This application relates to acoustic waveguides for speakers.
Many audio speaker systems include multiple speaker drivers that are each responsible for producing sounds in specific frequency ranges. For example, conventional speaker systems often include one or more woofers having a speaker driver designed to produce low-frequency sounds (i.e., approximately 20 Hz-250 Hz), one or more midrange drivers designed to produce midrange sounds (i.e., approximately 250 Hz-2 kHz), and one or more tweeters having speaker drivers designed to produce high-frequency sounds (i.e., approximately 2 kHz-20 kHz). In these speaker systems, the woofers, midranges, and tweeters may each be housed in individual speaker housings. Separating the speaker drivers into individual speaker housings, however, can be detrimental to the uniformity and quality of sound received at a given location due to the different positions of the individual speakers. For example, muddy sound localization and poor dialog intelligibility can also result due to the smearing of sound across multiple speakers. In addition, two or more sound sources spaced apart from each other and playing at the same frequency can cause a phenomenon called lobing to occur. Lobing occurs when the sound waves from two or more sound sources cancel each other out at some off-axis locations and reinforce at others, resulting in the degradation of the sound at some off-axis listening positions.
Other speaker systems include multiple speaker drivers in a single speaker housing. In these systems, the speaker drivers can be coupled to horn structures and/or waveguides positioned adjacent to each other within the single speaker housing. This configuration with the speaker drivers positioned near each other can provide a combined sound at a given location having better uniformity than in the speaker systems having speaker drivers in different housings. The speaker drivers, however, are still separated from each other and the separation can lead to a sub-optimal wave summation of the sounds emitted by the individual drivers, which may provide a non-coherent wave front at the device output.
Acoustic waveguides have been developed to provide improved sound distribution from selected drivers. Examples of such improved waveguides include the waveguides and associated technology set forth in U.S. Pat. Nos. 7,177,437, 7,953,238, 8,718,310, 8,824,717, and 9,204,212, each of which is incorporated herein in its entirety by reference thereto. These waveguides are configured to work with a single high frequency driver and are therefore limited in their operating bandwidth. It would be desirable to provide a waveguide that emits across an extended frequency range using one or more high-frequency drivers and one or more midrange drivers. The inventors of the present technology, however, have discovered substantive improvements to the conventional waveguide technologies to provide these and other benefits.
The present technology is directed to an acoustic waveguide for a speaker assembly and associated systems. Several embodiments of the present technology are related to acoustic waveguides coupled to midrange and high-frequency speaker drivers and that include midrange and high-frequency sound channels configured to direct the sound waves produced by the speaker drivers out of a front surface of the waveguide. Specific details of the present technology are described herein with respect to
The illustrated waveguide 6 includes a housing 8 coupled to first and second speaker drivers, which may be a midrange driver 10 and a high-frequency driver 12. The midrange and high-frequency drivers 10 and 12 are configured to receive source signals from one or more source signal generator 5 (
As seen in
The illustrated housing 8 includes rear and top driver mounting portions 24 and 22. The rear driver mounting portion 24 has a mounting flange 25 surrounding an inlet aperture 40 acoustically coupled to a plurality of spaced apart high-frequency sound channels 30 extending through the housing 8. The high-frequency driver 12 removably attaches to the mounting flange 25 so the high-frequency driver 12 is substantially axially aligned with the inlet aperture 40. The top driver mounting portion 22 removably receives the midrange driver 10 (
The size, shape, and position of the individual sound input portions 28a-e may be dependent on the size, shape, and position of the sound ports 38a-e within the housing 8. In the illustrated embodiment each sound input portions 28a-e is aligned with a respective one of the sound ports 38a-e to ensure that the sound emitted by the midrange driver 10 is directed through sound ports 38a-e. In some embodiments, such as the embodiment shown in
As seen in
In the illustrated embodiment, the midrange driver 10 is mounted to the housing's top surface such that the midrange driver 10 is not axially aligned with the housing 8. The mid-frequency sound enters the housing 8 through the sound input portions 28a-e and sound ports 38a-e generally normal to the housing's longitudinal axis, and changes direction as the sound enters the midrange sound paths 34a-e to move in a plane generally parallel to the housing's longitudinal axis. This arrangement of the midrange driver 10 wherein the mid-frequency sound enters the housing substantially non-axially is suitable because the mid-frequency sound waves from the midrange driver are large enough so that a standing wave will not form in the bend or curve of the midrange sound paths 34a-e. Additionally, the size and shape of the sound input portions 28a-e, the sound ports 38a-e, and the sound paths 34a-d can be selected to help mitigate the formation of any standing waves.
In the housing 8 shown in
Similarly, in some embodiments, the lengths of each of the plurality of high-frequency sound paths 36a-d are all substantially equal to each other (i.e., at least acoustically equal) so that all of the high-frequency sound signals entering the inlet aperture 40 at the same time are divided between the four high-frequency sound channels 32a-d and travel the same distance as the other high-frequency sound signals moving along the high-frequency sound paths 36a-d. All of the high-frequency sound signals entering the waveguide 6 at the same time will exit the high-frequency openings 18a-d at the same time even though they each pass through different high-frequency openings 18a-d and travel in different directions. In other embodiments, however, the individual high-frequency sound channels 32a-d can be sized such that some or all of the corresponding sound paths 36a-d have different lengths.
The midrange and high-frequency channels 30a-e and 32a-d are configured to isolate the midrange sound signals from the high-frequency sound signals as they travel through the wave guide. Accordingly, the midrange sound signals do not mix with or travel in the high-frequency channels 32a-d, and the high-frequency sound signals do not travel in the midrange channels 30a-d. In the illustrated embodiment, the interleaved midrange and high-frequency sound channels 30a-e and 32a-d are curved and contoured within the housing 8, although the channels can have different shapes and arrangements in other embodiments.
While the midrange sound paths 34a-e all have substantially the same path length as each other, and the high-frequency sound paths 36a-d also have substantially the same path length as each other, the path length of the midrange sound paths 34a-e is not necessarily the same as the path length of the high-frequency sound paths 36a-d. In some embodiments, such as the embodiment shown in
To provide a desired and positive acoustic experience for a listener of the speaker assembly, the midrange sound signal and the high-frequency sound signal should arrive at a listener effectively at the same time (i.e., the midrange sound signals leave the first plurality of openings 16a-e at the same time the high-frequency sound signals leave the second plurality of openings 18a-d). The midrange and high-frequency bands may partially overlap such that the midrange driver 10 and high-frequency driver 12 are both capable of producing sounds at frequencies within the overlapping frequencies. When two such overlapping sound waves meet, they may interfere with each other and provide a combined wave with an amplitude equal to the sum of the amplitude of the amplitudes for the two original sound waves. When the two waves are in phase with each other (i.e., the peaks and troughs of the first sound wave are aligned with the peaks and troughs of the second sound wave), the two waves constructively interfere and the amplitude of the combined wave is equal to the sum of the maximum amplitudes of the two original waves. However, when the two waves are out of phase with each other, (i.e., the peaks and troughs of the first sound wave are not aligned with the peaks and troughs of the second sound wave), the two waves destructively interfere and the amplitude of the combined wave is less than the sum of the maximum amplitudes of the two original waves.
In embodiments where the path length of the midrange sound paths 34a-e in the housing 8 is greater than the path length of the high-frequency sound paths 36a-d, the time required for the high-frequency sound signal to travel through each of the high-frequency sound channels 32a-d is longer than the time required for the midrange sound signal to travel through each of the plurality of midrange sound channels 30a-e. As a result, the time required for the high-frequency sound signal to travel from the high-frequency driver 12 to a listener of the speaker assembly is greater than the time required for the midrange sound signal to travel from the midrange driver 10 to the location of the listener. If care is not taken, the midrange and high-frequency sound signals may be out of phase with each other, creating a non-uniform listening experience.
To ensure that the midrange and high-frequency sound signals reach the listener at the same time, the drivers 10 and 12 may be connected to a controller, such as a digital signal processor or other controller, to delay the signal generation from one of the drivers. In other embodiments, other delay techniques, such as a passive crossover network, as an example, may be coupled to the speaker drivers 10 and 12 and/or the waveguide 6 to delay the transmission and/or generation of one of the sound signals. The time delay may be based on the operational frequency ranges of the drivers, the signal phases, and the difference between the path lengths of the midrange and high-frequency sound paths 34a-e and 36a-d. Delaying selected sound signal generation can help ensure a coherent wave front or other optimal wave summation at the output of the housing 8.
In the illustrated embodiment, the high-frequency sound channels 32a-d can be sized and shaped such that the sum of the cross-sectional area for each of the high-frequency sound channels 32a-d at points near the second input aperture 40 is substantially equal to the surface area of the output surface of the high-frequency driver 12. On the other hand, the midrange driver 10 may have an output surface area significantly larger than that of the high-frequency driver 12. Equating the sum of the cross-sectional areas for each of the midrange sound channels 30a-e at points adjacent to the first input aperture 26 to the surface area of the output surface of the midrange driver 10 would result in an oversized housing 8. Because of this, the midrange sound channels 30a-e are sized and shaped such that the sum of the cross-sectional areas for the midrange sound channels 30a-e at points adjacent to the first input aperture 26 are less than the surface area of the midrange driver output surface. However, because the midrange driver 10 and the first input aperture 26 are significantly larger than the high-frequency driver and second input aperture 40, the cross-sectional area of each of the plurality of midrange sound channels 30a-e at points near the first input aperture 26 is greater than the cross-sectional area of each of the plurality of high-frequency sound channels 32a-d at points near the second input aperture 40. Other embodiments can have midrange sound channels 30a-e and high-frequency sound channels 32a-d with different cross-sectional area ratios or configurations. For example, some or all of the sound channels 30a-e and 32a-d may have a flared configuration wherein the cross-sectional areas of the channels gradually increase between the respective first or second input apertures 26 and 40 and the openings 16a-e and 18a-d at the front 20 of the housing 8.
As seen in
In the illustrated embodiment shown in
As seen in
The waveguide 41 is configured so the midrange sound signal travels through the plurality of midrange sound channels 58a-e along the midrange sound paths 62a-e toward the front 44 of the housing 42, and the high-frequency sound signal travels through the plurality of high-frequency sound channels 60a-d along the high-frequency sound paths 64a-d toward the front surface 44 of the housing 42. Each midrange sound path 62a-e has a path length substantially equal to that of the other midrange sound paths 62a-e, and each high-frequency sound path 64a-d has a path length substantially equal to that of the other high-frequency sound paths 64a-d.
In the illustrated embodiment, the midrange sound channels 58a-e have a substantially constant width and height along the entire length to the midrange openings 66a-e. The high-frequency sound channels 60a-d also have a substantially constant width and height (although less than the width of the midrange sound channels 58a-e) along most, but not all, of the high-frequency sound path 64a-d. The high-frequency sound channels 60a-d of the illustrated embodiment flare outwardly as they approach the front 44 of the housing 42, such that the high-frequency openings 68a-d have a width W4 greater than the width W3 of the midrange openings 66a-e. In other embodiments, the high-frequency openings 68a-d can have the same width or smaller width as those of the midrange openings 66a-e.
Adjustments to the sound channel's dimensions can also be achieved by controlling the channel height along some or all of the channel's length. For example,
In this illustrated embodiment, each high-frequency sound channel can flare vertically as it approaches the front surface 74 of the housing 72, such that the channel has a first height H1 at a point near the inlet aperture 82 and a second height H2 that is greater than the first height H1. In some embodiments, all of the high-frequency sound channels and all of the midrange sound channels can increase in height as they extend toward the front surface 74. As discussed above, the midrange and the high-frequency sound channels can also flare horizontally along some or all of the sound paths (i.e., increasing in width) as the sound channels extend toward the front surface 74. In some embodiments, the height and/or width of the high-frequency sound channels may change at a different rate than the change to the respective height and/or width of the midrange sound channels over the same distance. In the illustrated embodiment, the front surface of the waveguide at the midrange and high-frequency openings is substantially flat or planar and perpendicular to the longitudinal axis of the waveguide. In other embodiments, the waveguide can be configured with a curved or arcuate front surface which can help with controlling the distribution of the sound exiting the waveguide. In yet other embodiments, the waveguide's front surface can have other shapes (i.e., multi-planar, partially-circular, partially-spherical, etc., or combinations thereof), and the front surface can be at one or more selected angles relative to the waveguide's longitudinal axis.
In the previously illustrated embodiments, the waveguide is depicted as having a housing that includes five midrange sound channels interleaved with four high-frequency sound channels and the various channels are arranged such that the outermost sound channels are midrange sound channels. However, this is only an example. In other embodiments, the housing can include a different number of midrange and high-frequency sound channels, and the various sound channels can be arranged such that the outermost sound channels are high-frequency sound channels.
When the sound waves are emitted from the waveguide, the sound waves tend to spread out. Eventually, the individual sound waves can spread out until they overlap with a different sound wave. If the two different sound waves have a similar frequency and are in phase with each other, the two sound waves can combine together to form a single united wavefront having a generally evenly distributed intensity. In this way, when the midrange sound waves are emitted from the output openings 118a-e, the midrange sound waves can combine together to form a single midrange wavefront. On the other hand, the high-frequency sound waves tend to not spread out as quickly as the midrange sound waves and the distance between individual output openings 116a-f can be too far for the high-frequency sound waves to sufficiently combine and form a united wavefront before the high-frequency sound waves reach listeners. As a result, some of the listeners may experience louder high-frequency sounds than other listeners because the high-frequency sound waves are not evenly distributed. To cause the high-frequency sound waves to spread out sufficiently so that they can form a more-united wavefront, the high-frequency sound channels 132a-f can start to flare out before the front surface 120. With this arrangement, the high-frequency sound waves can start to spread out before reaching the front surface 120 and can cause the distance between two of the output openings 116a-f to be reduced so that the high-frequency sound waves can merge into a single wavefront more quickly.
To further improve the uniformity of the high-frequency wavefront, the midrange sound channels 130a-e and the high-frequency sound channels 132a-f can be arranged such that the high-frequency sound channels 132a-f are interleaved with the midrange sound channels 130a-e. With this arrangement, the outermost sound channels for the waveguide 106 are the high-frequency sound channels 132a and 132f. The housing 108 can include a mounting flange 114 that can be used to couple the housing 108 to a horn. During operation of the waveguide 106, when the sound waves are emitted from the front surface 120, the horn can direct the high-frequency and midrange sound waves toward listeners of the speaker system. By arranging the sound channels such that the high-frequency sound channels 132a and 132f are the outermost sound channels, the associated high-frequency sound waves can travel along the sidewalls of the horn.
While forming the waveguide such that the high-frequency sound channels 132a and 132f are the outermost sound channels can help to increase the uniformity of the high-frequency wavefront, the distances between adjacent output openings 118a-f may still be too far for the high-frequency sound waves to sufficiently combine and form a uniform wavefront before the sound waves reach the listeners. To further increase the uniformity of the high-frequency wavefront, in some embodiments, the waveguide can include a mixing portion coupled to the front surface of the housing and configured to reduce the spacing between the individual high-frequency sound waves when the sound waves are emitted from the waveguide.
During operation of the waveguide 206, high-frequency sound waves enter the housing 208 and pass into the high-frequency sound channels 232a-f, which direct the high-frequency sound waves toward the front of the housing 208. Upon reaching the front surface of the housing 208, the high-frequency sound waves pass into the extensions 286a-f. The extensions 286a-f are each centered over one of the high-frequency sound channels 232a-f and are shaped such that the sidewalls of the extensions 286a-f are aligned with the sidewalls of the high-frequency sound channels 232a-f. In this way, the extensions 286a-f act as continuations of the flared portions of the high-frequency sound channels 232a-f. After passing through the extensions 286a-f, the high-frequency sound waves are emitted from a front surface 292 of the mixing portion 284. With this arrangement, each of the extensions 286a-f is formed immediately adjacent to a neighboring extension 286a-f such that, at the front surface 292 of the mixing portion 284, the extensions 286a-f are not separated from each other. Because the distance between each of the extensions 286a-f at the front surface 292 is minimized, after passing through the extensions 286a-f and being emitted from the front surface 292, the high-frequency sound waves can quickly merge together to form a uniform wavefront.
To allow the midrange sound waves to also be emitted by the mixing portion 284, the mixing portion 284 can include a plurality of ducts 288 that couple the midrange sound channels 230a-e to the extensions 286a-f. In this way, after the midrange sound waves pass through the midrange sound channels 230a-e, the midrange sound waves can pass into the ducts 288, which direct the midrange sound waves into the extensions 286a-f. The midrange sound waves can then pass through the extensions 286a-f and mix with the high-frequency sound waves before being emitted from the front surface 292 of the mixing portion 284. However, if the individual ducts 288 are too wide, the high-frequency sound waves can interact with the ducts 288 as they pass through the extensions 286a-f, which can affect the high-frequency sounds emitted from the mixer portion 284. For example, if the ducts 288 are too wide, the high-frequency sound waves can enter the ducts 288 and bounce off of the walls of the ducts 288, which can cause acoustic modes to form. Accordingly, to prevent the high-frequency sound waves from interacting with the ducts 288, the ducts 288 can be thin enough so that the high-frequency sounds do not significantly interact with the ducts 288.
In some embodiments, each of the midrange sound channels 230a-e can be coupled to the corresponding extensions 286a-f with just a single duct 288. In other embodiments, however, some or all of the midrange sound channels 230a-e can be coupled to the corresponding extensions 286a-f with a plurality of thin ducts 288. For example, in the illustrated embodiment, the mixer apparatus 284 includes a single duct 288 that couples the midrange sound channel 230e to the extension 286e and two ducts 288 that couple the midrange sound channel 230d to the extension 286e. In still other embodiments, each of the midrange sound channels 230a-e can be coupled to the corresponding extensions 286a-f with two or more ducts 288. In some embodiments, the ducts 288 coupled to opposing sides of a given extension 286 can be staggered from each other. Further, because the high-frequency sound waves tend to spread out as they move through the extensions 286a-f, the ducts 288 positioned closer to the front surface 292 can be wider than ducts 288 positioned near the throat of the extensions 286a-f without the high-frequency sound waves interacting with the wider ducts 288. In embodiments for which the midrange sound channels 230a-e are coupled to multiple ducts 288, the sum of the widths of each of ducts 288 coupled to a given one of the sound channels 230a-e can be equal to the width of the given midrange sound channel 230a-e. In general, the mixer portion 284 can include any suitable number of ducts 288 coupled between the individual midrange sound channel 230a-e and the extensions 286a-f and the individual ducts 288 can have any suitable width that does not cause the high-frequency sound waves to interact with the ducts 288.
In some embodiments, the mixer portion 284 can be formed separately from the housing 208 and can be attached to the front surface of the housing 208 (e.g., with an adhesive, screws, other fasteners, etc.). For example, in the illustrated embodiment, the mixer portion 284 is coupled to the housing 208 using the lip portion 214 of the housing 208. The mixer portion 284 can be configured to attach to a waveguide with a flat front surface or an arcuate or otherwise shaped front surface as discussed above. Similarly, the front surface 292 of the mixing portion 284 can be substantially planar, arcuate or otherwise shaped as discussed above. The front surface 292 can be substantially perpendicular to the longitudinal axis of the waveguide or at one or more angles relative to the longitudinal axis, which can help to selectively control sound distribution as the sound exits the waveguide and the mixing portion. In other embodiments, however, the mixer portion 208 can be integrally formed as part of the housing 208 such that the waveguide 206 is formed from a single component. Further, in embodiments for which the mixer portion is integrally formed as part of the housing 208, the ducts 288 can be positioned further from the front surface 292 of the mixer portion 284. For example, in some embodiments, the ducts 288 can be formed such ducts 288 can couple individual of the midrange sound channels 230a-e to adjacent high-frequency sound channels 232a-f.
In the embodiment shown in
As in the embodiment shown in
From the foregoing, it will be appreciated that specific embodiments of the invention have been described herein for purposes of illustration, but that various modifications may be made without deviating from the scope of the invention. Accordingly, the invention is not limited except as by the appended claims.
This application is a continuation of U.S. patent application Ser. No. 16/950,808, titled “MULTI-WAY ACOUSTIC WAVEGUIDE FOR A SPEAKER ASSEMBLY” and filed Nov. 17, 2020, which is a continuation of U.S. patent application Ser. No. 16/722,781, titled “MULTI-WAY ACOUSTIC WAVEGUIDE FOR A SPEAKER ASSEMBLY” and filed Dec. 20, 2019, which is a continuation of U.S. patent application Ser. No. 16/243,997, titled “MULTI-WAY ACOUSTIC WAVEGUIDE FOR A SPEAKER ASSEMBLY” and filed Jan. 9, 2019, which claims the benefit of and priority to U.S. Provisional Patent Application No. 62/615,398, titled “MULTI-WAY ACOUSTIC WAVEGUIDE FOR A SPEAKER ASSEMBLY” and filed Jan. 9, 2018, all of which are incorporated herein in their entirety by reference thereto.
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Number | Date | Country | |
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Parent | 16950808 | Nov 2020 | US |
Child | 17583111 | US | |
Parent | 16722781 | Dec 2019 | US |
Child | 16950808 | US | |
Parent | 16243997 | Jan 2019 | US |
Child | 16722781 | US |