A compression driver includes a magnet assembly and a waveguide mounted to the magnet assembly, the waveguide having a first side, an opposed second side, and a central aperture forming an exit of the compression driver. An annular diaphragm is disposed above the magnet assembly and adjacent the second side of the waveguide, the diaphragm having an external flat portion generally coplanar with an internal flat portion. A compression chamber is defined between the diaphragm and the second side of the waveguide, the second side of the waveguide having a final segment that tapers toward the central aperture, wherein part of the diaphragm is loaded by the compression chamber and part of the diaphragm radiates directly to the exit of the compression driver.

A speaker includes: a diaphragm having a dome shape; a tubular member having the diaphragm disposed inside, and having an inner diameter increasing toward a front; and a phase plug. The phase plug includes: a front surface, a rear surface facing a central portion on a front surface of the diaphragm at a constant interval in parallel, and a side surface connecting the front surface and the rear surface. A front surface of the phase plug is larger than a rear surface of the phase plug as viewed in a front-rear direction of a speaker. At least a part of a side surface of the phase plug has an inclined surface extending outward while extending forward, faces an inner circumferential surface of the tubular member and a front surface of the diaphragm, and directs a sound wave generated from the diaphragm toward an inner circumferential surface of the tubular member.

Loudspeaker (1) comprising: a container (2) provided with a front opening (3) delimited by at least two opposite edges (4, 5) of the container (2); at least one speaker (30, 31) housed in the container (2); a mounting panel (20) to which is fixed the at least one speaker (30, 31). The container (2) comprises a fixing guide having a guide axis (A-A) and the mounting panel (20) is a slide slidably received in the fixing guide to close the front opening (3). The container (2) comprises two front walls (10, 11) mutually arranged on opposite sides with respect to the front opening (3), wherein the front walls (10, 11) define an acoustic waveguide diverging between an inlet throat and an outlet mouth and wherein the front opening of the container (3) represents the inlet throat of the diverging acoustic waveguide.

A compression driver includes a magnet assembly and a waveguide mounted to the magnet assembly, the waveguide having a first side, an opposed second side, and a central aperture forming an exit of the compression driver. An annular diaphragm is disposed above the magnet assembly and adjacent the second side of the waveguide, the diaphragm having an external flat portion generally coplanar with an internal flat portion. A compression chamber is defined between the diaphragm and the second side of the waveguide, the second side of the waveguide having a final segment that tapers toward the central aperture, wherein part of the diaphragm is loaded by the compression chamber and part of the diaphragm radiates directly to the exit of the compression driver.

Sound emanating from the high-frequency diaphragm of a coaxial speaker will diffract into the annular gap between the tweeter unit and the midrange cone. This results in response irregularities. We therefore disclose a loudspeaker, comprising first and second drivers located substantially coaxially with the first driver located centrally and the second driver located concentrically around the first driver, the loudspeaker being bounded at its radially outer side for at least part of its extent by the voice coil former of the second driver and including a spacing between the outermost extent of the first driver and the innermost extent of the second driver thus defining an annular space, the annular space containing a sound-absorbent material. By placing the sound-absorbing material in the annular space, the resonances within this space are damped, thus alleviating their effect. The annular space can have a lower resonant frequency that is below the passband of the first driver. Essentially, instead of minimising the effect of the annular gap by reducing its size and seeking to seal its outer opening, we propose to enlarge the space so that the fundamental resonant frequency it exhibits drops out of the passband of the high-frequency driver and hence out of the frequency range of interest. This both prevents the fundamental frequency of the cavity from being excited, and also allows sufficient room within the space to accommodate a sound-absorbent material to absorb these undesirable resonances.

A compression driver includes a phasing plug including a base portion having a first side and an opposed second side, the first side including a central hub portion extending outwardly from the first side, the base portion including one or more apertures that extend therethrough from the first side to the second side. A diaphragm is disposed adjacent the phasing plug second side, and a compression chamber defined between the diaphragm and the phasing plug. In one embodiment, a front plate is attached to the phasing plug first side, the front plate having a central aperture generally aligned with the hub portion and base portion apertures. A horn may be attached to the front plate or directly to the phasing plug first side.

This disclosure relates to speakers and more specifically to an array speaker for distributing music uniformly across a room. A number of audio drivers can be radially distributed within a speaker housing so that an output of the drivers is distributed evenly throughout the room. In some embodiments, the exit geometry of the audio drivers can be configured to bounce off a surface supporting the array speaker to improve the distribution of music throughout the room. The array speaker can include a number of vibration isolation elements distributed within a housing of the array speaker. The vibration isolation elements can be configured to reduce the strength of forces generated by a subwoofer of the array speaker.

A method may include measuring a physical quantity associated with a load driven by an amplifier, generating a windowing function having a variable length and based on a number of samples of the physical quantity to be processed, applying the windowing function to the physical quantity, performing a transform on the physical quantity as filtered by the windowing function, and determining a characteristic of the load based on the transform.

A loudspeaker device includes first and second diaphragms arranged co-axially in an opposed relation to each other and having a rear volume in-between, each diaphragm having a plurality of motors operatively coupled thereto, and a frame having first and second ends, and first and second rims provided at the first and second ends, respectively. The motors of the first and second diaphragms are arranged in the same plane, and the motors are provided on the frame around the periphery of the first and second diaphragms.

A treble loudspeaker with an improved mounting structure for a phase plug, having a T-shaped iron, a magnet, a washer, a phase plug and a diaphragm. The magnet is located between the T-shaped iron and the washer. The T-shaped iron has a central hole. The phase plug is inserted into the central hole and fixedly connected to the T-shaped iron. A soft gasket is provided at a plane junction between the phase plug and the T-shaped iron. The diaphragm is located above the phase plug to cover the phase plug, and a sound guiding gap is provided between the diaphragm and the phase plug.