The speaker device includes a cylindrical main body, a sound receiving portion, plural speaker units and at least one passive radiation plate. The cylindrical main body includes a top portion and a bottom portion. The sound receiving portion disposed on the top portion of the cylindrical main body. The speaker units are disposed within the cylindrical main body. The exports of the speaker units face the directions extending radially outward from an axial center of the cylindrical main body respectively. Each of the speaker units outputs a voice signal. The passive radiation plate is disposed on a surrounding surface of the cylindrical main body, and located between the speaker units and the bottom portion of the cylindrical main body. The passive radiation plate is driven to produce resonance with the air within the cylindrical main body, which is vibrated by the vibration of the voice signal.

An electronic instrument includes a housing, a fitting part that is freely attached/detached to/from an illumination apparatus, and a sound reproduction space that is formed in the housing.

An earpiece includes a shell forming a cavity and a sound channel having a first end connected to and in communication with the cavity, and a second end opposite to the first end, the sound channel forming a single pass-through cavity extending from the first end to the second end; an insert disposed within the cavity; a speaker; a circuit board assembly mounted onto the insert, the circuit board assembly comprising a printed circuit board defining a first side and a second side, and a first microphone disposed on the first side; an acoustic chamber formed between the insert and the circuit board assembly, the first microphone being disposed within the acoustic chamber; and an acoustic channel extending from the acoustic chamber to the sound channel.

The speaker device includes a cylindrical main body, a sound receiving portion, plural speaker units and at least one passive radiation plate. The cylindrical main body includes a top portion and a bottom portion. The sound receiving portion disposed on the top portion of the cylindrical main body. The speaker units are disposed within the cylindrical main body. The exports of the speaker units face the directions extending radially outward from an axial center of the cylindrical main body respectively. Each of the speaker units outputs a voice signal. The passive radiation plate is disposed on a surrounding surface of the cylindrical main body, and located between the speaker units and the bottom portion of the cylindrical main body. The passive radiation plate is driven to produce resonance with the air within the cylindrical main body, which is vibrated by the vibration of the voice signal.

A dual-diaphragm loudspeaker driver assembly can include a multiple pole magnet structure, and first and second pole piece assemblies can be provided on opposite first and second sides of the multiple pole magnet structure. In an example, each pole piece assembly defines an airgap over a polarity transition region on a respective side of the magnet structure. First and second voice coils can be provided in respective ones of the airgaps, wherein each of the voice coils is coupled to a respective diaphragm assembly, and at least one acoustic tuning port can be configured to provide a damped acoustic communication path between first and opposite second sides of each diaphragm assembly.

A first MEMS motor and s second MEMS motor share a common back volume and a common support structure, and the common support structure is configured to support a first diaphragm and the first back plate, and the common support structure is also configured to support the second diaphragm and the second back plate. A channel passes through the common support structure and communicates with the exterior environment, the channel being of a first diameter, the channel being disposed beyond an outer periphery of each back plate. An opening extends through the silicon nitride layer, the opening having a second diameter, the second diameter being less than the first diameter, the channel communicating with the opening. The opening has a length that is orthogonal to second diameter, and the first back plate and the second back plate have a thickness, wherein the length is no greater than twice the thickness. The channel and the opening allow direct communication between the exterior environment and the common back volume.

A loudspeaker system includes a loudspeaker enclosure having a front and a rear. Further, the loudspeaker system includes at least one first bass sound source, arranged in the loudspeaker enclosure, having a main direction of radiation at the front and at least one treble and/or midrange sound source. At least one first chamber of the loudspeaker enclosure is provided with a first sound exit opening that is at the side in regard to the main direction of radiation. The loudspeaker system further comprises at least one first directivity bass sound source that is arranged in the first chamber.

An integrated loudspeaker assembly along with associated methods and systems for enhancing audio output from a consumer electronic device including such an integrated loudspeaker assembly are disclosed. More particularly an integrated loudspeaker assembly configured to utilize the enclosure of an associated consumer electronic device for back volume is disclosed. Methods and systems for optimizing the audio performance of a consumer electronic device with an integrated loudspeaker assembly are also disclosed.

Speaker assemblies for a headphone device may include an audio speaker configured to produce audible sound in response to receiving an audio signal at the audio speaker. A tactile bass vibrator distinct from the audio speaker may be operatively connected to the audio speaker. The tactile bass vibrator may be configured to produce tactile vibrations in response to receiving the audio signal at the tactile bass vibrator. A current divider may be operatively connected to the audio speaker and the tactile bass vibrator. A pivoting portion of an attachment structure of an ear cup supporting the audio speaker, tactile bass vibrator, and current divider may intersect with a geometrical central axis of the ear cup, and the audio speaker and tactile bass vibrator may not intersect with the geometrical central axis of the respective ear cup.

An integrated loudspeaker assembly along with associated methods and systems for enhancing audio output from a consumer electronic device including such an integrated loudspeaker assembly are disclosed. More particularly an integrated loudspeaker assembly configured to utilize the enclosure of an associated consumer electronic device for back volume is disclosed. Methods and systems for optimizing the audio performance of a consumer electronic device with an integrated loudspeaker assembly are also disclosed.