An earphone comprising an earphone housing having a wall comprising (1) a front side that joins (2) an end portion in which a primary sound output opening is formed, which joins (3) a face portion in which a secondary output opening is formed, which joins (4) a back side which joins the front side and encloses a driver, wherein the primary output opening is dimensioned to output sound generated by a diaphragm of the driver contained within the earphone housing into the ear and the secondary output opening is dimensioned to vent the ear to a surrounding environment, and wherein the primary output opening and the secondary output opening face different directions.

Example techniques may involve reduction of turbulence noise from a sound transducer that is mounted within an interior housing of a playback device. An example playback device may include an enclosure comprising a first interior volume and a second interior volume. The playback device may further include a speaker mounted within an interior of the enclosure. The speaker includes a diaphragm dividing the first interior volume and the second interior volume and the speaker is moveable along an axis to generate sound. The playback device may also include a first speaker vent providing airflow between the first interior volume and an exterior of the enclosure and a second speaker vent providing airflow between the first interior volume and the exterior of the enclosure. The first speaker vent directs airflow in a first direction and second speaker vent directs airflow in a second direction.

An MEMS microphone is provided, including a base having a back cavity, and a capacitor system disposed on the base, the capacitor system including a backplate and a diaphragm disposed oppositely to the backplate. The diaphragm includes a body portion and a plurality of venting portions connected to the body portion, each of the plurality of venting portions includes a venting aperture penetrating through the diaphragm and a membrane flap partially fixed to the diaphragm and located in the venting aperture. The MEMS microphone further includes an insulation connecting pillar having one end fixedly connected to the backplate and another end fixedly connected to the membrane flap. Compared with the related art, the venting portion is fixedly connected to the backplate through the insulation connecting pillar, so that the venting portion is not easily warped, thereby improving reliability of the MEMS microphone.

An audio system for a vehicle is provided with a woofer speaker having a front side for producing a required bass-range acoustic output in a passenger compartment of the vehicle and a back side having an infinite baffle. The audio system includes a bass-compatible speaker disposed in the passenger compartment of the vehicle. A controller is in communication with the woofer and the bass-compatible speaker and is programmed to distribute the required bass-range sound output to the woofer and the bass-compatible speaker based on at least one of a vehicle speed and a sound output level of the audio system.

A speaker includes a frame and a partition wall coupled with the frame to define a boundary between a high-pitched sound zone and a low-pitched sound zone. The high-pitched sound zone includes an electromagnetic component accommodating area and plural discontinuous sound chamber extension areas. The electromagnetic component accommodating area and the plural discontinuous sound chamber extension areas are fluid-communicable.

A speaker includes a frame and a partition wall coupled with the frame to define a boundary between a high-pitched sound zone and a low-pitched sound zone. The high-pitched sound zone includes an electromagnetic component accommodating area and plural discontinuous sound chamber extension areas. The electromagnetic component accommodating area and the plural discontinuous sound chamber extension areas are fluid-communicable.

A MEMS device includes a package for providing an inner volume, a MEMS microphone arranged in the inner volume, a sound port through the package to the inner volume, and a passive acoustic attenuation filter acoustically coupled to the sound port.

Aspects of the subject technology relate to inductive acoustic filters for acoustic devices. An inductive filter may include a substrate, an etched serpentine channel in a surface of the substrate and extending within the substrate from a first port in the substrate to a second port in the substrate. The inductive filter may also include a polymer cover layer adhesively attached to the surface of the substrate over the etched serpentine channel. The inductive filter may be positioned over an opening in a substrate of an acoustic module, such as a microphone module or a speaker module.

The present disclosure discloses an acoustic output device. The acoustic output device may include a first acoustic driver including a first diaphragm; a second acoustic driver including a second diaphragm; a control circuit electrically connected with the first acoustic driver and the second acoustic driver respectively, the control circuit provides a first electrical signal for driving a vibration of the first diaphragm, and a second electrical signal for driving a vibration of the second diaphragm, and a phase of the first electrical signal and a phase of the second electrical signal are opposite; and a housing supporting the first acoustic driver and the second acoustic driver, wherein a sound generated by the vibration of the first diaphragm is radiated outward through a first sound guide hole on the housing, and a sound generated by the vibration of the second diaphragm is radiated outward through a second sound guide hole on the housing.

Headphones may include an ear-cup housing and an audio driver disposed at least partially within the ear-cup housing. The audio driver may include a driver housing, a diaphragm suspended from the driver housing, one of a magnet and a coil carried on a back side of the diaphragm, and another of the magnet and the coil carried by the driver housing behind the diaphragm, the magnet and coil magnetically coupled with one another such that electrical current flowing through the coil generates a magnetic force acting on the diaphragm through the magnet or coil carried on the back side of the diaphragm. A port may extend through a surface of the driver housing directly between an acoustical cavity within the driver housing and an exterior of the ear-cup housing without communicating acoustically with a volume of space outside the driver housing and within the ear-cup housing.