An earpiece includes an earbud that supports at least one electrode, and an ear tip that includes a hydrogel. The ear tip is configured to be coupled to the earbud such that the hydrogel overlies the at least one electrode and such that the hydrogel is disposed between the at least one electrode and the user's skin when the earpiece is worn.

An in-ear optical sensor device sits deep within the ear canal of a subject such that is in the cartilaginous region and/or the bony region of the ear canal where effects from temporomandibular joint activity or other movement, and external light, are limited. The device has a lateral housing and a medial articulating head joined at an articulation joint so that the medial articulating head may be angled relative to the lateral housing to help the device fit within tortuous ear canals. The device also includes a seal configured to conform to the shape of the ear canal to physically support the device to further limit movement and block environmental light. An audio receiver is also included in the device.

A personal audio device (e.g., headphones, earphones) can have an earpiece (e.g., an ear cup or earbud) with a removable cushioning member (e.g., headphone cushions or ear tips for earbuds). The cushioning member can include an identification tag that encodes identification data for the cushioning member. When the cushioning member is attached to the earpiece, the identification tag is brought into proximity with a tag sensor in the earpiece and the earpiece can read the identification tag to determine identification data for the cushioning member. The identification data can be used to modify a behavior of the earpiece and/or of a host device communicably coupled to the earpiece.

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 system comprising an earpiece, the earpiece having a first end facing a tympanic membrane, and a second end facing toward a surrounding of a user when the earpiece is worn by the user, includes: a vent channel coupled to a first vent opening at the first end, and to a second vent opening at the second end, wherein the vent channel comprises a vent port; a closing element comprising a first magnetic member, the closing element configured to cause the vent port to be open, and to cause the vent port to be closed; an inductive member comprising a conductive material, the inductive member configured for inductive coupling with a second magnetic member, wherein the second magnetic member is configured for displacing the closing element by magnetic interaction with the first magnetic member; and a processor configured to obtain an electrical measurement value of the second magnetic member.

A sound-attenuating assembly may have a headpiece and two covered dampening assembly that may be detachably attached to the locations of the headpiece that oppose a wearer's ear; the dampening assembly may have a padded member that may be in contact with a dividing member that may be in a contact with a compressible member which may be disposed within a concave member; the dampening assembly may be disposed within a cover such a fastener of the cover detachably attaches to a fastener of the headpiece.

While a first wearable audio output component of a wearable audio output device is in a first position relative to a first ear of a user and a second wearable audio output component of the wearable audio output device is in the first position relative to a second ear, a computer system operates the wearable audio output device in a first mode. While doing so, the computer system detects a change in position of the first component from the first position to a second position; and, in response, while the second component is maintained in the first position, the computer system transitions the wearable audio output device from the first mode to a different, second mode that is a pass-through mode in which audio outputs provided via the wearable audio output device include pass-through audio components that include at least a portion of ambient sound from the physical environment.

A wearable audio output device in a physical environment includes an input device and one or more microphones. While ambient sound from the physical environment is being detected by the microphone(s), the wearable audio output device: while in a first mode, provides a first audio output including one or more pass-through audio components selected so as to increase audio pass-through of the ambient sound; detects an input via the input device; in response to detecting the input, and in accordance with a determination that the input is a first type of gesture, transitions from the first mode to a second mode; and, while in the second mode, provides a second audio output including one or more cancellation audio components selected so as to increase audio cancellation of the ambient sound.

While operating a wearable audio output device in a first mode, a computer system receives an input corresponding to a request to transition the wearable audio output device from the first mode to a noise-cancellation mode in which audio outputs that are provided via the wearable audio output device include cancellation audio components selected so as to at least partially cancel ambient sound from the physical environment. In response, if a first and second wearable audio output components of the wearable audio output device are both in-ear, the computer system transitions the wearable audio output device from the first mode to the noise-cancellation mode; and if either or both of the first and second wearable audio output components is not in-ear, the computer system forgoes transitioning the wearable audio output device from the first mode to the noise-cancellation mode.

A computer system detects an occurrence of a respective event. In response, and in accordance with a determination that a first wearable audio output component of a wearable audio output device is at least partially in a first ear of the user and that a second wearable audio output component of the wearable audio output device is at least partially in a second ear of the user, the computer system displays acoustic seal information for the wearable audio output device, including concurrently displaying, via the display device: a first indication of a quality of a first acoustic seal between the first wearable audio output component and the first ear of the user; and a second indication, distinct from the first indication, of a quality of a second acoustic seal between the second wearable audio output component and the second ear of the user.