Mitigating effects of cavity resonance in speakers

What is claimed is: 1. A speaker, comprising: a housing; at least one electro-acoustic driver including a diaphragm; and a cover secured to one or more of the housing and driver, the cover configured to partially extend over the diaphragm to affect an associated cavity resonance frequency of an air cavity adjacent to the diaphragm, wherein the cover extends over no more than one third of a cross sectional area of an open end of a conical structure formed by the diaphragm. 2. The speaker of claim 1 , wherein an extent to which the cover partially extends over the diaphragm is configured based on a target value of the cavity resonance frequency. 3. The speaker of claim 2 , wherein the target value of the cavity resonance frequency is higher than a cut-off frequency associated with a passband for the driver. 4. The speaker of claim 2 , wherein the extent to which the cover partially extends over the diaphragm is configured such that voice coil rubbing inside the speaker is avoided. 5. The speaker of claim 1 , wherein the at least one electro-acoustic driver is associated with low-frequency components of audio produced by the speaker. 6. The speaker of claim 1 , further comprising an acoustic horn that includes a first side panel and a second side panel, edges of the first and second side panels defining an opening for receiving acoustic outputs from one or more high-frequency drivers. 7. The speaker of claim 6 , wherein the opening is disposed proximate to an inside end of the at least one electro-acoustic driver, the inside end being opposite to an outside end of the at least one acoustic driver, wherein the outside end is closer than the inside end to an exterior sidewall of the housing. 8. The speaker of claim 6 , further comprising a manifold disposed between the opening and the one or more high-frequency drivers, the manifold including a plurality of acoustic passages for connecting the opening to each of the one or more high-frequency drivers. 9. The speaker of claim 8 , wherein the opening has a convex curvature extending outward from the housing. 10. The speaker of claim 9 , further comprising an adaptor disposed between the manifold and the acoustic horn, the adaptor including a plurality of apertures for the acoustic outputs from the one or more high-frequency drivers to radiate from the plurality of acoustic passages to the acoustic horn. 11. The speaker of claim 10 , wherein the adaptor is semi-flexible, and configured to conform to the convex curvature of the opening. 12. The speaker of claim 10 , wherein the adaptor includes a plurality of bending portions configured to allow the adaptor to conform to the convex curvature of the opening. 13. The speaker of claim 1 , wherein the cover is constructed of a polycarbonate and acrylonitrile butadiene styrene (ABS) blend. 14. An acoustic transducer comprising: a driver cone comprising: a central portion, an annular peripheral portion, and a diaphragm between the central portion and the peripheral portion, wherein the central portion, the annular peripheral portion, and the diaphragm together form a closed end of an air cavity adjacent to the driver cone; an electrodynamic driver configured to move the driver cone to vary pressure levels within the air cavity in accordance with an electrical signal; and a cover disposed in contact with the annular peripheral portion such that the cover extends over a portion of a plane of the annular peripheral portion to affect an associated cavity resonance frequency of the air cavity, wherein the cover extends over no more than one third of a cross sectional area of the portion of the plane bounded by the annular peripheral portion. 15. The acoustic transducer of claim 14 , wherein an extent to which the cover extends over the plane of the annular peripheral portion is configured based on a target value of a cavity resonance frequency associated with the air cavity. 16. The acoustic transducer of claim 15 , wherein the target value of the cavity resonance is higher than a cut-off frequency associated with a passband for the driver. 17. The acoustic transducer of claim 15 , wherein the extent to which the cover extends over the plane of the annular peripheral portion is configured such that voice coil rubbing in the acoustic transducer is avoided. 18. An acoustic transducer comprising: a driver cone comprising: a central portion, an annular peripheral portion, and a diaphragm between the central portion and the peripheral portion, wherein the central portion, the annular peripheral portion, and the diaphragm together form a closed end of an air cavity adjacent to the driver cone; an electrodynamic driver configured to move the driver cone to vary pressure levels within the air cavity in accordance with an electrical signal; and a cover disposed in contact with the annular peripheral portion such that the cover extends over a portion of a plane of the annular peripheral portion to affect an associated cavity resonance frequency of the air cavity, wherein the cover is configured such that the cover fits over a part of the annular peripheral portion in conformity with a profile of the part. 19. The acoustic transducer of claim 18 , wherein the part of the annular peripheral portion is selected in accordance with a target radiation pattern associated with the acoustic transducer. 20. A speaker comprising: a housing enclosed by two sidewalls, a rear wall, a top surface, and a bottom surface; two or more low-frequency drivers disposed within the housing such that front faces of the low-frequency drivers are substantially parallel to the rear wall of the housing; a cover disposed over each of the two or more low-frequency drivers such that the cover partially extends over a diaphragm of the corresponding low-frequency driver to affect an associated cavity resonance frequency of an air cavity adjacent to the diaphragm, wherein the cover extends over no more than one third of a cross sectional area of an open end of a conical structure formed by the corresponding diaphragm; one or more high-frequency drivers disposed between the low-frequency drivers and the rear wall of the housing; and a manifold disposed within the housing, the manifold comprising multiple acoustic passages for radiating acoustic outputs from the high-frequency drivers out of the housing. 21. The speaker of claim 20 , wherein a target value of the cavity resonance frequency is higher than a cut-off frequency associated with a passband for the corresponding driver. 22. The acoustic transducer of claim 2 , wherein the target value of the cavity resonance frequency is higher than a cut-off frequency associated with a passband for the driver.