The present invention relates to reproduction of sound in multichannel systems generically known as “surround-sound” or “home theater” systems and more specifically to single enclosure “sound bar” style multi-driver loudspeaker systems configured for use in front of a listening space.
Listeners use two channel “stereo systems” and “surround-sound” or “home theater” audio systems for music playback and other types of audio reproduction.
Surround-sound or home theater loudspeaker systems are configured for use with standardized home theater audio systems which may include a plurality of playback channels, each typically served by an amplifier and a loudspeaker. In basic Dolby™ home theater audio playback systems, there are typically five or more channels of substantially full range material plus a subwoofer channel configured to reproduce band-limited low frequency material. The five substantially full range channels in a basic Dolby Digital 5.1™ system are typically, center, left front, right front, left surround and light surround (e.g., as shown in
Unfortunately, when typical surround sound (e.g., Dolby® 5.1) loudspeaker systems are installed in listener's homes, setup problems are encountered and many users struggle with speaker placement, component connections and related complications. In response, many listeners have turned to “soundbar” style home theater loudspeaker systems (e.g., 50) which incorporate at least left, center and right channels into a single enclosure (e.g., 60) configured for use near the user's video display (as shown in
These soundbar style single enclosure loudspeaker systems (“soundbars”) are simpler to install and connect and can be configured as compact, active loudspeaker products for use almost anywhere. But most soundbars provide unsatisfactory performance for listeners who want to listen to movies and music from listening positions arrayed in a typical user's listening space. Traditional home-theater installations (e.g., 10 as shown in
Unlike home theater systems, modern commercial Cinemas are now equipped with sound systems designed to create an “immersive” or “3-D” sound field with loudspeakers mounted over the listeners to create sound images which come from sources that are in front, behind, beside and overhead. For example, the Dolby® Atmos™ system places loudspeakers in or on the theater's ceiling to provide overhead sound sources, and reproduction of Dolby® Atmos™ “height” or elevation program material is now possible using loudspeakers in the home, as described Dolby's U.S. Pat. No. 9,648,440, the entire disclosure of which is incorporated by reference for purposes of defining the background and “Atmos” Height-Channel nomenclature. A consumer or home theater enthusiast who cannot equip their home using commercial cinema sound equipment but wants to recreate the immersive 3-D sound field experienced with the Dolby® Atmos™ system can configure and install a system with “Virtual Height” speakers such as those described and illustrated in Dolby's U.S. Pat. No. 9,648,440. A competing Height-Channel or vertically immersive elevation audio reproduction speaker system is sold by DTS, Inc. in connection with the “DTS-X®” brand name.
Height-Channel speakers or speakers with upward firing elevation modules such as those described in Dolby's U.S. Pat. No. 9,648,440 (and illustrated in
There is a need, therefore, for a more effective, satisfying and unobtrusive system and method for providing high-fidelity playback of cinema sound in a home theater user's listening space when the user seeks to recreate or simulate the immersive 3-D sound field experienced with modern commercial cinema systems having Height-Channel audio reproduction such as the Dolby® Atmos™ or DTS-X® systems.
Accordingly, it is an object of the present invention to overcome the above mentioned difficulties by providing a method and system for implementing a new loudspeaker configuration and signal processing method for overcoming the problems with prior art ATMOS™ or DTS-X® compatible Height-Channel speaker equipped home theater products which provides high-fidelity playback of cinema sound in a home theater user's listening space when the user seeks to recreate or simulate the immersive 3-D sound field experienced with modern commercial cinema systems such as the Dolby® ATMOS™ or DTS-X® systems.
In the system of the present invention, an ATMOS or DTS-X® enabled soundbar and subwoofer home theater sound system (somewhat like 50, in
There are two main aspects to the system and method of the present invention, the first describes a system for substantially reducing the forward-radiating sound associated with Height-Channel (e.g., ATMOS) loudspeaker arrays (e.g., 113DS) in a Height-Channel enabled sound bar system over a limited bandwidth. By design, Height-Channel signals are intended to be beamed in a prescribed radiation pattern (e.g., 108) towards the ceiling of a media room or space (e.g., 102, at a spot 104) for reflection down into the listening area (e.g., at 24). Any significant direct radiation from a loudspeaker system (such as a soundbar enclosure, e.g., 60) toward the listener is harmful to the Height-Channel effect due in part to something the listener experiences which is referred to as the “Precedence” or “Haas” effect. The directly radiated sound (113DS) will substantially detract from the intended height cues afforded by sound that seems to originate from above (the ceiling reflected sound from 104 actually desired) because of this Haas effect. In applicant's development work, it was discovered that by employing the soundbar's front facing mid-bass transducers to reproduce a band-passed phase reversed replica of the Height-Channel (e.g., ATMOS) signals, a Height-Channel enabled soundbar having left and right side Height-Channel speaker arrays can be configured and driven to provide much better performance. The Height-Channel arrays' radiation patterns may be effectively improved in a measurable way.
Another aspect of the system and method of the present invention involves steering the sound projecting from a Height-Channel array in such a manner that its primary axis of radiation is selectable or steerable within an angular range and may generally deviate from what would ordinarily be expected based on the geometry of the array of transducers. Array steering and controls related to phased array steering control the acoustic transducers' primary axis of radiation and is accomplished in part by determining the inter array element time delay. In accordance with the generally accepted practices regarding phased array design (e.g., as described and illustrated in U.S. Pat. No. 9,736,977, to Yamamoto et al.), directivity may be improved by increasing the number of array elements which is functionally similar to increasing the array size relative to an acoustic wavelength. During applicant's Height-Channel (e.g. ATMOS) enabled soundbar development work, it was discovered that the front-to-back dimension is of particular significance with respect to steering an array's directivity.
The advantages of the system and method of the present invention include, most importantly, that the radiation pattern of each Height-Channel array of a Height-Channel-enabled soundbar is improved by effectively cancelling some portion of the forward radiating component (e.g., like 113DS, as shown in
The upward orientation facilitates a more efficient use of enclosure volume and permits more possibilities with regard to industrial design as a means of distinguishing this novel product from conventional ATMOS™ compatible soundbars.
The above and still further objects, features and advantages of the present invention will become apparent upon consideration of the following detailed description of a specific embodiment thereof, particularly when taken in conjunction with the accompanying drawings, wherein like reference numerals in the various figures are utilized to designate like components.
Turning now to
In accordance with the configuration and method of the present invention, the lower portion of the Height-Channels' bandwidth that would otherwise be part of the undesired direct radiation signal (213DS) radiating directly forward into the listening area 24 is cancelled acoustically. A cancellation signal is generated and radiated from the soundbar's front firing speakers 312. As illustrated in
In the initial signal processing method step, a band-pass filter over the upper bass range (e.g., approximately 200 to 400 Hz or higher) is applied to each Height-Channel channel signal (both left and right height channels, whether discrete for Dolby ATMOS program material, DTS equivalent program material with discrete channels or derived height channels when using non-ATMOS program material such as Dolby Digital 5.1 or 7.1). In the next step, phase or polarity inversion of each band-pass height channel signal is applied. Depending on the product configuration (of soundbar system 260), the signal may then be attenuated by 3 to 9 dB and there may be product-dependent magnitude shaping (parametric equalization) to complete the signal processing in order to derive a corrective secondary source for substantially reducing direct in-room radiation (e.g., 213DS) from the Height-Channel loudspeaker arrays 310L, 310R, as perceived by the listener at the listening location 24. In an equivalent, alternative embodiment, the radiation pattern of the Height-Channel loudspeaker arrays 310L, 310R may be altered by reducing the beamwidth or increasing the directivity of the Height-Channel array for the cancellation signal projected toward the listener.
In the absence of imposing delay on the Height-Channel cancellation signal for the soundbar's front firing speakers 312, the derived secondary source radiation would reach listeners in advance of the direct radiation from the Height-Channel loudspeakers 310L, 310R (i.e., signal 213DS, which is supposed to be cancelled acoustically). Therefore an appropriate delay should be placed on the Height-Channel direct signal cancellation signals relative to the front channel loudspeaker radiation in order to ensure synchronous radiation in the listening area and optimal performance from the secondary sources. The delay may be computed simply by considering the distance between the acoustic center of the secondary sources (i.e., front facing soundbar speakers 312) and the acoustic center of the Height-Channel upward facing speakers in the arrays 310L, 310R.
When multiple speakers are employed, an average location is preferably derived for purposes of this delay computation:
delay=(AC,A−AC,f)/c Eq. 1
where AC,A=the position of the acoustic center of the Atmos transducer(s), AC,f=the position of the acoustic center of the front baffle secondary source and c=speed of sound in air at sea level, room temperature=343 m/s. It may be noted that in some instances owing to the industrial design of the Height-Channel (e.g., ATMOS™ or DTS-X®) compatible soundbar, the computed delay may approach zero. This is especially the case for shallow soundbars whose Height-Channel arrays 310L, 310R are placed substantially over the front-baffle mounted transducers 312 aligned along speaker axis SA, in which case the front-baffle mounted transducers (e.g., 312L, 312R) most physically proximate or closest to the Height-Channel arrays 310L, 310R are selected as the secondary (cancellation) sources.
The second aspect of this invention pertains to steering the multi-element array of electro-acoustic transducers which are firing from the soundbar 260 upwardly into the listening space. By delaying the acoustic output of adjacent array elements or adjacent loudspeaker driver transducers by an appropriate amount of time, the collective output of the array (e.g., 310L and 310R) may be steered (see, e.g., the diagram of
t=l*tan(theta)/c Eq. 2
where l is the inter-element spacing (2.25 in), theta is the steering angle (5 degrees) and c is the speed of sound and air (343 m/s). For this exemplary embodiment, the time delay for that 5 degree steering angle t is equal to 14.6 uSec. Further refinements to the radiation pattern may be implemented by applying particular finite impulse response (“FIR”) filters to each element's magnitude response, in the manner generally known as magnitude shaping, thereby combining both phase and magnitude shaping to derive an optimized steered array response. In accordance with the present invention, signal processing methods with FIR filters for beam-shaped acoustic arrays are refined for applications including the soundbar structures illustrated in
Referring again to
Multi-driver multi-channel single enclosure Height-Channel (e.g., ATMOS™ or DTS-X®) enabled soundbar loudspeaker system 260 preferably has a single chassis including planar bottom and left and right side sidewall members which also support a substantially vertical front wall segment or planar baffle defining a speaker axis SA and having a proximal or front surface bounded by a left end opposing a right end. In the illustrated embodiment, the single enclosure Height-Channel enabled soundbar loudspeaker system's enclosure is preferably configured with a first forward facing driver 312L positioned laterally left of the enclosure center nearer the left end and a second forward facing driver 312R positioned laterally right of the enclosure center nearer the right end. The enclosure also aims and supports other midwoofer and tweeter drivers mounted and aimed forwardly, as best seen in
Multi-driver multi-channel single enclosure Height-Channel enabled soundbar loudspeaker system 260 also has an upper surface or enclosure wall segment with left and right distal ends which carry a left side upward firing array of three drivers 310L configured to generate the left Height-Channel (virtual height) channel's audio and a right side upward firing array of three drivers 310R configured to generate the right Height-Channel (virtual height) channel's audio.
The first forward facing driver 312L is driven with signals modified in accordance with the present invention to cancel any undesired horizontally projecting direct sound (e.g., 213DS, as best seen in
Multi-channel single enclosure Height-Channel enabled soundbar loudspeaker system 260 preferably includes several dedicated amplifiers, each driving a corresponding loudspeaker driver (e.g., 312L, 312R) which are each mounted and acoustically sealed into one of five (5) subenclosures (as shown in
Persons of skill in the art will recognize that the present invention makes available a system and method for Active Cancellation of a Height-Channel array's forward sound radiation (e.g., 213DS) employing the Soundbar front baffle's transducers and steering the sound projecting from the Height-Channel arrays via Phased Array techniques. The invention also comprises a multi-channel single enclosure Height-Channel (e.g., ATMOS™ or DTS-X®) enabled soundbar loudspeaker system 260, including first enclosure 270 having front baffle surface 270F aligned along speaker axis SA and terminating on opposing lateral sides with substantially transverse left and right sidewall surfaces 270L, 270R and terminating along its upper edge with a top wall surface 270T.
Soundbar loudspeaker enclosure 270 preferably has a plurality of acoustically isolated sub-enclosures, and in
Soundbar loudspeaker system enclosure 270 supports and aims loudspeaker drivers or transducers including aa first, left-main and Height-Channel direct signal cancellation loudspeaker driver 312L mounted on front baffle 270F, proximate left sidewall 270L, (ii) second, right-main and Height-Channel direct signal cancellation loudspeaker driver 312R, mounted on front baffle 270F, proximate the right sidewall 270R, and (iii) a first, left three driver Height-Channel speaker array 310L aimed upwardly from the top wall surface 270T, proximate left sidewall 270L and having its acoustic center spaced from the left-main and Height-Channel direct signal cancellation loudspeaker driver 312L by a selected distance DL-AC in the range of 2 to 6 inches (e.g., 2-3 inches, and preferably less than 5.5 inches). Soundbar loudspeaker system 260 enclosure 270 also supports and aims (iv) a second, right Height-Channel speaker array 310R aimed upwardly from the top wall surface, proximate the right sidewall and having its acoustic center spaced from the right-main and Height-Channel direct signal cancellation loudspeaker driver 312R by a distance DR-AC in the range of 2 to 6 inches (e.g., 2-3 inches, and preferably less than 5.5 inches).
As illustrated in
In an alternative prototype for the steered “beam” direction for the sound from the Height-Channel arrays (e.g., 310L, 310R, see
Thus t=2.924 (10−5) seconds or about 0.03 mS (for Θ of 5 degrees). As noted above, while the exemplary embodiment described and illustrated here includes three element Height-Channel arrays 310L and 310R, the structure and beam steering method of the present invention can be implemented effectively with each array comprising between 2 and 5 elements with slightly different spacings.
In multi-driver multi-channel single enclosure Height-Channel (e.g., ATMOS™ or DTS-X®) enabled soundbar loudspeaker system 260, each Height-Channel array is steered at a selected ceiling bounce angle (e.g., between 5 degrees and 20 degrees, depending, in part, on where soundbar enclosure 270 is mounted and how deep, front to back, the enclosure will be), so steering delay “t” may be selected to correspond to the desired ceiling bounce angle and may be in the range of 0.03 ms to 1.3 ms or more, depending on the placement and size of the drivers in each Height-Channel array (e.g., 310L). Referring to
Referring again to
As noted above, for purposes of defining a broad descriptive nomenclature, in this application, the terms ATMOS or DTS-X are used not as trademarks but instead are used nominatively and interchangeably to describe, generically, Virtual Height signals and speakers intended to create the desired vertically immersive elevation effect, so left and right side Virtual Height sound projecting speaker arrays (310L, 310R) are referred to variously as Height-Channel arrays or ATMOS arrays, and so the term ATMOS is refers broadly to Height-Channel or Virtual Height signals, speakers, signal processing circuits or DSP methods intended to facilitate or create the desired vertically immersive elevation effect.
Having described preferred embodiments of a new and improved loudspeaker system and signal processing method, it is believed that other modifications, variations and changes will be suggested to those skilled in the art in view of the teachings set forth herein. It is therefore to be understood that all such variations, modifications and changes are believed to fall within the scope of the present invention.
This application claims priority to and benefit of: (a) U.S. Provisional Application No. 62/815,204 (filed Mar. 7, 2019), entitled “Active Cancellation of an ATMOS Soundbar's Array's Forward Sound Radiation Employing the Soundbar's Front Baffle's Transducers and Steering ATMOS Arrays via Phased Array Techniques” and(b) US PCT Application PCT/US20/21745 (filed Mar. 9, 2020) entitled “Active Cancellation of a Height-Channel Soundbar Array's Forward Sound Radiation”, both by Brad STAROBIN et. al., the entire disclosures of which are incorporated herein by reference.
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/US2020/021745 | 3/9/2020 | WO |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2020/181288 | 9/10/2020 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
4489432 | Polk | Dec 1984 | A |
4497064 | Polk | Jan 1985 | A |
4569074 | Polk | Feb 1986 | A |
8054980 | Wu et al. | Nov 2011 | B2 |
9374640 | Starobin | Jun 2016 | B2 |
9648440 | Crockett et al. | May 2017 | B2 |
9736577 | Yamamoto et al. | Aug 2017 | B2 |
9865245 | Kamdar et al. | Jan 2018 | B2 |
10217451 | Kamdar et al. | Feb 2019 | B2 |
10863276 | Walther et al. | Dec 2020 | B2 |
10902838 | Kamdar et al. | Jan 2021 | B2 |
11190877 | Kamdar et al. | Nov 2021 | B2 |
20080273713 | Hartung et al. | Nov 2008 | A1 |
20100119089 | Tracy | May 2010 | A1 |
20120163614 | Asada et al. | Jun 2012 | A1 |
20150304791 | Crockett et al. | Oct 2015 | A1 |
20170053641 | Kamdar et al. | Feb 2017 | A1 |
20170127211 | Crockett et al. | May 2017 | A1 |
20170164134 | Yamamoto | Jun 2017 | A1 |
20170208392 | Smithers et al. | Jul 2017 | A1 |
20170325019 | Bezzola et al. | Nov 2017 | A1 |
20180103316 | Faller et al. | Apr 2018 | A1 |
20180184202 | Walther et al. | Jun 2018 | A1 |
20180192185 | Starobin | Jul 2018 | A1 |
20180242077 | Smithers et al. | Aug 2018 | A1 |
20180367939 | Fischer | Dec 2018 | A1 |
20190116445 | Gerrard et al. | Apr 2019 | A1 |
20210409866 | Orth | Dec 2021 | A1 |
Number | Date | Country |
---|---|---|
WO 2018112335 | Aug 2018 | WO |
Number | Date | Country | |
---|---|---|---|
20220159397 A1 | May 2022 | US |
Number | Date | Country | |
---|---|---|---|
62815204 | Mar 2019 | US |