A cushion member that is secured to a massage table or massage chair and contains a video or virtual reality headset within a substantially central opening or cutout of the cushion member to allow an individual to view video, virtual reality scenes, or other text, graphics or indicia while receiving a massage. A retaining shelf can also be secured to the cushion member to provide support for the video or virtual reality headset. Speakers can also be embedded in the cushion member or a headphone jack or port can be provided with the headset to also allow the individual to listen to any audio associated with the displayed material on the headset.

An elevating speaker device for use in bathtub includes: a main body having an accommodation space formed therein and having at least one water hole and a penetrating hole; and an elevating speaker member, having a lower portion thereof disposed with an inner fastening member having a base and an inner sliding member, the inner fastening member respectively has a damping teeth and a spring, the inner sliding member has a long teeth connected to the damping teeth; the elevating speaker member has an inclined plate downwardly inclined from one end towards another end, and has two ends respectively downwardly extended with a water discharging channel and a fastening channel, at least one plastic sleeve is disposed in the fastening channel and sleeved with a tubular member allowing a power wire and a signal wire to be enclosed.

A MicroElectroMechanical System (MEMS) includes a MEMS device; a feature extraction component coupled to an output of the MEMS device, wherein the feature extraction component is configured to provide a plurality of features of an output signal of the MEMS device; and a low data rate interface coupled to the feature extraction components, wherein the low data rate interface is configured to transmit the plurality of features of the output signal of the MEMS device, and wherein a low data rate of the low data rate interface is determined by a number of the plurality of features transmitted, wherein the MEMS device, the feature extraction component, and the low data rate interface are packaged together in a semiconductor package.

A MicroElectroMechanical System (MEMS) includes a MEMS device; a feature extraction component coupled to an output of the MEMS device, wherein the feature extraction component is configured to provide a plurality of features of an output signal of the MEMS device; and a low data rate interface coupled to the feature extraction components, wherein the low data rate interface is configured to transmit the plurality of features of the output signal of the MEMS device, and wherein a low data rate of the low data rate interface is determined by a number of the plurality of features transmitted, wherein the MEMS device, the feature extraction component, and the low data rate interface are packaged together in a semiconductor package.

The present invention provides a microphone assembly having shielding function for a motor vehicle, comprising: a microphone circuit board having a microphone, which is supplied by a differential audio bus such that the ground potential of the microphone is floating; a cover which is located outside the microphone circuit board; a foamy part which is located between the cover and the microphone circuit board; and a shielding film which is suitable for shielding the microphone against electrostatic discharge, wherein the shielding film is located between the cover and the foamy part and covers the outer surface of the foamy part, and wherein the shielding film is electrically conductive and grounded to a vehicle chassis ground potential. In this situation, the shielding film can collect electrostatic charges and guide them to the chassis ground of the vehicle, so that electronic components on the microphone circuit board under the shielding film, especially the microphones having the floating ground, can be shielded from electrostatic discharge (ESD) damage. As a result, the ESD robust performance of the microphone assembly is significantly improved.

A waveguide housing for a speaker assembly. The speaker assembly includes first and second drivers coupled to the waveguide housing where the first driver generates a midrange sound signal and the second driver emits a high-frequency sound signal. The waveguide housing includes a first plurality of sound channels configured to receive the midrange sound signal from the first driver such that the midrange sound signal travels through the first plurality of sound channels and is emitted from the waveguide housing by a first plurality of openings in the waveguide housing. The waveguide housing also includes a second plurality of sound channels configured to receive the high-frequency sound signal from the second driver such that the high-frequency sound signal travels through the second plurality of sound channels and is emitted from the waveguide housing by a second plurality of openings in the waveguide housing.

A display device includes: a display panel including a first substrate and a light emitting element layer disposed on the first substrate; and a sound generator disposed on one surface of the first substrate, where the sound generator vibrates the display panel to output a sound. The sound generator includes: a first vibration generator which vibrates the display panel by generating a magnetic force using a first voice coil therein; and a second vibration generator including a vibration layer which contracts or expands based on a voltage applied thereto to vibrate the display panel, where the first vibration generator and the second vibration generator overlap each other in a thickness direction of the display panel.

A vehicle sensor assembly includes an optical sensor surface, at least two transducers arranged to input energy into the optical surface to produce an energy wave through the optical sensor surface and sense an attribute of an energy wave within the optical sensor surface. A controller arranged to drive the at least two transducers to input energy into the optical surface to produce an energy wave within the optical sensor surface to dislodge debris from the optical sensor surface.

A loudspeaker containing a sound-generating element and a grill mounted as a cover in front of the sound-generating element. The grill has optically transparent areas. At least one lighting element is mounted between the sound-generating element and the grill, the lighting element being visible from the outside through the optically transparent areas of the grill when illuminated.

A loudspeaker containing a sound-generating element and a grill mounted as a cover in front of the sound-generating element. The grill has optically transparent areas. At least one lighting element is mounted between the sound-generating element and the grill, the lighting element being visible from the outside through the optically transparent areas of the grill when illuminated.