1. Field of the Invention
The present invention relates to audio speaker systems, and, more particularly, to audio speaker systems including acoustic transformers that transform wavefronts of one shape from primary waveguides into another shape for input into sound disseminating secondary waveguides.
2. Description of the Related Art
Typically, a horn-type loudspeaker consists of a driver coupled to an initial throat section. The geometry of the sound-radiating diaphragm of the loudspeaker driver may be a cone, a spherical dome, a flat piston, or an annular ring-radiating diaphragm.
It is well known that the angle of sound radiation of the loudspeaker driver is dependent on the dimensions of the radiating exit relative to the wavelength of sound that is being generated. When the wavelength of sound is large compared to the dimension of the driver exit, the resulting radiation pattern has a wide angle. When the wavelength of sound is small compared to the dimension of the driver exit, the resulting radiation pattern has a narrow angle.
The walls of a horn can only confine the radiation pattern; the walls cannot widen the pattern. If the pattern of sound radiated from driver is wider than the angle of the horn walls, then the sound from the driver will fill the horn and the horn walls will determine the resulting radiation pattern of the horn/driver combination.
On the other hand, if the pattern of sound radiated from driver is narrower that the horn walls, then the sound from the driver will radiate as a narrow beam through the horn and the resulting radiation pattern of the horn/driver combination will be substantially unaffected by the horn walls. In this latter case, where the angle of radiation from the driver exit is narrower than the desired coverage, several techniques have been used in the prior art.
One technique in the prior art to widen the angle of radiation of the driver exit is to pass the sound from the driver exit through an acoustic-transformer/geometry-transition that changes the shape from a round to a rectangular slot, wherein one dimension of the slot is smaller than that of the driver exit. If the smallest dimension of the rectangular slot is smaller than the wavelength of sound, then the radiation angle from the slot will be wide and the horn walls can control the angle of radiation from the horn/driver combination (see U.S. Pat. Nos. 4,187,926 and 4,308,932).
The transformation from round to rectangular can solve the problem in the direction where the slot is smaller than the driver exit. However, problems may still exist in the direction where the direction where the rectangular slot dimension is larger than the driver exit.
Another technique used in the prior art in addition to the rectangular slot is to apply vanes in the throat that spread out the acoustic energy, widening the radiation angle (see U.S. Pat. No. 4,685,532). The vanes are a brute force approach to spreading the pattern out.
In the former case, where the angle of radiation from the driver exit is wider than the desired coverage, the horn walls can control the angle of radiation from the horn/driver combination. However, for very narrow horn/driver radiation angles, the horn can become long enough to create practical problems. Several techniques have been used in the prior art to narrow the coverage angle in a shorter distance. These effectively use an acoustic-transformer/geometry-transition that transforms from the round driver exit to a rectangular slot wherein the wave front has been tailored to be substantially flat, resulting in a narrow radiation pattern. This may be substituted for the first part of the horn, shortening the overall length. These inventions use path way geometries to delay the arrival of the sound at the center of the rectangular slot, making the wave front at the rectangular slot substantially flat (see U.S. Pat. Nos. 5,163,167, 6,581,719 and 6,668,969).
The above describes horn/driver combinations with symmetric radiation angles. However, a horn may be designed to radiate sound energy asymmetrically, directing more energy out the top of the horn and less energy out the bottom. One technique in the prior art to achieve that is to pass the sound from the driver exit through an acoustic-transformer/geometry-transition that changes the shape from round to a tall slot with a semi-trapezoidal shape that is wider at the top than at the bottom. This geometric transition directs more energy towards the top. The trapezoidal-shaped slot is coupled to horn flares to define the radiation angles of the horn/driver combination. (see U.S. Pat. No. 5,020,630).
For substantially curved and substantially flat wavefronts, the prior art addresses the two extremes as independent devices—devices that are applicable for making the radiation pattern from the loudspeaker driver exit much wider, or devices for making the pattern much narrower. The prior art addresses asymmetrical energy distribution with slots of varying widths.
The propagation of sound in a horn may be described by the one-dimensional horn equation:
where the scalar velocity potential, Φ, is described along the x direction, and the cross sectional area of the horn is given by S. The speed of sound c (e.g., the speed of pressure waves) may be defined by:
c
2
=B/ρ
where B is the bulk modulus of a gas (such as air), and ρ is the fluid density of the gas. The acoustic impedance at the throat of a waveguide is determined by the size and shape of the input and output of the device, the expansion function S and the waveguide length. This is a one-dimensional approximation for determining the radiation impedance of an acoustic waveguide. So, for two acoustic paths to have equal impedance they must share the same input and output shape, length, and expansion function.
According to the prior art, when designing waveguides for the purpose of transforming the apparent shape of the source, certain assumptions are made regarding the nature of the source. U.S. Pat. No. 5,163,167, for example, assumes a planar circular isophase wave surface as the excitation for such a waveguide. The term “isophase” means that the sound wave produced would be similar to the sound wave produced by a single piston-like vibrating disk. It can be shown for all electromechanical transducers that there exists a high frequency limit where diaphragm mode shapes and/or acoustic effects produce a non-planar, non-isophase wave front.
What is neither disclosed nor suggested in the art is an acoustic waveguide that does not have the problems and limitations of prior art waveguides as described above.
The present invention addresses the acoustic-transformer/geometry-transition portion in the initial section of a horn. The present invention may utilize a technique that enables the angle of radiation from a loudspeaker driver exit to be tailored to be wider, narrower or any angle in-between. The present invention may use unique sound paths to precisely define the energy distribution, which may be equal or unequal.
The present invention provides an acoustic waveguide that may transform a planar or nonplanar wave at its entrance into a planar wave with uniform power distribution at its exit. The radial divisions near the entrance may be maintained until the annular ring exit. Each of a plurality of acoustic paths from the radial division to the annular ring output may have an equal path length and an equal expansion rate so that the acoustic impedances of all paths from input to output are equal.
A second acoustic waveguide may receive the output of the first waveguide. The second waveguide may transform a circular planar wave at an entrance of the second waveguide into a rectangle planar wave with uniform power distribution at an exit of the second waveguide. The entrance of the second waveguide may be an annular ring divided into several input sections that transform into a rectangular output divided into the same number of output sections. Acoustic channels or paths acoustically interconnecting the input sections with respective ones of the output sections may all have a same expansion rate from input to output yielding equal acoustic impedances. The divided rectangular output may be symmetric in both horizontal and vertical cross sections.
In one embodiment, the invention is directed towards loudspeaker driver/horn combinations, and, more specifically, loudspeaker driver/horn combinations with specific directional behavior. One embodiment of the present invention has an annular ring input orifice, and a curved or planar rectangular output orifice. The input of the device may be coupled directly to an annular ring radiating diaphragm, a compression driver that has an annular ring acoustic output, a cone style transducer, or a pre-conditioning waveguide that transforms the circular exit of a compression driver into an annular ring. The input and output orifices may be connected by four or more discrete paths which are defined by thin wall divisions at the input and output. Practically speaking, the device may be constructed from three pieces, e.g., an upstream housing, a downstream housing, and a central part which includes the vanes or walls that define the acoustic paths between the two housings. These acoustic paths, or “exit paths” of the device may be symmetric in at least one plane that bisects the device. The exit of the device may be affixed to a rectangular horn entrance or may be mounted in a baffle.
The invention comprises, in one form thereof, an acoustic transformer including at least one outer boundary wall, and a plurality of inner walls disposed within the outer boundary wall. The outer boundary wall and the inner walls define a substantially annular input opening divided by at least some of the inner walls into a plurality of circumferentially-spaced input sections. Each of the input sections has an inner circumferential side and an outer circumferential side. A substantially rectangular output opening is divided by at least some of the inner walls into a plurality of output sections. Each of a plurality of acoustic paths interconnects a respective one of the input sections with a respective one of the output sections. Each of the paths has a substantially equal path length and a substantially equal expansion rate.
The invention comprises, in another form thereof, an acoustic transformer, including at least one outer boundary wall, and a plurality of inner walls disposed within the outer boundary wall. The outer boundary wall and the inner walls define a substantially annular input opening divided by at least some of the inner walls into a plurality of circumferentially-spaced input sections. Each of the input sections has an inner circumferential side and an outer circumferential side. A substantially rectangular output opening is divided by at least some of the inner walls into a plurality of rectangular output slots. The slots are arranged in a matrix including a plurality of rows and a plurality of columns. Each of a plurality of air-filled acoustic paths interconnects a respective one of the input sections with a respective one of the output slots. Each of the paths is separated in an air-tight manner from each of the other paths.
The invention comprises, in yet another form thereof, an acoustic transformer including a substantially wedge-shaped core. More particularly, while the overall shape of the core may be wedge-shaped, if the vanes were removed it would reveal several ‘steps’ on the wedge surface. An outer boundary wall is in spaced relationship from each of first and second opposite outer surfaces of the wedge-shaped core. A plurality of inner walls are disposed between each of the first and second opposite outer surfaces of the wedge-shaped core and the outer boundary wall. First ones of the inner walls divide a first space between the first outer surface of the wedge-shaped core and the outer boundary wall into a plurality of first acoustic paths. Second ones of the inner walls divide a second space between the second outer surface of the wedge-shaped core and the outer boundary wall into a plurality of second acoustic paths. Each of the first and second acoustic paths has a substantially equal length and a substantially equal expansion rate.
The invention comprises, in still another form thereof, an acoustic transformation method, including providing a first waveguide having at least one first outer boundary wall. A plurality of first inner walls is disposed within the first outer boundary wall. The first outer boundary wall and the first inner walls define a first input opening divided by at least some of the first inner walls into a plurality of first input sections. A substantially annular first output opening is divided by at least some of the first inner walls into a plurality of arcuately rectangular, circumferentially-spaced first output sections. A first plate surrounds the first output opening. A second waveguide is provided including at least one second outer boundary wall. A plurality of second inner walls is disposed within the second outer boundary wall. The second outer boundary wall and the second inner walls define a substantially annular second input opening divided by at least some of the second inner walls into a plurality of circumferentially-spaced second input sections. A second plate surrounds the second input opening. A substantially rectangular second output opening is divided by at least some of the inner walls into a plurality of second output sections. The first plate is coupled to the second plate such that each of the first output sections is aligned with a respective one of the second input sections, and such that a plurality of acoustic paths are established through the first and second waveguides. Each of the paths interconnects a respective one of the first input sections with a respective one of the second output sections. A sound wave is fed into the first input opening. The sound wave is transformed within the first and second waveguides. The transformed sound wave is received at the second output opening.
The invention comprises, in a further form thereof, an acoustic waveguide including first and second opposite ends. The first end includes a substantially circular annular ring input, and the second end includes a substantially rectangular output. A group of at least four divided passages interconnect the input and the output. The group of passages is symmetric relative to at least one plane.
An advantage of the waveguide of the present invention is that it exploits symmetry.
Another advantage is that the waveguide may operate on a greater variety of excitation waves, and has fewer requirements regarding what kind of excitation wave is acceptable.
Yet another advantage is that the waveguide does not rely on the pressure gradient at the waveguide entrance to be in a direction that is normal to the entrance. A reason for such flexibility is that the division of acoustic paths corrects wave components with non-normal pressure gradients.
The above mentioned and other features and objects of this invention, and the manner of attaining them, will become more apparent and the invention itself will be better understood by reference to the following description of embodiments of the invention taken in conjunction with the accompanying drawings, wherein:
a is a perspective view from the output side of the acoustic waveguide of
b is the view of
a is a sectional view along line 7a-7a in
b is a sectional view along line 7b-7b in
a is an output side view of an acoustic waveguide of the invention that may include the acoustic paths shown in
b is an input side view of the waveguide of
a is an output side view of another embodiment of a waveguide of the invention, similar to
b is an input side view of the waveguide of
a is an output side view of an acoustic waveguide of the invention that may include the unequal acoustic paths shown in
b is an input side view of the waveguide of
a is an output side view of another embodiment of a waveguide of the invention, similar to
b is an input side view of the waveguide of
a is a perspective view diagramming the acoustic paths of another embodiment of an acoustic waveguide having a flat exit, equal path lengths, and unequal exit areas.
b is a perspective view diagramming the acoustic paths of another embodiment of an acoustic waveguide having a flat exit, unequal path lengths, and equal exit areas.
a is a perspective view diagramming the acoustic paths of another embodiment of an acoustic waveguide having a complex curved exit, unequal path lengths, and equal exit areas.
b is a perspective view diagramming the acoustic paths of another embodiment of an acoustic waveguide having a complex curved exit, equal path lengths, and unequal exit areas.
c is a perspective view diagramming the acoustic paths of another embodiment of an acoustic waveguide having a complex curved exit, unequal path lengths, and unequal exit areas.
d is a perspective view diagramming the acoustic paths of another embodiment of an acoustic waveguide having a complex curved exit, equal path lengths, and equal exit areas.
a is a perspective view diagramming the acoustic paths of another embodiment of an acoustic waveguide having a concave exit, unequal path lengths, and equal exit areas.
b is a perspective view diagramming the acoustic paths of another embodiment of an acoustic waveguide having a concave exit, equal path lengths, and equal exit areas.
c is a perspective view diagramming the acoustic paths of another embodiment of an acoustic waveguide having a concave exit, unequal path lengths, and unequal exit areas.
d is a perspective view diagramming the acoustic paths of another embodiment of an acoustic waveguide having a concave exit, equal path lengths, and unequal exit areas.
a is a perspective view diagramming the acoustic paths of another embodiment of an acoustic waveguide having a convex exit, unequal path lengths, and equal exit areas.
b is a perspective view diagramming the acoustic paths of another embodiment of an acoustic waveguide having a convex exit, equal path lengths, and unequal exit areas.
Corresponding reference characters indicate corresponding parts throughout the several views. Although the exemplification set out herein illustrates embodiments of the invention, in several forms, the embodiments disclosed below are not intended to be exhaustive or to be construed as limiting the scope of the invention to the precise forms disclosed.
Referring now to the drawings, and particularly to
Input plate 12 has, and surrounds, a circular divided input 20 in the form of a through hole that extends through input plate 12. The through hole of input 20 is divided by radially-oriented inner walls 22 into eight equally-sized, pie-shaped entrance slots 24. Each of slots 24 leads into a respective one of eight channels 26. Each of channels 26 extends from input plate 12 to a respective one of eight arcuate exit through slots 28 (
The eight arcuate exit through slots 28 may be conjointly referred to as a divided annular ring output 29 of waveguide 10. Annular ring output 29 is divided into eight equally-sized and evenly-spaced sections 28.
Each of channels 26 is partially defined by two adjacent radially-oriented inner walls 22. Each of channels 26 is also partially defined by a respective one of eight substantially triangularly-shaped inner walls 30. Two walls 30 are visible in
A cone 37, best shown in the cross-sectional side view of
Each of channels 26 is further partially defined by a respective substantially trapezoid-shaped section 38 of frusto-conically-shaped outer boundary wall 40. In order to maintain clarity of illustration, only one section 38 is shown in
Frusto-conical outer boundary wall 40 extends from a circular circumference 42 of circular divided input 20 to the radially outward circumferential side 44 (
Being that sections 38 are formed on a frusto-conically-shaped wall 40, each of sections 38 is somewhat arcuate in that it conforms to wall 40. Despite each of sections 38 being somewhat arcuate, each of sections 38 is essentially trapezoidal.
Four trapezoid-shaped ribs 46 extend from input plate 12 to output plate 14 on the outer surface of boundary wall 40. Ribs 46 may provide added structural integrity to waveguide 10.
The present invention may assume that the power distribution of the input waveform is substantially consistent and predominantly symmetric. Regardless of the shape of the wave surface or the direction of the pressure gradient, waveguide 10 may separate the input wave-front into divisions of equal power and may guide the input wave-fronts into a divided annular ring. It has been shown that given a small enough waveguide, regardless of the shape of the input wave, the input wave tends to take the shape of a plane wave as the input wave propagates through the waveguide. Because each channel or path 26 in waveguide 10 may be identical, the path length and expansion functions may also be equal. Thus, from the input to waveguide 10 at input 20, a planar wave radiating annular ring with equal power distribution may be realized at output plate 14.
Cone 37 and boundary wall 40 are shown in
The waveguide may be formed of any rigid molded material, such as metal, plastic, or resin, for example. Shown in
Acoustic transformer 10 includes an outer boundary wall 40, and inner walls 22, 37 disposed within outer boundary wall 40. Inner wall 37 is conically-shaped, and is divided into eight equally-sized and evenly-spaced triangular walls 30 around its circumference. Circular input plate 12 includes a through hole that serves as an input opening divided by inner walls 22 into a plurality of input sections 24. The input sections 24 conjointly form a circular divided input 20.
Circular output plate 14 includes, and surrounds, an annular output opening that is divided by inner walls 22 into a plurality of circumferentially-spaced output sections 28 that conjointly form a divided annular ring output 29. Each of output sections 28 has an inner circumferential side 30c and an outer circumferential side 38c, 44.
Each of eight acoustic paths 26 interconnects a respective one of input sections 24 with a respective one of the output sections 28. Each of the paths 26 has an equal path length and an equal expansion rate. The term “expansion rate” may indicate the rate at which the cross-sectional area of a path 26 increases from input plate 12 to output plate 14. Although each of the paths 26 has an equal expansion rate, the rate of expansion of the cross-sectional area of an individual path 26 may be different at different points along the progression of the path 26 from input plate 12 to output plate 14.
Outer boundary wall 40 and inner wall 37 define a circular input opening 20 divided by inner walls 22 into a plurality of pie-shaped sections 24. Annular output opening 29 is divided by inner walls 22 into a plurality of circumferentially-spaced output sections 28. Each of a plurality of air-filled acoustic paths 26 interconnects a respective one of the input sections 24 with a respective one of the output sections 28. Each of paths 26 may be separated in an air-tight manner from each of the other paths 26. That is, fluid (e.g., air) or sound waves may not be able to transfer from one channel 26 to another channel 26 between circular divided input 20 and divided annular ring output 29.
Frusto-conically-shaped outer boundary wall 40 is in spaced relationship with an outer surface of a cone-shaped core 37. Inner walls 22 are disposed between and interconnect the cone-shaped core and the outer boundary wall. Inner walls 22 divide a space between cone-shaped core 37 and outer boundary wall 40 into a plurality of acoustic paths 26. Each of paths 26 has a substantially equal length such that sound waves may travel an equal distance through any of paths 26 between an input and an output of waveguide 10. Each of paths 26 may have a substantially equal expansion rate such that a first derivative of the cross-sectional area of each path 26 as a function of the position along the length of the path is equal at each position along the length of the path. Further, a second derivative of the cross-sectional area of each path 26 may also be equal at any point along the length of the path.
In
Circular input plate 112 includes and surrounds an annular input opening that extends through input plate 112. The annular input opening is divided by inner walls 122 into a plurality of circumferentially-spaced and equally-sized input sections 124 that conjointly form a divided annular ring input 120. Each of the eight arcuate input sections 124 has an inner circumferential side 130c and an outer circumferential side 138c.
Each of the eight input sections 124 leads into a respective one of eight channels 126. Each of channels 126 extends from input plate 112 to a respective one of eight rectangular exit through slots 128 (
The eight rectangular exit through slots 128 may be conjointly referred to as a divided rectangular output 129 of waveguide 110. Rectangular output 129 is divided into eight equally-sized and evenly-spaced slots 128 arranged in a matrix. In this particular embodiment, the matrix includes two rows and four columns of slots 128.
Each of channels 126 is partially defined by two adjacent inner walls 122. Walls 122 are radially-oriented at plate 112, and are oriented in a same direction at plate 114. This same direction of orientation is in substantially vertical directions 131 with respect to the viewing angle of
A core 137, which has a substantially triangular cross section in the view of
Each of channels 126 is further partially defined by a respective substantially rectangular outer wall 138 that is on an inner surface of an outer boundary wall 140. Each of the eight rectangular walls 138 has two opposite sides 145 (
Outer boundary wall 140 extends from the radially outward circumferential side 144 (
Being that walls 138 are formed on an arcuate and twisting outer wall 140, each of walls 138 is somewhat arcuate and twisting in that it conforms to outer wall 140. Despite each of walls 138 being somewhat arcuate and twisting, each of walls 138 is essentially rectangular.
A plurality of trapezoid-shaped ribs 146 extend from input plate 112 to output plate 114 on the outer surface of boundary wall 140. Ribs 146 may provide added structural integrity to waveguide 110.
Core 137 and boundary wall 140 are shown in
As best shown in
Waveguide 110 may be formed of any rigid molded material, such as metal, plastic, or resin, for example. Shown in
Acoustic transformer 110 includes an outer boundary wall 140, and inner walls 122, 137 disposed within outer boundary wall 140. Inner wall 137 is substantially wedge-shaped, and its opposite faces are divided into eight evenly-spaced, substantially rectangular walls 130. Circular input plate 112 includes an annular through hole that serves as an input opening divided by inner walls 122 into a plurality of input sections 124. The input sections 124 conjointly form an annular divided input 120.
Rectangular output plate 114 includes and surrounds a divided rectangular output opening that is divided by inner walls 122 into two rows of four rectangular output sections 126 that conjointly form a divided rectangular output 129. Each of output sections 126 has a linear inner 130d and a linear outer side 138d.
Each of eight acoustic paths 126 interconnects a respective one of input sections 124 with a respective one of the output slots 128. In one embodiment, each of the paths 126 has a substantially equal path length and a substantially equal expansion rate. The term “expansion rate” may indicate the rate at which the cross-sectional area of a path 126 increases from input plate 112 to output plate 114. Although each of the paths 126 may have an equal expansion rate, the rate of expansion of the cross-sectional area of an individual path 126 may still be different at different points along the progression of the path 126 from input plate 112 to output plate 114.
Outer boundary wall 140 and inner wall 137 define an annular input opening 120 divided by inner walls 122 into a plurality of arcuately rectangular sections 124. Rectangular output opening 129 is divided by inner walls 122 into a plurality of evenly-spaced, rectangular output slots 128. Each of a plurality of air-filled acoustic paths 126 interconnects a respective one of the input sections 124 with a respective one of the output slots 128. Each of paths 126 may be separated in an air-tight manner from each of the other paths 126. That is, fluid (e.g., air) or sound waves may not be able to transfer from one channel 126 to another channel 126 between divided annular input 120 and divided rectangular output 129.
Outer boundary wall 140 is in spaced relationship with an outer surface of a wedge-shaped core 137. Inner walls 122 are disposed between and interconnect the wedge-shaped core and the outer boundary wall. Inner walls 122 divide a space between wedge-shaped core 137 and outer boundary wall 140 into a plurality of acoustic paths 126. Each of paths 126 may have a substantially equal length such that sound waves may travel a substantially equal distance through any of paths 126 between an input and an output of waveguide 110. Each of paths 126 may have a substantially equal expansion rate such that a first derivative of the cross-sectional area of each path 126 as a function of the position along the length of the path is equal at each position along the length of the path. Further, a second derivative of the cross-sectional area of each path 126 may also be equal at any point along the length of the path.
As shown in
As further shown in
As described above, waveguide 110 further terminates in a horizontally and vertically symmetric rectangular exit 129. Divided paths 126 may be constructed to have equal path lengths and equal expansion rates (and thus equal volume) on a single quadrant of waveguide 110. The quadrant geometry may be mirrored in the horizontal and vertical construction planes, as may be observed from
Although input 120 of waveguide 110 is shown in
Acoustic paths 26 and 126 of waveguides 10 and 110 are described herein as possibly having equal rates of expansion. It is to be understood that where the term “rate of expansion” or similar language is used herein, the term encompasses the possibility that the rate of expansion is negative relative to a direction from the input toward the output. That is, the equal expansion rates of the acoustic paths may be negative. Stated differently, the acoustic paths may have equal rates of contraction.
One embodiment of an acoustic transformation method 1100 of the present invention is illustrated in
In a next step 1104, a second waveguide is provided including at least one second outer boundary wall. A plurality of second inner walls is disposed within the second outer boundary wall. The second outer boundary wall and the second inner walls define a substantially annular second input opening divided by at least some of the second inner walls into a plurality of circumferentially-spaced second input sections. A second plate surrounds the second input opening. A substantially rectangular second output opening is divided by at least some of the inner walls into a plurality of second output sections. For instance, waveguide 110 includes inner walls 122, 130 disposed within outer boundary wall 140. Outer boundary wall 140 and inner walls 130 define annular input opening 120, which is divided by inner walls 122 into circumferentially-spaced input sections 124. Plate 112 surrounds input opening 120. A rectangular output opening 129 is divided by inner walls 122 into output sections 128.
Next, in step 1106, the first plate is coupled to the second plate such that each of the first output sections is aligned with a respective one of the second input sections, and such that a plurality of acoustic paths are established through the first and second waveguides, each of the paths interconnecting a respective one of the first input sections with a respective one of the second output sections. For example, as shown in
In a next step 1108, a sound wave is fed into the first input opening. That is, as shown in
In step 1110, the sound wave is transformed within the first and second waveguides. For instance, a planar or non-planar sound wave fed into input opening 20 by loudspeaker 48 may be transformed within waveguide 10 into a planar, annular wave with uniform power distribution at output opening 29. Within waveguide 110, the planar, annular wave may be further transformed into a planar, rectangular wave with uniform power distribution at output opening 129.
In a final step 1112, the transformed sound wave is received at the second output opening. For example, as shown in
Waveguides 10 and 110 are shown as each having eight separate acoustic paths. However, it is to be understood that a waveguide of the invention can have a number of acoustic paths other than eight. For example, in
The four arcuate exit through slots 228 may be conjointly referred to as a divided annular ring output 229 of waveguide 210. Annular ring output 229 is divided into four equally-sized and evenly-spaced sections 228.
Each of channels 226 is partially defined by two adjacent radially-oriented inner walls 222. Each of channels 226 is also partially defined by a respective one of four substantially triangularly-shaped inner walls 230. Only one wall 230 is visible in
Each of channels 226 is further partially defined by a respective substantially trapezoid-shaped section 238 of frusto-conically-shaped outer boundary wall 240. Wall 240 includes the four trapezoid-shaped sections 238 separated from each other by narrow strips at which radial walls 222 engage wall 240. Other features of waveguide 210 are substantially similar to those of waveguide 10, and thus are not described herein in order to avoid needless repetition.
In
Each of the four input sections 324 leads into a respective one of four channels 326. Each of channels 326 extends from input 320 to a respective one of four rectangular exit through slots 328 (
The four rectangular exit through slots 328 may be conjointly referred to as a divided rectangular output 329 of waveguide 310. Rectangular output 329 is divided into four equally-sized and evenly-spaced slots 328 arranged in a matrix of two rows and two columns.
Each of channels 326 is partially defined by two adjacent inner walls 322. Walls 322 are radially-oriented at input 320, and are oriented in a same direction at output 329. Each of channels 326 is also partially defined by a respective one of four twistingly rectangular inner walls 330. Each of channels 326 is further partially defined by a respective substantially rectangular outer wall 338 that is on an inner surface of an outer boundary wall 340. Other features of waveguide 310 are substantially similar to those of waveguide 110, and thus are not described herein in order to avoid needless repetition. The output of waveguide 210 may be mated to the input of waveguide 310, just as the output of waveguide 10 is mated to the input of waveguide 110 in
In the embodiments of
The four rectangular exit through slots 428 may be conjointly referred to as a divided rectangular output 429 of waveguide 410. Rectangular output 429 is divided into four equally-sized and evenly-spaced slots 428 arranged in a matrix of two rows and two columns.
Each of channels 426 is partially defined by two adjacent inner walls 422. Walls 422 are radially-oriented at input 420, and are oriented in a same direction at output 429. Each of channels 426 is also partially defined by a respective one of four twistingly triangular inner walls 430. Each of channels 426 is further partially defined by a respective substantially rectangular outer wall 438 that is on an inner surface of an outer boundary wall 440. Other features of waveguide 410 are substantially similar to those of waveguides 210 and 310, and thus are not described herein in order to avoid needless repetition.
As insured by the symmetry of waveguide 410, each of the four acoustic paths 426 has an equal rate of expansion as well as an equal acoustic impedance.
Illustrated in
In the alternative embodiment of
Driver 600 may include U-shaped terminals 610 through which electrical inputs to a voice coil (not shown) within a magnetic gap (not shown) may be entered. Driver 600 may further include a frusto-spherical phase plug entrance 612 disposed closely adjacent and parallel to a frusto-spherical titanium dome 614.
In general, the waveguide of the invention may be able to transform a substantially time coherent wavefront of even power distribution at the annular input into a variety of wavefronts at the device output. Segmenting or isolating the acoustic passages that link or interconnect the input and output may serve to restrict the acoustic wave from propagating along any path other than the path that it is intended to propagate along. The parameters An, Bn, ln, and Zn may be individually selected for each path to thereby create convex, concave or planar exit wavefront geometries in one plane while acoustic pressure gradient symmetry is maintained in another plane.
A particularly useful application for the invention may be in the field of arrayable loudspeaker systems wherein a planar wave exiting wavefront is required. The present invention may achieve this condition by setting An, Bn, ln and Zn equal for every path. This may produce, at the waveguide output, a planar wave with symmetric pressure gradients in the horizontal plane and line source behavior in the vertical plane.
In another embodiment, input area An and output area Bn may also be varied to produce a source of varying intensity. This may be accomplished by having all input areas An's equal but having the output areas Bn's unequal so that the acoustic power is evenly divided at the entrance, but unevenly dispersed at the exit. Conversely, the input areas An's could be unequal and the output areas Bn's unequal. This technique may of course mean that different expansion functions are implemented for each path. A variety of mathematically useful source shapes may be realized in this way.
As can be seen in
Illustrated in
Illustrated in
Illustrated in
Illustrated in
As can be seen in
As shown in
A limited number of embodiments of the waveguide of the invention have been illustrated and described herein. However, it is to be understood that the invention encompasses a myriad of source geometries which may be tailored to a variety of desired acoustic coverage patterns. Further, all of these variations in input and output geometries are realizable by virtue of the present invention.
A specific embodiment of the present invention may provide an acoustic wave guide including a substantially circular annular ring input at one end and a substantially rectangular output at the other end. There may exist four or more divided passages or paths which are symmetric in at least one plane. The passages may interconnect the input of the device to the output of the device for the purpose of transforming the shape of an acoustic wave from the input to the output. That is, the acoustic wave may be transformed to have a desired geometry and energy distribution.
The invention may encompasses varied combinations of elements including: a wave front of any shape at the exit; a flat exit with paths of equal lengths and equal areas; a flat exit with paths of unequal lengths, but equal areas; a flat exit with paths of unequal lengths and unequal areas; a flat exit with paths of equal lengths, but unequal areas; a convex curved exit with equal lengths and equal areas; a convex curved exit with paths of unequal lengths, but equal areas; a convex curved exit with paths of unequal lengths and unequal areas; a convex exit with paths of equal lengths, but unequal areas; a concave curved exit with paths of equal lengths and equal areas; a concave curved exit with paths of unequal lengths, but equal areas; a concave curved exit with paths of unequal lengths and unequal areas; a concave exit with paths of equal lengths, but unequal areas; a complex asymmetric curved exit with paths of equal lengths and equal areas; a complex asymmetric curved exit with paths of unequal lengths, but equal areas; a complex asymmetric curved exit with paths of unequal lengths and unequal areas; and/or a complex asymmetric exit with paths of equal lengths, but unequal areas.
As described herein, a first waveguide and a second waveguide (e.g., waveguides 10 and 110) may be coupled together in series. However, it is to be understood that the second waveguide does not necessarily need to receive input from a first waveguide. That is, the second waveguide may be operable within the scope of the invention with and without a first waveguide providing inputs for the second waveguide. The second waveguide may receive inputs from a source other than another waveguide.
While this invention has been described as having an exemplary design, the present invention may be further modified within the spirit and scope of this disclosure. This application is therefore intended to cover any variations, uses, or adaptations of the invention using its general principles.
The present application is a continuation of co-pending U.S. patent application Ser. No. 12/850,000, filed Aug. 4, 2010, now U.S. Pat. No. ______, the entire content of which is hereby incorporated by reference.
Number | Date | Country | |
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Parent | 12850000 | Aug 2010 | US |
Child | 14291406 | US |