Embodiments relate to an audio system configured to provide enhancement of low audio frequencies. The audio system includes a tissue transducer and a speaker coupled to the tissue transducer. The tissue transducer is configured to be coupled to a tissue of a user (e.g., pinna of a user's ear). The speaker includes a diaphragm having a first surface and a second surface that is opposite the first surface. The first surface is configured to generate a first set of airborne acoustic pressure waves, and the second surface is configured to generate a backpressure. The tissue transducer is driven by the backpressure to vibrate the tissue to form a second set of acoustic pressure waves. The first set of airborne acoustic pressure waves and the second set of acoustic pressure waves together form audio content that is presented to the user.

Presented herein, is a modular tactile flooring system. The tactile flooring system is made from individual modules that each support a tactile transducer. The individual modules may be assembled to form a tactile dance floor. More specifically, the modules may interlock to form a single dance floor surface. Further, the modules may be individually leveled to provide a level surface even when an underlying support surface is uneven. that facilitates assembly of a tactile sound floor and readily permits the tactile sound floor to be assembled in a desired location.

A terminal speaker includes an enclosure with accommodating space with an affixed sound production monomer. The sound production monomer has a diaphragm configured to vibrate to produce sound. The enclosure includes a first inner bottom wall and an inner sidewall fastened to the first inner bottom wall. The diaphragm is fastened to the inner sidewall, dividing the accommodating space into front and rear cavities. The first inner bottom wall is in the front cavity. A sound outlet hole penetrates the inner sidewall. The front cavity is in communication with the sound outlet hole by a front cavity channel. The diaphragm is tilted relative to the first inner bottom wall. The perimeter of the end of the front cavity in communication with the sound outlet hole is greater than the perimeter of the end of the front cavity remote from the sound outlet hole.

A smart sound mirror device includes: a speaker unit configured to output a sound; a mirror unit detachably installed to the speaker unit; and a wall mount bracket configured to be fixedly installed on a wall, the wall mount bracket being selectively fixed to the speaker unit or the mirror unit. Further, the speaker unit includes: a speaker body; a speaker built in the speaker body; a speaker bracket mounted on a rear portion of the speaker body to be fixed to the wall mount bracket; and a speaker cover mounted on a front portion of the speaker body and providing a sound slit through which a sound of the speaker is output.

One example process includes playing, via one or more loudspeakers, one or more audio frequencies at a particular sound pressure level, measuring, via a sensor, a displacement of a laser beam being emitted from a laser source through a slot of a soundbar housing the one or more loudspeakers during the playing, and determining, via a processor, one or more characteristic coefficients of a grommet based on the displacement.

A sounding device includes a first vibrating system, a second vibrating system and a magnetic circuit system, where the first vibrating system includes a first vibrating diaphragm and a voice coil arranged inside the first vibrating diaphragm, and the first vibrating diaphragm includes a first central portion; the second vibrating system includes a second vibrating diaphragm disposed opposite to the first vibrating diaphragm, and the second vibrating diaphragm includes a second central portion; and the magnetic circuit system is arranged between the first vibrating diaphragm and the second vibrating diaphragm, and the voice coil is accommodated in a magnetic gap of the magnetic circuit system; the magnetic circuit system defines an avoid hole; and at least one of the first central portion and the second central portion is extended into the avoid hole to fixedly connect the first central portion and the second central portion.

An electroacoustic conversion device includes a vibration plate, an inner voice coil attached to the vibration plate, an outer voice coil attached to the vibration plate outside the inner voice coil to surround the inner voice coil, a magnet, a yoke, and the frame which holds the vibration plate and the yoke. The magnet includes a wiring portion which is in a form of a through hole or a notch in which inner signal lines for the inner voice coil are provided.

The present application discloses a screen sounding system having a screen, an exciter for driving the screen, and a magnetic element fixedly connected with the screen. The exciter includes a housing with an accommodation space and a magnet arranged in the accommodation space. The housing is fixed on the magnetic element through magnetic attraction force between the magnet and the magnetic element. Compared with the related art, the screen sounding system disclosed by the present application facilitates removal and installation of the exciter. The position of the exciter can be adjusted through slip. Meanwhile, the magnetic element can avoid an influence on the screen caused by a magnetic field of the exciter.

A speaker device includes a frame, a vibration unit and a magnetic circuit unit. The vibration unit includes a diaphragm fixed to the frame and a voice coil. The magnetic circuit unit includes a yoke and a magnet assembly that is accommodated and fixed in the yoke and is spaced apart from the yoke to form a magnetic gap. The voice coil is inserted in the magnetic gap. The yoke includes a yoke bottom wall, a yoke side wall and flanges. The flange includes a first section and a second section extending from the first section. A side of the first section close to the second section and the second section enclose a fixing step. The second section is fixed to the frame. The speaker device of the present disclosure has better reliability.

A loudspeaker configured to be mounted in a seat assembly is disclosed. The loudspeaker includes: a diaphragm having a first radiating surface and a second radiating surface, wherein the first radiating surface and the second radiating surface are located on opposite faces of the diaphragm; a drive unit configured to move the diaphragm based on an electrical signal; a loudspeaker support structure, wherein the diaphragm is suspended from the loudspeaker support structure via one or more loudspeaker suspension elements.