A protective face mask implemented with a pocket located on a front surface of the mask A removable amplifier unit configured to be placed into the pocket, the removable amplifier unit comprising: a micro-processor configured to process voice data; a rechargeable battery coupled to the micro-processor; a Bluetooth device coupled to the micro-processor; a microphone coupled to the micro-processor and configured to provide the voice data to the micro-processor; and a speaker unit configured to output the voice data processed by the micro-processor.

A wearable element is disclosed. In an embodiment a wearable element includes at least one piezoelectric element configured to vibrate so that a haptic impression of an acoustic signal is generated, wherein the wearable element is wearable on a body.

The methods, systems and devices provided herein relate to sleep-aid. Some embodiments include a vibration source and/or a sound source. In some embodiments, the vibration source and/or sound source emit vibrations and/or sounds that stimulate a subject's vagus nerve, or another nerve, to induce sleep or relaxation in the subject.

A system for communicating pitch selections wirelessly from a wireless transmitter has a coded signal generator that generates coded signals in accordance with selected pitch types. A receiver decodes the received coded signals, selects an audio file based on the received coded signal and generates an audio signal announcing the selected pitch type based on the transmitted selected pitch type in accordance with the received coded signal. The audio signal is transduced by a bone conductor transducer so that the player can hear the announced selected pitch type through bone conduction.

[Problem] To provide a neck-worn device in which a battery or other electronic component is disposed at an appropriate location.

[Solution] This neck-worn device is to be worn at the neckline of a wearer, wherein a body part 30 comprises: a battery 90; a circuit board 85 on which is installed an electronic component that is driven by receiving power supplied from the battery 90; and a body part casing 32 in which the battery 90 and the circuit board 85 are stored. The circuit board 85 is disposed inside the body part casing 32 so as to be positioned in between the battery 90 and the neckline of the wearer while the device is being worn.

[Effect] Heat generated from the battery 90 is not readily transmitted to the wearer, thus improving the fit of the neck-worn device.

Ambient noise attenuating headphones are disclosed that may be used when a user is laying down on their side. The headphones include an ergonomic support structure, a noise attenuating structure housed within the ergonomic support structure having a circumferential end configured to surround an ear of the user, wherein the noise attenuating structure comprises a first and second elastic portion, and wherein the second elastic portion has the circumferential end having a material density less than the first elastic portion, and a speaker coupled to the noise attenuating structure.

A speaker unit that has a housing, a lower substrate that is fixed to the housing, a plurality of first ultrasonic vibrators that are arranged on the lower substrate, an upper substrate that is fixed to the housing and has a plurality of openings (OP) formed therein at locations that correspond to the first ultrasonic vibrators, and a plurality of second ultrasonic vibrators that are arranged on the upper substrate.

In general, the present embodiments relate to a method and apparatus for estimating spatial content of a soundfield at a desired location, including a location that has actual sound content obstructed or distorted. According to certain aspects, the present embodiments aim at presenting a more natural, spatially accurate sound, for example to a user at the desired location who is wearing a helmet, mimicking the sound a user would experience if they were not wearing any headgear. Modes for enhanced spatial hearing may be applied which would include situation-dependent processing for augmented hearing. According to other aspects, methods and apparatuses record or capture the sound experienced by a number of the participants and devices on and near the field of play, analyze the captured sound for its various components and their associated spatial content, and make those components available to participants and spectators.

An audio control system includes at least one microphone, at least one speaker, and one or more processors. The at least one microphone is at a first position adjacent to an ear of a user and configured to detect a sound field at the first position and output a sound signal indicative of the detected sound field. The at least one speaker is at a second position spaced from the first position and configured to output sound responsive to receiving an audio signal. The one or more processors are configured to generate the audio signal based on the sound signal and a target parameter of the sound field at (i) the first position and (ii) a third position spaced from the first position; and provide the audio signal to the at least one speaker to cause the at least one speaker to output the sound responsive to receiving the audio signal.

A speaker includes a housing having walls that define a cavity and a diaphragm covering the cavity and configured to vibrate under application of a magnetic field. The vibration produces sound waves. The walls are configured to deform under bending stress. The speaker is configured produce the sound waves both in an undeformed state and in a deformed state. Another speaker includes a flexible layer, a sensor configured to detect a curvature of the flexible layer, and a transducer disposed on and configured to vibrate the flexible layer. The vibrations of the flexible layer generate sound waves and output generated by the transducer is based on the curvature of the flexible layer.