A sound emitter device for use on a motor vehicle comprises a casing comprising an axial wall and a bottom wall, the axial wall extending along a vertical axis from the bottom wall toward an opening opposite the bottom wall, a control circuit, an acoustic membrane that closes the opening of the casing and that is provided on its lower face with excitation means controlled by the control circuit a peripheral rim that is arranged in the opening, the external peripheral edge of the acoustic membrane being mounted to bear on the peripheral rim, a secondary wall that is made in one piece with the peripheral rim and that is bent toward the peripheral rim so as to retain the acoustic membrane by clamping its external peripheral edge between the peripheral rim and the secondary wall.

A thin speaker driver has a supporting frame, a magnet assembly, a voice coil assembly, a spider, a surround, and a diaphragm. The diaphragm is curved in radial section and has multiple coaxially arranged arc portions. A radial section of each arc portion has a curvature radius. The curvature radiuses of the radial sections of the arc portions are different from each other. Two of the arc portions that are disposed adjacent to each other are tangent to each other at which the two adjacent arc portions connect to each other. With the curvature variation of the radial section of the arc portions, different arc portions can be use to create sounds with different pitches. Accordingly, the speaker driver can create sounds with wide frequency responses to achieve full-range operation and thickness of the speaker driver can be greatly reduced, such that the speaker driver can be thinned.

A portable electronic device is described and includes a device housing, an acoustic housing disposed within the device housing and defining an interior volume, a speaker diaphragm assembly disposed within the interior volume and in fluid communication with a first opening leading out of the housing, and a microphone disposed within the interior volume and in fluid communication with a second opening leading out of the acoustic housing. Placing both the speaker diaphragm assembly and microphone within the same acoustic housing allows both components to share common power and data transfer circuitry. Furthermore, the additional volume of the acoustic housing used to accommodate the microphone can improve the acoustic performance of the speaker diaphragm assembly by increasing the back volume associated with the speaker diaphragm assembly.

Headphones include a left loudspeaker element; a right loudspeaker element; and a holder for holding the left loudspeaker element and the right loudspeaker element, such that the loudspeaker elements can be attached to the ears, wherein the left loudspeaker element or the right loudspeaker element includes: a first sound converter; a second sound converter, wherein the first sound converter is implemented such that the first sound converter provides directed emission in the direction of an ear in the operating position of the headphones, and the second sound converter is implemented such that the second sound converter provides no or less directed emission than the first sound converter in the direction of the ear in the operating position of the headphones.

A speaker device includes: a diaphragm that radiates sound; an edge arranged in an outer periphery of the diaphragm; a frame arranged in an outer periphery of the edge, and including an annular attachment part connected to an outer peripheral region of the edge; and a connecting member arranged between the outer peripheral region and the attachment part and adhered to the outer peripheral region and the attachment part. An inner diameter of the attachment part is less than an inner diameter of the outer peripheral region.

A speaker device includes: a diaphragm that radiates sound; an edge arranged in an outer periphery of the diaphragm; a frame arranged in an outer periphery of the edge, and including an annular attachment part connected to an outer peripheral region of the edge; and a connecting member arranged between the outer peripheral region and the attachment part and adhered to the outer peripheral region and the attachment part. An inner diameter of the attachment part is less than an inner diameter of the outer peripheral region.

A speaker device includes: a diaphragm that radiates sound; an edge arranged in an outer periphery of the diaphragm; an attachment part facing an outer peripheral region of the edge; and a connecting member held between the outer peripheral region of the edge and the attachment part, wherein the connecting member is adhered to at least one of the outer peripheral region or the attachment part, and the edge has a curved portion convexly curved on a sound radiation side.

A speaker device includes: a diaphragm that radiates sound; an edge arranged in an outer periphery of the diaphragm; an attachment part facing an outer peripheral region of the edge; and a connecting member held between the outer peripheral region of the edge and the attachment part, wherein the connecting member is adhered to at least one of the outer peripheral region or the attachment part, and the edge has a curved portion convexly curved on a sound radiation side.

A speaker comprises a permanent magnet (2) and a coil (8) positioned around the permanent magnet (2) and attached to a membrane (10), wherein the membrane comprises an elastomer of thickness less than 0.3 mm and with a Young's modulus below 100 MPa.

An electrodynamic compression driver is defined that contains a compression chamber assembly partially bounded by an annular diaphragm. The compression chamber assembly has an annular axisymmetric geometry with a single exit for acoustic radiation. The chamber geometry is further defined such that only the zero-hertz mode of acoustic coupling is supported, allowing the use of a lumped parameter model for analysis of the acoustic coupling of diaphragm and compression chamber. The lumped parameter model is integrated with eigenmode analysis of diaphragm modes and characterization of the cross-coupling between diaphragm and compression chamber. The result is more rapid computation of how to control mechanical modes in the annular diaphragm so that they benefit the compression driver's acoustic output. Embodiments of compression chamber and diaphragms with geometry that facilitate modal control are provided.