A hearing protection device comprises a first earpiece comprising a first transducer for provision of a first ear canal input signal and a first receiver for provision of a first audio output signal based on a first ear canal output signal. The hearing protection device comprises a second earpiece comprising a second transducer for provision of a second ear canal input signal and a second receiver for provision of a second audio output signal based on a second ear canal output signal. The hearing protection device comprises a first mixer module, connected to the first earpiece and a controller module, for provision of a first output signal based on one or more first input signals. The hearing protection device comprises a second mixer module, connected to the second earpiece and the controller module, for provision of a second output signal based on one or more second input signals.

An acoustic device that includes a housing, a nozzle portion, a speaker hole, a first microphone hole, a speaker, a first microphone, and a processor configured to output a first signal through the speaker, receive a second signal corresponding to the first signal through the first microphone, output a third signal through the speaker when a magnitude of a first frequency band component of the second signal is greater than a first value, receive a fourth signal corresponding to the third signal through the first microphone, and determine that the protruding end surface of the nozzle portion is blocked and the acoustic device is not worn in a user's ear when a magnitude of a second frequency band component of the fourth signal is greater than a second value.

A device or a method using the device includes a balloon configured to seal a user's orifice, where the balloon is configured to produce an acoustic seal between a first side and a second side of the balloon in an ear canal. At least a second side of the balloon is fitted into the ear canal. Audio processing circuitry produces an audio signal for driving a speaker in the device and to measure sound level using output from the microphone in the device while the speaker is being driven by the audio signal. The device or method further includes control circuitry to evaluate a seal quality of the device. Other embodiments are disclosed.

This application relates to earbuds configured with one or more biometric sensors. At least one of the biometric sensors is configured to be pressed up against a portion of the tragus for making biometric measurements. In some embodiments, the housing of the earbud can be symmetric so that the earbud can be worn interchangeably in either a left or a right ear of a user. In such an embodiment, the earbud can include a sensor and circuitry configured to determine and alter operation of the earbud in accordance to which ear the earbud is determined to be sitting in.

At least one exemplary embodiment is directed to a method of generating preferred dynamic range function to process audio reproduced by an earphone device. The function includes processing the audio to improve speech intelligibility. The function is acquired with a self-administered hearing test.

The technology described in this document can be embodied in a method that includes receiving one or more electronic files comprising information on structural features of a portion of an ear of a user, generating an electronic representation of the eartip or a cast based on a portion of the information on the structural features of the portion of the ear, and producing the eartip based on the electronic representation. The eartip includes an outlet, and a sealing structure disposed around an exterior of the outlet, wherein a first end of the sealing structure is attached to the outlet, and a second, opposite end of the sealing structure is physically separated from the exterior of the outlet. Generating the electronic representation includes configuring one or more structural parameters of the outlet or the sealing structure in accordance with the structural features of the portion of the ear.

An ultrasonic proximity sensor can determine one or more characteristics of a local environment. For example, the sensor can emit an ultrasonic signal into a local environment and can receive an ultrasonic signal from the local environment. From a measure of correlation between the emitted and the received signals, the sensor can classify the local environment. By way of example, such a sensor can assess whether an in-ear earphone is positioned in a user's ear. A media device in communication with the sensor can transmit an audio signal to the earphone for audio playback responsive to a determination by the sensor that the earphone is in the user's ear and can redirect the audio signal to another playback device responsive to a determination by the sensor that the earphone is not in the user's ear. Related and other aspects also are described.

A headphone device having an earcup that is configured to form a portion of an acoustic assembly of a headphone device. The earcup includes a seamless three-dimensional cover. The cover is formed from a continuous fabric of interlocking yarn. The cover can include portions having different performance characteristics, such as acoustic properties and/or comfort properties, that can be provided using different knit patterns and/or different fabric materials.

A head-worn audio system includes a support frame, a first contact element configured to contact a first portion of a head of a user, a first actuator coupled to the support frame and configured to move the first contact element, a first sensor configured to generate a first sensor signal indicating a first state of the first contact element and a second sensor signal indicating a second state of the first contact element, and a processor. The processor is communicatively coupled to the first actuator and the first sensor and is configured to cause the first actuator to move the first contact element from a first position that corresponds to the first state to a second position that corresponds to the second state, wherein, in the second state, the first contact element is in contact with the head of the user.

An earphone can employ a dynamic tip to seal the ear canal of a user. At least one audio transducing driver may be positioned within a housing that is attached to a dynamic tip. The tip can have a first chamber separated from a second chamber by a constriction ring with sealing material occupying portions of the first chamber and the second chamber.