A speaker system is provided with a housing adapted to mount to a support. A driver is supported by the housing and arranged to project sound about a first axis extending at an offset angle relative to a longitudinal axis extending from the housing. A waveguide extends from the driver to define a cavity extending along the first axis. The waveguide includes a first segment formed at a first angle relative to the longitudinal axis, and a second segment formed at a second angle relative to the longitudinal axis, wherein the second segment is arranged opposite the first segment and the second angle is greater than the first angle to collectively provide an asymmetrical sound pattern in a first plane.

An ear-plug device is an in-ear device that presents audio content to an ear canal of a user. The in-ear device includes a body configured to at least partially fit inside the ear canal of the user, and a transducer assembly coupled to the body. The transducer assembly comprises at least one transducer located within the ear canal. The at least one transducer is configured to vibrate a portion of the ear canal to cause the ear canal to create an airborne acoustic pressure wave in the ear canal in accordance with vibration instructions. The airborne acoustic pressure wave corresponds to and is for presentation of the audio content to the user.

According to an aspect of the disclosure, a loudspeaker includes an enclosure having a front sidewall that is disposed between a first acoustic opening and a second acoustic opening. The loudspeaker further includes a motorboard comprising a first opening arranged along a plane and a second opening arranged along the plane, an active driver, and a passive component. The active driver is arranged concentric to the first opening to transmit sound waves directly through the first opening toward the front sidewall. In addition, the passive component is arranged concentric to the second opening to transmit sound waves directly through the second opening toward the front sidewall.

Disclosed is a terminal apparatus, including a protective shell and a sounding device installed in the protective shell, where the sounding device includes a vibration system and a magnetic circuit system; where the vibration system includes a vibration diaphragm including a first surface and a second surface facing away from the first surface; the magnetic circuit system is located on a side of the second surface of the vibration diaphragm; the sounding device defines a first sounding hole at a position in communication with a space on a side of the first surface, and a second sounding hole at a position in communication with a space on the side of the second surface; and the protective shell defines a first terminal sounding hole in communication with the first sounding hole, and a second terminal sounding hole in communication with the second sounding hole.

In an audiovisual system, in which video is displayed on a screen that does not permit sound to pass through the screen, such as a light emitting diode panel, a high-frequency speaker positioned above an audience seating area can direct sound toward the screen, so that the screen can reflect the sound toward the audience seating area. The high-frequency speaker can be used with one or more low-frequency speakers positioned at or near the height of the audience seating area. The low-frequency and high-frequency sounds can appear to originate from close to the same height, thereby creating a realistic audio image at the audience seating area. A spectral filter can negate the spectral effects of propagation to and reflection from the screen. Suitable time delays can synchronize the high-frequency sound with the low-frequency sound and with video displayed on the screen.

A sound-generating device, a display device, a sound-generating controlling method, and a sound-generating controlling device are provided. The sound-generating device includes: a reflection plate which includes a first sound wave reflection face arranged towards a first direction; a plurality of main loudspeakers, the plurality of main loudspeakers are distributed in an array in a preset three-dimensional space, and the preset three-dimensional space is located at one side of the first sound wave reflection face towards a first direction; the plurality of main loudspeakers include first main loudspeakers with a sound-generating direction towards the first direction, and second main loudspeakers with a sound-generating direction towards a second direction, the second direction is an opposite direction of the first direction; and the sound waves emitted by the second main loudspeakers are transmitted to the first sound wave reflection face and can be reflected by the first sound wave reflection face.

A compression driver for an omnidirectional loudspeaker having an inverted dome diaphragm, a phasing plug having a top portion facing a convex surface of the inverted dome diaphragm and a plurality of concentric apertures that cooperate with the convex surface of the inverted dome diaphragm. Each aperture has a predetermined radial width and is spaced a predetermined concentric distance from an adjacent aperture converging at an exit of the phasing plug. The compression driver has a dispersion control assembly mounted to the bottom portion of the phasing plug along the central axis.

An open-ear headphone with an acoustic module that is configured to be located at least in part in a concha of an outer ear of a user. The acoustic module includes an acoustic transducer, and a sound-emitting opening that is configured to emit sound produced by the acoustic transducer. A body is coupled to the acoustic module and includes a first portion that is configured to pass over an outer side of at least one of an anti-helix and a helix and a lobule of the outer ear, and a second portion that is configured to be located behind the outer ear.

According to an embodiment, a wearable device includes: a case including an inner space and including a through-hole connecting the inner space and an outside of the wearable device; a speaker disposed within the case and configured to output audio; and a nozzle including audio path extending from the inner space to the outside of the wearable device, inserted to the through-hole, rotatably coupled to the case within the through-hole; wherein, the case may include a seating portion supporting a part of the nozzle disposed inside the case and formed along the periphery of the through-hole; and a guiding portion disposed in the seating portion and configured to guide the rotation of the nozzle.

Provided is a speaker box, including housing and sounding unit having diaphragm including vibration portion and suspension portion. The housing includes holder, lower and upper covers. The holder includes holder body, holder extension portion and holder fixing portion. The sounding unit is fixed to the holder fixing portion. Orthographic projection of the vibration portion completely falls into the holder body. The suspension portion is arc-shaped formed by recessing away from the holder body. The lower cover includes lower cover plate and lower cover sidewall. The sounding unit, the holder and the lower cover sidewall define front sound cavity. The sounding unit and the lower cover define rear sound cavity. The lower cover sidewall, the holder fixing portion, the holder extension portion and the upper cover define auxiliary rear sound cavity communicated with the rear sound cavity. The speaker box has large cavity volume and good acoustic performance.