Abstract: An electronic device having a microphone behind a water resistant, air-impermeable membrane is disclosed. Embodiments include a trapped volume of air between the membrane and the microphone. A barometric equalization element may define an acoustic leak path, e.g., a tortuous leak path, between the trapped volume of air and an encased space within a casing of the electronic device. Other embodiments are also described and claimed.

Abstract: A mesh network of printed circuit boards (PCBs) including a first PCB coupled to a second rigid PCB by way of an interlocking connection is provided. The interlocking connection has a degree of freedom that allows the first and second PCBs to form a twist angle between each other; the interlocking connector configured to provide electrical coupling between active components disposed in each of the first and second PCBs. A method of forming a substrate fabric including a mesh network as above is also provided. Further provided is a method of activating the mesh network of printed circuit boards as above.

Abstract: An array of electrical components may be mounted in openings in an electronic device housing. Gaskets may be used to seal the electrical components to a housing wall. The housing wall may be planar or may have a cylindrical shape or other curved shape. A support structure such as a hollow tube may be mounted within the interior of a cavity region defined by the housing wall. The electrical components may be radially deployed into the openings. Mating ramped structures may be translated with respect to each other to push elongated strips of components outward or each electrical component may be pushed outward using a threaded nut that engages threads on the electrical component.

Abstract: An array of electrical components may be mounted in openings in an electronic device housing. Gaskets may be used to seal the electrical components to a housing wall. The housing wall may be planar or may have a cylindrical shape or other curved shape. The electrical components may be mounted to the housing wall using screws and nuts. Each nut may have a central member with opposing stops at the ends of the central member. An opening in each central member may receive a screw to allow the nut to rotate between an installation position and a locked position. The openings in the housing wall may have scalloped extensions that allow the nuts to clear the housing wall while the components are being inserted into the housing. Following installation, the nuts may be rotated into the locked positions.

Abstract: Headphone eartips with internal support components and methods for making the same are provided. Different support components may provide specific amounts and types of additional rigidity at specific portions of an exterior surface of an outer eartip body that may be expected to interface with specific portions of an ear canal geometry when an eartip subassembly is positioned within the ear canal, such that the eartip subassembly may conform to the various shapes of the ear canal while maintaining an acoustic seal.

Abstract: An electronic device having an interior volume, the electronic device including a sealing mechanism to prevent ingress of water into the interior cavity. The sealing mechanism having a channel having a first opening at an external environment and a second opening that leads to the interior volume, a membrane that covers the second opening, the membrane being air permeable and water resistant such that the membrane allows air to pass and prevents passage of water up to an upper pressure threshold, a stopper mechanism, and a diaphragm comprising a surface arranged to receive an external water pressure and that is air and water impermeable, the diaphragm being coupled to the stopper mechanism that deflects in response to the water pressure such that the diaphragm actuates the stopper mechanism and seals off the channel from at the first opening preventing water pressure at the membrane from exceeding the upper pressure threshold.

Abstract: An electronic device is disclosed. The electronic device may include a sealing element between a protective cover and a housing of the electronic device. The sealing element may provide a seal between the protective cover and the enclosure, as well as monitor or detect a force to the protective cover. Also, one or more support members may surround the sealing element to provide protection against a material (such as liquid) entering an opening between the protective cover and the enclosure. Alternatively, or in combination, the sealing element may include several openings, each of which may include a restraining element to limit movement of the sealing element. Also, a blocking element may be placed at or near an edge of the enclosure to provide additional reinforcement if the sealing element is laterally displaced. The blocking element may include an operational component of the electronic device, such as an antenna.

Abstract: An electronic device may have a rigid support structure to which electrical components are mounted. The rigid support structure may be an electronic device housing structure such as a housing wall having openings that receive the electrical components. The electrical components may have electrical component connectors. A printed circuit board may be used to convey signals for the electrical components. Connectors may be mounted to the printed circuit board. Lateral shift accommodation structures may be formed between the electrical component connectors and the electrical components or in the vicinity of the connectors on the printed circuit to allow the connectors on the printed circuit to mate with the electrical component connectors of the rigidly mounted electrical components.

Abstract: An audio system that adjusts one or more beam patterns emitted by one or more loudspeaker arrays based on the preferences of users/listeners is described. The audio system includes an audio receiver that contains a listener location estimator, a listener identifier, and a voice command processor. Inputs from the listener location estimator, the listener identifier, and the voice command processor are fed into an array processor. The array processor drives the one or more loudspeaker arrays to emit beam patterns into the listening area based on inputs from each of these devices. By examining the location, preferred usage settings, and voice commands from listeners, the generated beam patterns are customized to the explicit and implicit preferences of the listeners with minimal direct input. Other embodiments are also described.

Abstract: An acoustic port of acoustic device is covered with a mesh and/or other structure that resists entry of liquid and/or other materials into the acoustic device. Apertures of a housing that are separated by an umbrella section are coupled to the acoustic port such that the umbrella section may cover the acoustic port. In this way, when liquid enters one or more of the apertures, the umbrella section may direct the liquid away from the mesh such that pressure from the liquid upon the mesh may be reduced. As such, potential damage to the mesh and/or internal acoustic device components may be mitigated. In some implementations, the apertures may be covered with an additional mesh. Such additional mesh may further reduce the pressure of entering liquid on the mesh covering the acoustic port of the acoustic device.

Abstract: An acoustic port of acoustic device is covered with a mesh and/or other structure that resists entry of liquid and/or other materials into the acoustic device. Apertures of a housing that are separated by an umbrella section are coupled to the acoustic port such that the umbrella section may cover the acoustic port. In this way, when liquid enters one or more of the apertures, the umbrella section may direct the liquid away from the mesh such that pressure from the liquid upon the mesh may be reduced. As such, potential damage to the mesh and/or internal acoustic device components may be mitigated. In some implementations, the apertures may be covered with an additional mesh. Such additional mesh may further reduce the pressure of entering liquid on the mesh covering the acoustic port of the acoustic device.

Abstract: A mesh network of printed circuit boards (PCBs) including a first PCB coupled to a second rigid PCB by way of an interlocking connection is provided. The interlocking connection has a degree of freedom that allows the first and second PCBs to form a twist angle between each other; the interlocking connector configured to provide electrical coupling between active components disposed in each of the first and second PCBs. A method of forming a substrate fabric including a mesh network as above is also provided. Further provided is a method of activating the mesh network of printed circuit boards as above.

Abstract: A joint speaker surround and gasket. The speaker surround of the joint speaker surround and gasket is formed of a surround material and has an inner edge defining a speaker cone aperture shaped to match a speaker cone and an outer edge portion shaped to match a housing. The gasket of the joint speaker surround and gasket is formed of a gasket material. The gasket is integrally bonded to the outer edge portion of the speaker surround.