein with a second sound aperture corresponding to the first sound aperture on the main substrate. The method also includes forming a sound delay filter at a receiving space of the cover to be connected to the second sound aperture. The method also includes forming a semiconductor chip electrically connected to the sound sensing module at the receiving space, to selectively operate the sound delay filter according to a signal output from the sound sensing module.

An integrated circuit includes a processor that upsamples a vibration signal. The processor determines a correlation value. The correlation value may be based on a microphone signal, the upsampled vibration signal, or both. The processor determines filter coefficients. The filter coefficients may be determined based on the correlation value being above a threshold. The filter coefficient may be based on the upsampled vibration signal. The processor filters the vibration signal based on the filter coefficients to remove a noise portion and obtain a processed microphone signal. The processor outputs the processed microphone signal.