Information
-
Patent Grant
-
6363157
-
Patent Number
6,363,157
-
Date Filed
Thursday, August 28, 199727 years ago
-
Date Issued
Tuesday, March 26, 200222 years ago
-
Inventors
-
Original Assignees
-
Examiners
Agents
-
CPC
-
US Classifications
Field of Search
US
- 381 89
- 381 337
- 381 338
- 381 339
- 381 345
- 381 346
- 381 347
- 381 348
- 381 349
- 381 99
- 381 98
- 181 199
-
International Classifications
-
Abstract
A loudspeaker system includes an enclosure supporting first and second loudspeaker driver assemblies and having an internal volume. At least the first loudspeaker driver assembly is constructed and arranged to radiate sound energy into the listening region outside the enclosure over at least the range of audio frequencies above a predetermined first frequency. The second loudspeaker driver assembly is constructed and arranged to radiate sound energy over a first predetermined range of audio frequencies embracing at least a range of audio frequencies below a second frequency above the first frequency. The first loudspeaker driver assembly, the second loudspeaker driver assembly and the enclosure are constructed and arranged to coact to maintain the pressure in the enclosure substantially constant over at least the range of frequencies between the first and second frequencies.
Description
The invention relates to multiple element electroacoustic transducing.
For background reference is made to U.S. Pat. No. 4,008,374.
It is an important object of the invention to provide an improved multiple element electroacoustic transducer.
According to the invention, there is an enclosure supporting a first loudspeaker driver assembly and a second loudspeaker driver assembly and having an internal volume. At least the first loudspeaker driver assembly is constructed and arranged to radiate sound energy into the listening region outside the enclosure over a first range of audio frequencies above a predetermined first frequency and a predetermined second frequency higher than the first frequency. The second loudspeaker driver assembly is constructed and arranged to radiate sound energy over a first predetermined range of audio frequencies embracing at least the range of audio frequencies between the first frequency and the second frequency. The first loudspeaker driver assembly, the second loudspeaker driver assembly and the enclosure are constructed and arranged to coact to maintain the pressure in the enclosure substantially constant over at least the range of frequencies between the first and second frequencies. The first predetermined range of audio frequencies may be substantially the full audio frequency range, or may correspond substantially to the bass frequency range. There may be an audio signal input and a low-pass filter coupling the audio signal input to the second loudspeaker driver assembly, and a high-pass filter coupling the audio signal input to the first loudspeaker driver assembly. The first loudspeaker driver assembly may comprise a number of loudspeaker drivers. There may be an audio signal input including a plurality of input channels coupled to respective ones of the loudspeaker drivers, and a summer coupling the input channels to the second loudspeaker driver assembly. The enclosure may include first and second ports coupling the first and second loudspeaker driver assembly to the listening region outside the enclosure.
The second loudspeaker driver assembly may be constructed and arranged to radiate to the listening region outside the enclosure through an acoustic impedance, such as an acoustic waveguide or port, or be coupled to an enclosed chamber.
In a specific form of the invention, the acoustic impedance may be an acoustic waveguide having one end closed and the other end open. In a specific form, the second loudspeaker driver assembly may be mounted such that the distance from the loudspeaker assembly to the open end is about twice the distance to the closed end. In another specific form, the acoustic impedance may be a ported or unported chamber.
According to a specific form of the invention the first loudspeaker assembly may have more loudspeaker drivers than the second loudspeaker assembly, and both assemblies may be limited to operating over the same bass frequency range.
Other features, objects and advantages will become apparent from the following detailed description which refers to the following drawings in which:
FIG. 1
is a combined block diagram and diagrammatic view partially in section of an electroacoustical transducing system according to the invention;
FIG. 2
is a combined block diagram and diagrammatic view partially in section of another electroacoustical transducing system according to the invention;
FIGS. 3
a
and
3
b
are combined block diagrams and diagrammatic views partially in section of another electroacoustical transducing system according to the invention;
FIG. 4
is a combined block diagram and diagrammatic view partially in section of another electroacoustical transducing system according to the invention; and
FIG. 5
is a pictorial partially cutaway perspective view of another embodiment of the invention with multiple ported drivers.
Similar reference symbols identify corresponding elements throughout the drawings.
Referring to the drawings and more particularly to
FIG. 1
, there is shown an electroacoustical transducing system
38
according to the invention. A housing
12
with enclosure
25
supports first loudspeaker driver
14
and second loudspeaker driver
16
having cones
1
,
5
, respectively. First loudspeaker driver
14
has a cone
1
with outside and inside surfaces
2
and
4
, respectively. An optional high-pass filter
24
couples audio signal input terminal
20
to first loudspeaker driver
14
.
Second loudspeaker driver
16
has a cone
5
with outside and inside surfaces
6
and
8
, respectively. Outside surface
6
faces acoustic waveguide
18
intermediate the waveguide closed and open ends. A low-pass filter
22
couples audio signal input terminal
20
to second loudspeaker driver
16
. First loudspeaker driver
14
and second loudspeaker driver
16
operate over a common range of frequencies where the wavelength is significantly larger than a linear dimension, such as height, width or length of enclosure
25
so that the compliance of enclosure
25
is very low.
First and second loudspeaker drivers
14
,
16
may be identical, or second loudspeaker
16
may be a woofer for operating over the bass frequency range. Second loudspeaker driver
16
may be mounted in an opening in waveguide
18
such that the distance to the open end is about twice the distance to the closed end, or at some other location, such as at the closed end. Waveguide
18
may be replaced by a different acoustic impedance, such as an unported, singly ported or multiply ported volume, or an acoustic waveguide open at both ends. Waveguide
18
may be straight with parallel walls as shown or may assume a variety of different configurations, such as folded, tapered at the closed end, tapered along a portion of its length or along substantially its entire length.
First and second loudspeaker drivers
14
,
16
are constructed and arranged so that in the common frequency range over which they operate, at least at low audio frequencies, they operate in push-pull to maintain substantially constant pressure in enclosure
25
in this common frequency range. The common frequency range may extend over the full audio frequency range.
In an exemplary embodiment, first loudspeaker driver
14
radiates sound energy directly into the listening region at least including the common frequency range and the audio frequency range above the common frequency range when the common frequency range is less than the full audio frequency range while second loudspeaker driver
16
radiates low frequency energy through the open end of waveguide
18
dimensioned to efficiently transfer low frequency energy from second loudspeaker driver
16
to the listening region outside the enclosure, incorporating the principles of the waveguide speaker disclosed in U.S. Pat. No. 4,628,528 incorporated by reference herein.
This embodiment of the invention furnishes efficient operation over substantially the full range of audio frequencies. At bass frequencies, for example, below 100 Hz, typically in the common frequency range, requiring substantial air movement to produce loud sound levels, first and second loudspeaker drivers
14
and
16
operating push-pull to maintain the pressure in enclosure
15
substantially constant, helping to thereby overcome the low compliance (or high resistance) of the relatively small volume in enclosure
25
. Acoustic waveguide
18
further enhances the efficiency of energy transfer between second loudspeaker driver
16
and the listening region outside the enclosure. At higher audio frequencies, first loudspeaker driver
14
radiates the sound energy, thereby using less power than if both first and second loudspeaker drivers
14
and
16
were radiating.
The parameters of optional high-pass filter
24
may be set to balance the power drawn by first and second loudspeaker driver
14
and
16
so that they may be driven by power amplifiers of substantially similar capacity or by a single amplifier through suitable crossover networks. It may also be desirable to protect the loudspeaker drivers from low frequency, high amplitude noise, such as by including a filter with a sharp cutoff below a predetermined low audio frequency. In embodiments without power balancing or protection from low frequency, high amplitude noise, optional high-pass filter
24
may be omitted.
If second loudspeaker driver
16
is a woofer with high frequency roll-off, low-pass filter
22
may be omitted in applications without power balancing.
It may be advantageous to use a full-range driver for first loudspeaker driver
14
and a bass driver or woofer for second loudspeaker driver
16
.
Referring to
FIG. 2
, there is shown a second embodiment of the invention having three loudspeaker drivers
14
′ corresponding to first loudspeaker driver
14
in the system of FIG.
1
. Loudspeaker drivers
14
′ may be identical and have a combined cone area approximately equal to that of second loudspeaker driver
16
. Loudspeaker drivers
14
′ may be arranged to form an array creating a desired sound field pattern. This embodiment has a number of advantages because the smaller drivers
14
′ coact with the second loudspeaker driver
16
at bass frequencies to provide considerable radiating area, and at higher frequencies operate more efficiently with less mass.
Referring to
FIG. 3
a,
there is shown another embodiment of the invention having the three loudspeaker drivers
14
L,
14
C and
14
R corresponding to first loudspeaker driver
14
in
FIG. 1
separately so that each can receive a different signal, such as left, center and right channel signals, respectively, of a stereo or surround signal.
Referring to
FIG. 3
b,
there is shown a modification of the embodiment of
FIG. 3
a.
In this embodiment, power amplifiers
23
couple the signals from audio signal input terminal
22
to the respective loudspeaker drivers
14
L,
14
C and
14
R. Summer
29
, low-pass filter
22
and amplifier
27
also couple the audio channels to second loudspeaker driver
16
.
Referring to
FIG. 4
, there is shown still another embodiment of this invention omitting the optional low-pass and high-pass filters
22
and
24
of
FIGS. 1
,
2
,
3
a
and
3
b.
Audio signal input terminal
20
′ may provide amplified audio signals to loudspeaker drivers
14
a,
14
b,
14
c,
14
d
and
14
e.
Front loudspeaker driver
14
a,
14
b
and
14
c
each have inside and outside cone surfaces
4
′ and
2
′. Transducers
14
a,
14
b
and
14
c
may face in different directions to provide a desired sound field pattern. Rear transducers
14
d
and
14
e
each have inside and outside surfaces
6
′ and
8
′, respectively, for radiating into acoustic enclosure
18
′, which includes subchamber
30
and a port
32
. Transducers
14
a,
14
b,
14
c,
14
d,
and
14
e
may be selected such that the combined radiating surfaces of the drivers (in this embodiment
14
a,
14
b
and
14
c
) radiate sound directly into the listening region have a combined area approximately equal to the combined radiating surfaces of transducer
14
d
and
14
e
that radiate to the listening region outside the enclosure through subchamber
30
and port
32
. Alternatively, port
32
may be covered by cover
32
′ (shown in broken lines) so that subchamber
30
is a closed volume that is an impedance coupled to transducers
14
d
and
14
e.
Referring to
FIG. 5
, there is shown a pictorial partially cutaway perspective view of another embodiment of the invention in which front loudspeaker drivers
14
′ and rear loudspeaker drivers
16
′ are ported through ports
32
′ and
32
″ and each operate over substantially the full audio frequency range.
Other embodiments are within the claims.
Claims
- 1. A loudspeaker system comprising,a first loudspeaker driver assembly, a second loudspeaker driver assembly, an enclosure supporting said first and second loudspeaker driver assemblies and having an internal volume, at least said first loudspeaker driver assembly constructed and arranged to radiate sound energy directly into the listening region outside said enclosure over substantially the full range of audio frequencies, an acoustic impedance coupling at least said second loudspeaker driver assembly to the listening region outside said enclosure to radiate sound energy over a first predetermined range of audio frequencies embracing a bass portion of said full range of audio frequencies, said first loudspeaker driver assembly, said second loudspeaker driver assembly and said enclosure constructed and arranged to coact to maintain the pressure in said enclosure substantially constant over said bass portion.
- 2. A loudspeaker system in accordance with claim 1 and further comprising,an audio signal input and a low-pass filter coupling said audio signal input to said second loudspeaker driver assembly.
- 3. A loudspeaker system in accordance with claim 1 and further comprising,an audio signal input and a high-pass filter coupling said audio signal input to said first loudspeaker driver assembly.
- 4. A loudspeaker system in accordance with claim 1 wherein said acoustic impedance comprises an acoustic waveguide with ends having at least one end open.
- 5. A loudspeaker system in accordance with claim 4 wherein the other of the ends of said waveguide is closed.
- 6. A loudspeaker system in accordance with claim 5 wherein said second loudspeaker driver assembly is mounted in an opening of said acoustic waveguide such that the distance between said opening and the open end is approximately twice the distance between said opening and said closed end.
- 7. A loudspeaker system in accordance with claim 1 wherein said first loudspeaker driver assembly comprises a plurality of loudspeaker drivers.
- 8. A loudspeaker system in accordance with claim 7 and further comprising,an audio signal input including a plurality of input channels coupled to respective ones of said loudspeaker drivers.
- 9. A loudspeaker system in accordance with claim 8 and further comprising,a summer coupling said input channels to said second loudspeaker driver assembly.
- 10. A loudspeaker system in accordance with claim 1 wherein said acoustic impedance comprises a ported volume.
- 11. A loudspeaker system in accordance with claim 1 wherein said first loudspeaker driver assembly and said second loudspeaker driver assembly are constructed and arranged to radiate sound energy directly into the listening region outside said enclosure over substantially the full range of audio frequencies.
- 12. A loudspeaker system in accordance with claim 11 wherein said enclosure includes first and second ports coupling said first and second loudspeaker driver assemblies to the listening region outside said enclosure.
- 13. A loudspeaker system comprising,a first loudspeaker driver assembly, a second loudspeaker driver assembly, an enclosure supporting said first and second loudspeaker driver assemblies and having an internal volume, at least said first loudspeaker driver assembly constructed and arranged to radiate sound energy into the listening region outside said enclosure over at least the range of audio frequencies above a predetermined first frequency and a predetermined second frequency higher than said first frequency, said second loudspeaker driver assembly constructed and arranged to radiate sound energy over a first predetermined range of audio frequencies embracing at least the range of audio frequencies between said first frequency and said second frequency, said first loudspeaker driver assembly, said second loudspeaker driver assembly and said enclosure constructed and arranged to coact to maintain the pressure in said enclosure substantially constant over at least the range of frequencies between said first and second frequencies.
- 14. A loudspeaker system in accordance with claim 13 wherein said first predetermined range of audio frequencies is substantially the full audio frequency range.
- 15. A loudspeaker system in accordance with claim 13 wherein said first predetermined range of audio frequencies corresponds substantially to the bass frequency range.
- 16. A loudspeaker system in accordance with claim 13 and further comprising,an audio signal input and a low-pass filter coupling said audio signal input to said second loudspeaker driver assembly.
- 17. A loudspeaker system in accordance with claim 13 and further comprising,an audio signal input and a high-pass filter coupling said audio signal input to said first loudspeaker driver assembly.
- 18. A loudspeaker system in accordance with claim 13 wherein said first loudspeaker driver assembly comprises a plurality of loudspeaker drivers.
- 19. A loudspeaker system in accordance with claim 18 and further comprising,an audio signal input including a plurality of input channels coupled to respective ones of said loudspeaker drivers.
- 20. A loudspeaker system in accordance with claim 19 and further comprising,a summer coupling said input channels to said second loudspeaker driver assembly.
- 21. A loudspeaker system in accordance with claim 13 wherein said first loudspeaker driver assembly and said second loudspeaker driver assembly are constructed and arranged to radiate sound energy into the listening region outside said enclosure over substantially the full range of audio frequencies.
- 22. A loudspeaker system in accordance with claim 21 wherein said enclosure includes port structure coupling said first and second loudspeaker driver assemblies to the listening region outside said enclosure.
- 23. A loudspeaker system comprising,a first loudspeaker driver assembly, a second loudspeaker driver assembly operative over a first predetermined range of audio frequencies embracing a bass portion of the full range of audio frequencies, an enclosure supporting said first and second loudspeaker driver assemblies and having an internal volume, at least said first loudspeaker driver assembly constructed and arranged to radiate sound energy directly into the listening region outside said enclosure over substantially the full range of audio frequencies, an acoustic impedance coupled to said second loudspeaker driver assembly and separated from said internal volume by said second loudspeaker driver assembly and formed with an opening for radiating sound energy into the listening region outside said enclosure over said bass portion, said first loudspeaker driver assembly, said second loudspeaker driver assembly and said enclosure constructed and arranged to coact to maintain the pressure in said enclosure substantially constant over said bass portion.
- 24. A loudspeaker assembly comprising,a first loudspeaker driver assembly, a second loudspeaker driver assembly, an enclosure supporting said first and second loudspeaker driver assemblies and having an internal volume, said first loudspeaker driver assembly having a different number of loudspeaker drivers than said second loudspeaker driver assembly, said first loudspeaker driver assembly, said second loudspeaker driver assembly and said enclosure constructed and arranged to coact to maintain the pressure in said enclosure substantially constant over the bass frequency range.
US Referenced Citations (9)
Foreign Referenced Citations (1)
Number |
Date |
Country |
2505-125 |
Nov 1982 |
FR |