Claims
- 1. A loudspeaker enclosure system including:a) a total of first and second chambers within the enclosure system; b) at least one electro-acoustic transducer with a vibratable diaphragm having a first acoustical coupling surface and a second acoustical coupling surface; c) at least one differential area passive radiator within the enclosure system having three separate acoustical coupling surface areas including a small unitary acoustical coupling surface area, a large primary acoustical coupling surface area, and a differential acoustical coupling surface area, d) said first acoustical coupling surface of the said vibratable diaphragm being substantially air coupled through the first chamber to a first of the three separate acoustical coupling surface areas of said at least one differential area passive radiator; and e) a second of the three separate acoustical coupling surface areas of said at least one differential area passive radiator acoustically being coupled into the second chamber and from said second chamber to the external environment through at least a first opening of predetermined dimensions; f) a third primary acoustical coupling surface area of the three separate acoustical coupling surface areas of said at least one differential area passive radiator being acoustically coupled to the external environment.
- 2. The loudspeaker enclosure system of claim 1 wherein said opening of predetermined dimensions is at least a first passive acoustic radiator.
- 3. The loudspeaker enclosure system of claim 2 wherein said first of three separate acoustical coupling surfaces of said differential area passive radiator is the differential surface area of said differential area passive radiator.
- 4. The loudspeaker enclosure system of claim 2 wherein said first of three separate acoustical coupling surfaces of said differential area passive radiator is the small unitary surface area of said differential area passive radiator.
- 5. The loudspeaker enclosure system of claim 2 wherein said passive acoustic radiator has a predetermined characteristic of acoustic resistance.
- 6. The loudspeaker enclosure system of claim 2 wherein said passive acoustic radiator has a predetermined characteristic of acoustic mass.
- 7. A method for enhancing the output of at least one differential area passive radiator operating over a passband of frequencies and having at least three acoustic surface areas, including at least two surface areas of differing size, mounted in a loudspeaker enclosure including the steps of:a) acoustically coupling a first side surface of a diaphragm of an active transducer through a first chamber to an acoustically isolated first acoustic surface area of at least one differential area passive radiator; b) acoustically coupling a second acoustic surface area of the differential area passive radiator to a second chamber and on through at least one opening of predetermined dimensions to the external environment; c) coupling a third and largest acoustic surface area of the differential area passive radiator to the external environment.
- 8. The method of claim 7 further including the step of:d) configuring the opening of predetermined dimensions as a passive acoustic radiator.
- 9. The method of claim 8 further including the step of:e) tuning the passive acoustic radiator to a frequency above the passband of the differential area passive radiator.
- 10. The method of claim 8 further including the step of:e) tuning the passive acoustic radiator to a frequency in the passband of the differential area passive radiator.
- 11. The method of claim 8 further including the step of:e) tuning the passive acoustic radiator to a frequency below the passband of the differential area passive radiator.
- 12. The method of claim 7 further including the step of:d) adding the characteristic of acoustic resistance to the opening of predetermined dimensions.
- 13. A bandpass loudspeaker enclosure system including:a) at least a first, second and third chamber within the enclosure system; b) at least one electro-acoustic transducer within the enclosure system having a vibratable diaphragm with a first acoustical coupling surface and a second acoustical coupling surface; c) at least one differential area passive radiator within the enclosure system having three separate acoustical coupling surface areas including a small unitary acoustical coupling surface area, a large primary acoustical coupling surface area, and a differential acoustical coupling surface area; d) said first acoustical coupling surface of the said vibratable diaphragm being substantially air coupled through the first chamber to a first of the three separate acoustical coupling surface areas of said at least one differential area passive radiator; and e) second of the three separate acoustical coupling surface areas of said at least one differential area passive radiator acoustically coupled into the second chamber and from said second chamber to the external environment through at least a first opening of predetermined dimensions, f) a third and largest of the three separate acoustical coupling surface areas of said at least one differential area passive radiator acoustically coupled to the external environment, g) said second acoustical coupling surface of the said vibratable diaphragm substantially air coupled into the third chamber.
- 14. The bandpass loudspeaker enclosure system of claim 13 wherein; the at least a first opening of predetermined dimensions is at least a first passive acoustic radiator.
- 15. The bandpass loudspeaker enclosure system of claim 14 wherein said at least a first passive acoustic radiator has a predetermined acoustic resistance.
- 16. The bandpass loudspeaker of claim 13 wherein said first of three separate acoustical coupling surfaces of said differential area passive radiator is the differential surface area of said differential area passive radiator.
- 17. The bandpass loudspeaker of claim 13 wherein said first of three separate acoustical coupling surfaces of said differential area passive radiator is the small unitary surface area of said differential area passive radiator.
- 18. The bandpass loudspeaker enclosure system of claim 14 wherein said at least a first passive acoustic radiator has a predetermined characteristic of acoustic mass.
- 19. The bandpass loudspeaker enclosure system of claim 14 wherein said third chamber enclosure volume is coupled to the external environment through at least a second passive acoustic radiator and said second passive acoustic radiator has a predetermined characteristic of acoustic mass.
- 20. The bandpass loudspeaker enclosure system of claim 19 wherein said at least a second passive acoustic radiator is an augmented passive radiator.
- 21. The bandpass loudspeaker enclosure system of claim 20 further comprising a fourth chamber in communication with said augmented passive radiator.
- 22. The bandpass loudspeaker enclosure system of claim 21 wherein said fourth chamber is coupled to the external environment through an additional passive acoustic radiator converting the closed architecture augmented passive radiator to an open architecture differential area passive radiator.
- 23. The bandpass loudspeaker enclosure system of claim 14 wherein the at least a first passive acoustic radiator is tuned to a frequency above the passband frequency range of the bandpass loudspeaker system.
- 24. The bandpass loudspeaker enclosure of claim 14 wherein the first passive acoustic radiator is tuned to a frequency in the pass band of the bandpass loudspeaker system.
- 25. The bandpass loudspeaker enclosure of claim 14 wherein the first passive acoustic radiator is tuned to a frequency below the pass band of the bandpass loudspeaker system.
- 26. The bandpass loudspeaker enclosure system of claim 22 wherein the additional passive acoustic radiator coupling said fourth enclosure volume to the external environment is tuned to a frequency above the resonant frequency of the differential area passive radiator.
- 27. The bandpass loudspeaker enclosure system of claim 22 wherein the additional passive acoustic radiator coupling said fourth enclosure volume to the external environment is tuned to a frequency at or below the resonant frequency of the differential area passive radiator.
- 28. The bandpass loudspeaker enclosure system of claim 22 wherein the additional passive acoustic radiator coupling said fourth enclosure volume to the external environment has the characteristic of acoustic resistance.
- 29. A bandpass loudspeaker enclosure system including:a) at least a first, second and third chamber within the enclosure system; b) at least one electro-acoustic transducer within the enclosure system having a vibratable diaphragm with a first acoustical coupling surface and a second acoustical coupling surface; c) at least one differential area passive radiator within the enclosure system having three separate acoustical coupling surface areas including a small unitary acoustical coupling surface area, a large primary acoustical coupling surface area, and a differential acoustical coupling surface area; d) said first acoustical coupling surface of the said vibratable diaphragm being substantially air coupled through the first chamber to a first of the three separate acoustical coupling surface areas of said at least one differential area passive radiator; and e) second of the three separate acoustical coupling surface areas of said at least one differential area passive radiator acoustically coupled into the second chamber and from said second chamber the third through at least a first opening of predetermined dimensions, f) a third and largest of the three separate acoustical coupling surface areas of said at least one differential area passive radiator acoustically coupled to the external environment, g) said second acoustical coupling surface of the said vibratable diaphragm substantially air coupled into the third chamber.
- 30. The bandpass loudspeaker enclosure system of claim 29 wherein; the at least a first opening of predetermined dimensions is at least a first passive acoustic radiator.
- 31. The bandpass loudspeaker enclosure system of claim 30 wherein said at least a first passive acoustic radiator has a predetermined acoustic resistance.
- 32. The bandpass loudspeaker of claim 29 wherein said first of three separate acoustical coupling surfaces of said differential area passive radiator is the differential surface area of said differential area passive radiator.
- 33. The bandpass loudspeaker of claim 29 wherein said first of three separate acoustical coupling surfaces of said differential area passive radiator is the small unitary surface area of said differential area passive radiator.
Parent Case Info
This application is a continuation-in-part of U.S. Ser. No. 09/260,309, now U.S. Pat. No. 6,169,811 filed on Mar. 2, 1999 and U.S. patent application Ser. No. 09/505,553 filed Feb. 17, 2000.
US Referenced Citations (12)
Foreign Referenced Citations (3)
Number |
Date |
Country |
0 125 625 |
Aug 1984 |
DE |
02260910 |
Sep 1990 |
JP |
PCTUS9820817 |
Oct 1998 |
WO |
Non-Patent Literature Citations (5)
Entry |
“A Bandpass Loudspeaker Enclosure”, L.R. Finchman, Presented at the 634d Convention May 15-18, 1979 Los Angeles. |
“Augmented Passive-Radiator Loudspeaker System, Part 1*”, Thomas L. Clarke. |
“The Acoustic Lever Loudspeaker Enclosure*”, Earl R. Geddes, AES Fellow. |
Speak 32 from GedLee Associates, Copyright 1998. |
“Design of Acoustic Lever Loudspeaker Systems, Part One” Alan A. Phillips, AES 109th Convention, Los Angeles, Sep. 22-26, 2000. |
Continuation in Parts (2)
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Number |
Date |
Country |
Parent |
09/505553 |
Feb 2000 |
US |
Child |
09/753297 |
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US |
Parent |
09/260309 |
Mar 1999 |
US |
Child |
09/505553 |
|
US |