Patent Application
20070211574
1. Field of the Invention
The present invention relates generally to the field of parametric loudspeakers. More particularly, the present invention relates to a multi-channel parametric loudspeaker system, wherein individual channels are detected differentially by a listener or at individual reception points.
2. Related Art
Audio reproduction has long been considered a well-developed technology. Over the decades, sound reproduction devices have moved from a mechanical needle on a tube or vinyl disk, to analog and digital reproduction over laser and many other forms of electronic media. Advanced computers and software now allow complex programming of signal processing and manipulation of synthesized sounds to create new dimensions of listening experience, including applications within movie and home theater systems. Computer generated audio is reaching new heights, creating sounds that are no longer limited to reality, but extend into the creative realms of imagination.
Nevertheless, the actual reproduction of sound at the interface of electro-mechanical speakers with the air has remained substantially the same in principle for almost one hundred years. Such speaker technology is clearly dominated by dynamic speakers, which constitute more than 90 percent of commercial speakers in use today. Indeed, the general class of audio reproduction devices referred to as dynamic speakers began with the simple combination of a magnet, voice coil and cone, driven by an electronic signal. The magnet and voice coil convert the variable voltage of the signal to mechanical displacement, representing a first stage within the dynamic speaker as a conventional multistage transducer. The attached cone provides a second stage of impedance matching between the electrical transducer and air envelope surrounding the transducer, enabling transmission of small vibrations of the voice coil to emerge as expansive compression waves that can fill an auditorium. Such multistage systems comprise the current fundamental approach to reproduction of sound, particularly at high energy levels.
A lesser category of speakers, referred to generally as film or diaphragmatic transducers, relies on movement of an emitter surface area of film that is typically generated by electrostatic or planar magnetic driver members. Although electrostatic speakers have been an integral part of the audio community for many decades, their popularity has been quite limited. Typically, such film emitters are known to be low-power output devices having applications appropriate only to small rooms or confined spaces. With a few exceptions, commercial film transducers have found primary acceptance as tweeters and other high frequency devices in which the width of the film emitter is equal to or less than the propagated wavelength of sound. Attempts to apply larger film devices have resulted in poor matching of resonant frequencies of the emitter with sound output, as well as a myriad of mechanical control problems such as maintenance of uniform spacing from the stator or driver, uniform application of electromotive fields, phase matching, frequency equalization, etc.
As with many well-developed technologies, advances in the state of the art of sound reproduction have generally been limited to minor enhancements and improvements within the basic fields of dynamic and electrostatic systems. Indeed, substantially all of these improvements operate within the same fundamental principles that have formed the basics of well-known audio reproduction. These include the concept that (i) sound is generated at a speaker face, (ii) based on reciprocating movement of a transducer (iii) at frequencies that directly stimulate the air into the desired audio vibrations. From this basic concept stems the myriad of speaker solutions addressing innumerable problems relating to the challenge of optimizing the transfer of energy from a dense speaker mass to the almost massless air medium that must propagate the sound.
A second fundamental principle common to prior art dynamic and electrostatic transducers is the fact that sound reproduction is based on a linear mode of operation. In other words, the physics of conventional sound generation rely on mathematics that conform to linear relationships between absorbed energy and the resulting wave propagation in the air medium. Such characteristics enable predictable processing of audio signals, with an expectation that a given energy input applied to a circuit or signal will yield a corresponding, proportional output when propagated as a sound wave from the transducer.
In such conventional systems, maintaining the air medium in a linear mode is extremely important. If the air is driven excessively into a nonlinear state, severe distortion occurs and the audio system is essentially unacceptable. This nonlinearity occurs when the air molecules adjacent the dynamic speaker cone or emitter diaphragm surface are driven to excessive energy levels that exceed the ability of the air molecules to respond in a corresponding manner to speaker movement. In simple terms, when the air molecules are unable to match the movement of the speaker so that the speaker is loading the air with more energy than the air can dissipate in a linear mode, then a nonlinear response occurs, leading to severe distortion and speaker inoperability. Conventional sound systems are therefore built to avoid this limitation, ensuring that the speaker transducer operates strictly within a linear range.
Parametric sound systems, however, represent an anomaly in audio sound generation. Instead of operating within the conventional linear mode, parametric sound can only be generated when the air medium is driven into a nonlinear state. Within this unique realm of operation, audio sound is not propagated from the speaker or transducer element. Instead, the transducer is used to propagate carrier waves of high-energy, ultrasonic bandwidth beyond human hearing. The ultrasonic wave therefore functions as the carrier wave, which can be modulated with audio input that develops sideband characteristics capable of decoupling in air when driven to the nonlinear condition. In this manner, it is the air molecules and not the speaker transducer that will generate the audio component of a parametric system. Specifically, it is the sideband component of the ultrasonic carrier wave that energizes the air molecule with audio signal, enabling eventual wave propagation at audio frequencies.
Another fundamental distinction of a parametric speaker system from that of conventional audio is that high-energy transducers as characterized in prior art audio systems do not appear to provide the necessary energy required for effective parametric speaker operation. For example, the dominant dynamic speaker category of conventional audio systems is well known for its high-energy output. Clearly, the capability of a cone/magnet transducer to transfer high-energy levels to surrounding air is evident from the fact that virtually all high-power audio speaker systems currently in use rely on dynamic speaker devices. In contrast, low output devices such as electrostatic and other diaphragm transducers are virtually unacceptable for high-power requirements. As an obvious example, consider the outdoor audio systems that service large concerts at stadiums and other outdoor venues. Normally, massive dynamic speakers are necessary to develop direct audio to such audiences. To suggest that a low-power film diaphragm might be applied in this setting would be considered foolish and impractical.
Yet in parametric sound production, the present inventors have surprisingly discovered that a film emitter will outperform a dynamic speaker in developing high-power, parametric audio output. Indeed, it has been the general experience of the present inventors that efforts to apply conventional audio practices to parametric devices will typically yield unsatisfactory results. This has been demonstrated in attempts to obtain high sound pressure levels, as well as minimal distortion, using conventional audio techniques. It may well be that this prior art tendency of applying conventional audio design to construction of parametric sound systems has frustrated and delayed the successful realization of commercial parametric sound. This is evidenced by the fact that prior art patents on parametric sound systems have utilized high-energy, multistage-like bimorph transducers comparable to conventional dynamic speakers. Despite widespread, international studies in this area, none of these parametric speakers were able to perform in an acceptable manner.
In summary, whereas conventional audio systems rely on well accepted acoustic principles of (i) generating audio waves at the face of the speaker transducer, (ii) based on a high-energy output device such as a dynamic speaker, (iii) while operating in a linear mode, the present inventors have discovered that just the opposite design criteria are preferred for parametric applications. Specifically, effective parametric sound is effectively generated using (i) a comparatively low-energy film diaphragm, (ii) in a nonlinear mode, (iii) to propagate an ultrasonic carrier wave with a modulated sideband component that is decoupled in air (iv) at extended distances from the face of the transducer. In view of these distinctions, it is not surprising that much of the conventional wisdom developed over decades of research in conventional audio technology is simply inapplicable to problems associated with the generation parametric sound.
In particular to the present invention, many attempts have been made to create multi-channel surround sound systems. From the time of the introduction of two-channel stereo, there has been a frustration caused by having to use more than one speaker structure to reproduce more than one channel. Current surround sound systems now utilize five or more speakers per system. This places undesirable demands on the aesthetics of the domestic environment and increases the complexity of system installation. Further, there is often a situation where the ideal location for a particular speaker channel is not available, particularly for the surround channels, which often must be hung on rear or sidewalls, ideally in a symmetrical fashion about the listener.
Because of the above problems, there has been a long felt need to integrate more than one channel of projection into a single loudspeaker structure. Previous attempts have fallen by the wayside due to poor simulation of a stereo system. Besides failing in a stereo application, the previous attempts were not designed to address modem multi-channel requirements of three or more channels.
Furthermore, nearly all multi-channel systems are unable to produce true binaural sound, because when multiple conventional speakers emit sound, crosstalk amongst the speakers inherently exists because they are substantially omnidirectional in nature. True binaural sound can be created when independent sound waves are delivered exclusively to each ear of a listener. By controlling the sound that each ear can hear, impressive results may be realized, such as allowing the listener to pinpoint a virtual source of sound. Because of the crosstalk existing in the output of conventional multi-channel speaker systems, it has been exceedingly difficult to produce binaural sound without resorting to the use of headphones worn by the listener. Extensive and complex cross-talk cancellation techniques have been employed in an attempt to generate true binaural sound with conventional loudspeakers.
Similarly, multi-channel parametric devices have not been implemented successfully due to acoustic outputs that were too low when the parametric devices are reasonably sized for each individual channel. If such multiple parametric devices were made larger for a multi-channel system, the large devices would take up too much space and cause a significant increase in cost.
What is needed is a sound projector that can deliver multi-channel sound into an environment simulating multiple speaker locations, and generate true binaural sound.
It has been recognized that it would be advantageous to develop a system which provides the benefits of headphones, such as isolated listening, without the requirement of sound producing devices attached to the head or body of the listener.
The invention provides a virtual headset for enabling isolated listening to audio material by a listener without need for earphones or other physical audio producing devices attached to the listener. The virtual headset includes a parametric ultrasonic signal source supplying at least a first parametric ultrasonic channel signal comprised of an ultrasonic carrier signal and at least one sideband, and configured to be emitted and directed substantially exclusively at a first ear of the listener. The parametric ultrasonic signal source is coupled to an electro-acoustical emitter structure, which is configured to emit and direct a first parametric ultrasonic wave corresponding to the first parametric ultrasonic channel signal at the listener such that a first resultant decoupled audio wave will be heard substantially exclusively at the first ear of the listener, with minimal audible sound at a second ear of the listener.
Additional features and advantages of the invention will be apparent from the detailed description which follows, taken in conjunction with the accompanying drawings, which together illustrate, by way of example, features of the invention.
The following drawings illustrate exemplary embodiments for carrying out the invention. Like reference numerals refer to like parts in different views or embodiments of the present invention in the drawings.
a is a reference diagram for
b is a block diagram of a conventional audio system.
c is flow diagram illustrating the complexities of a parametric audio system, and defining the terminology of a parametric audio system.
d is an alteration of
a is an illustration of a sound source heard by a listener.
b is an illustration of a conventional audio system's attempt to reproduce the sound source of
c is an illustration of a prior art method for eliminating cross-talk between the output of conventional speakers.
a is an illustration of a parametric loudspeaker system using two electro-acoustical emitters and providing acoustically differentiable sound to a listener, in accordance with one embodiment of the invention.
b is an illustration of a parametric loudspeaker system using two electro-acoustical emitters and providing acoustically differentiable sound to a listener, in accordance with another embodiment of the invention.
a and 14b are illustrations of a parametric loudspeaker system that is capable of directing an emitted wave towards a moving target element, by adjusting the emission surface of the emitter.
a and 15b are illustrations of a parametric loudspeaker system that is capable of directing multiple emitted waves towards multiple moving target elements, by adjusting the emission surfaces of two emitters.
Reference will now be made to the exemplary embodiments illustrated in the drawings, and specific language will be used herein to describe the same. It will nevertheless be understood that no limitation of the scope of the invention is thereby intended. Alterations and further modifications of the inventive features illustrated herein, and additional applications of the principles of the inventions as illustrated herein, which would occur to one skilled in the relevant art and having possession of this disclosure, are to be considered within the scope of the invention.
Because parametric sound is a relatively new and developing field, and in order to identify the distinctions between parametric sound and conventional audio systems, the following definitions, along with the explanatory diagrams of
a serves the purpose of establishing the meanings that will be attached to various block diagram shapes in
The block labeled 102 will represent any acoustic compression wave. As opposed to an audio signal, which is in electronic form, an acoustic compression wave is propagated into the air. The block 102 representing acoustic compression waves will be used whether the compression wave corresponds to a sonic wave, an ultrasonic wave, or a parametric ultrasonic wave. Throughout this application, any time the word ‘wave’ is used, it refers to an acoustic compression wave which is propagated into the air.
The block labeled 104 will represent any process that changes or affects the audio signal or wave passing through the process. The audio passing through the process may either be an electronic audio signal or an acoustic compression wave. The process may either be a manufactured process, such as a signal processor or an emitter, or a natural process such as parametric sound generation using an air medium.
The block labeled 106 will represent the actual audible sound that results from an acoustic compression wave. Examples of audible sound may be the sound heard in the ear of a user, or the sound sensed by a microphone.
b is a flow diagram 110 of a conventional audio system. In a conventional audio system, an audio input signal 111 is supplied which is an electronic representation of the audio wave being reproduced. The audio input signal 111 may optionally pass through an audio signal processor 112. The audio signal processor is usually limited to linear processing, such as the amplification of certain frequencies and attenuation of others. Very rarely, the audio signal processor 112 may apply non-linear processing to the audio input signal 111 in order to adjust for non-linear distortion that may be directly introduced by the emitter 116. If the audio signal processor 112 is used, it produces an audio processed signal 114.
The audio processed signal 114 or the audio input signal 111 (if the audio signal processor 112 is not used) is then emitted from the emitter 116. As discussed in the section labeled ‘related art’, conventional sound systems typically employ dynamic speakers as their emitter source. Dynamic speakers are typically comprised of a simple combination of a magnet, voice coil and cone. The magnet and voice coil convert the variable voltage of the audio processed signal 114 to mechanical displacement, representing a first stage within the dynamic speaker as a conventional multistage transducer. The attached cone provides a second stage of impedance matching between the electrical transducer and air envelope surrounding the emitter 116, enabling transmission of small vibrations of the voice coil to emerge as expansive acoustic audio wave 118. The acoustic audio wave 118 proceeds to travel through the air 120, with the air substantially serving as a linear medium. Finally, the acoustic audio wave reaches the ear of a listener, who hears audible sound 122.
c is a flow diagram 130 that clearly highlights the complexity of a parametric sound system as compared to the conventional audio system of
The audio processed signal 134 or the audio input signal 131 (if the audio signal processor 132 is not used) is then parametrically modulated with an ultrasonic carrier signal 136 using a parametric modulator 138. The ultrasonic carrier signal 136 may be supplied by any ultrasonic signal source. While the ultrasonic carrier signal 136 is normally fixed at a constant ultrasonic frequency, it is possible to have an ultrasonic carrier signal that varies in frequency. The parametric modulator 138 is configured to produce a parametric ultrasonic signal 140, which is comprised of an ultrasonic carrier signal, which is normally fixed at a constant frequency, and at least one sideband signal, wherein the sideband signal frequencies vary such that the difference between the sideband signal frequencies and the ultrasonic carrier signal frequency are the same frequency as the audio input signal 131. The parametric modulator 138 may be configured to produce a parametric ultrasonic signal 140 that either contains one sideband signal (single sideband modulation, or SSB), or both upper and lower sidebands (double sideband modulation, or DSB).
Normally, the parametric ultrasonic signal 140 is then emitted from the emitter 146, producing a parametric ultrasonic wave 148 which is propagated into the air 150. The parametric ultrasonic wave 148 is comprised of an ultrasonic carrier wave and at least one sideband wave. The parametric ultrasonic wave 148 drives the air into a substantially non-linear state. Because the air serves as a non-linear medium, acoustic heterodyning occurs on the parametric ultrasonic wave 148, causing the ultrasonic carrier wave and the at least one sideband wave to decouple in air, producing a decoupled audio wave 152 whose frequency is the difference between the ultrasonic carrier wave frequency and the sideband wave frequencies. Finally, the decoupled audio wave 152 reaches the ear of a listener, who hears audible sound 154. The end goal of parametric audio systems is for the decoupled audio wave 152 to closely correspond to the original audio input signal 131, such that the audible sound 154 is ‘pure sound’, or the exact representation of the audio input signal.
d is an alteration of
In addition to undesirable aesthetic effects, it is very difficult to perfectly reproduce a virtual sound source using multiple conventional speakers.
b illustrates a simple attempt to employ conventional loudspeakers 350 to reproduce sound. In this simple example, left 352 and right 354 speakers are provided. To reproduce the sound source shown 302 in
Elaborate cross-talk cancellation techniques have been used in an attempt to overcome the crosstalk that inevitably exists when multiple conventional speakers are used. Signals are sent by each speaker which are intended to arrive at the ears of the user 180° out of phase with the cross-talk signals in order to cancel their effects. However, because of the omnidirectional nature of conventional speakers, the cancellation wave will inevitably reach both ears, which in turn creates additional cross talk signals which also must be canceled. The perpetual nature of this comb filtering techniques may cause tonal coloration to the sound, causing voices to sound unnatural.
An additional problem is that conventional speakers will inevitably produce reflection waves 376 from side walls 374, ceilings, and floors. The additional waves produced by room interaction interfere with the primary waves 368, 370, 372 and 374, further misrepresenting the location of the virtual sound source. Because of the aforementioned problems, previous attempt to produce true binaural sound using conventional speakers, have had limited commercial or technical success.
Because of the extensive cross-talk cancellation techniques that must be used to approximate true binaural sound with conventional speakers, the most effective prior art method for controlling crosstalk is illustrated in
Thus far, the only practical method for eliminating the crosstalk described above has been for the listener to wear headphones, which isolate the sound heard by each ear. Impressive results can be achieved by listening to a binaural recording through headphones, which employ various phase and volume control techniques to accurately enable the listener to pinpoint the virtual sound source. Unfortunately, as shown in
As illustrated in
In another embodiment, as illustrated in
In the context of the present invention, “acoustic differentiation of amplitudes” signifies that if a wave is intended to be heard at a first ear of a listener, it will either be undetected by the second ear, or will be detected by the second ear at a significantly lower amplitude than at the first ear. When acoustic differentiation of amplitudes is realized, many benefits can be attained, such as true binaural sound production. As described above, acoustic differentiation of amplitudes arriving at each ear of the listener has been impractical using conventional speakers. However, because of the directional nature of parametric loudspeakers, it is possible to emit one parametric ultrasonic wave that is detectable by the first ear of a listener, and substantially undetectable at the second ear. Likewise, a second parametric ultrasonic wave may be emitted that is detectable by the second ear of the listener, and substantially undetectable at the first ear. Therefore, acoustic differentiation of amplitudes arriving at each ear of the listener is enabled.
To attain acoustic differentiation of amplitudes arriving at each ear, it may be beneficial that the first decoupled audio wave is arrive at the first ear at an acoustic level of at least six dB greater than at the second ear, and the second decoupled audio wave arrive at the second ear at an acoustic level of at least six dB greater than at the first ear. When a six dB difference exists between the acoustic levels arriving at each ear of a listener, the listener obtains a substantial sense of acoustic differentiation of amplitudes.
In another embodiment, the first decoupled audio wave is configured to arrive at the first ear at an acoustic level of at least fifteen dB greater than at the second ear, and the second decoupled audio wave is configured to arrive at the second ear at an acoustic level of at least fifteen dB greater than at the first ear. When a fifteen dB difference exists between the acoustic levels arriving at each ear of a listener, the listener effectively obtains a sense of full acoustic differentiation of amplitudes.
In one embodiment of the system of
In one embodiment of the virtual headset employing more than one channel, the second parametric ultrasonic channel signal is identical to the first. If such is the case, only one audio input signal 161 (
The parametric ultrasonic emitter structure may include a piezoelectric film configured for emitting parametric ultrasonic waves. The present inventors have previously discovered and disclosed that a piezoelectric film is an ideal material for emitting parametric ultrasonic waves. Various types of film may be used as the emitter film. The important criteria are that the film be capable of responding to an applied electrical signal to constrict and extend in a manner that reproduces an acoustic output corresponding to the signal content. Although piezoelectric materials are the primary materials that supply these design elements, new polymers are being developed that are technically not piezoelectric in nature. Nevertheless, the polymers are electrically sensitive and mechanically responsive in a manner similar to the traditional piezoelectric compositions. Accordingly, it should be understood that reference to piezoelectric films in this application is intended to extend to any suitable film that is both electrically sensitive and mechanically responsive (ESMR) so that acoustic waves can be realized in the subject transducer.
The virtual headset may be configured to perform differential phase controlling of the propagated wave at an emission surface of the electro-acoustical emitter such that the orientation of the propagated wave may be controlled. To simplify the explanation of phase controlling of the propagated wave, an example is provided involving only a single channel and corresponding ultrasonic wave. To enable phase controlling of the propagated wave, the emission surface of the electro-acoustical emitter 508 structure may be divided into multiple isolated emitting portions 508a. Each isolated emitting portion is driven by the parametric ultrasonic signal source, wherein at least one isolated emitting portion is driven with a signal having a phase differential as compared to the other isolated emitting portions. The amount of phase differential causes the orientation of the resultant parametric wave to be beam steered, or directed towards a desired location. As illustrated in
The phase controlling technique described above may also be employed where more than one parametric ultrasonic wave is emitted from a single emitter, as shown in
a illustrates another embodiment of the invention, comprising a parametric loudspeaker system 900 for enabling isolated listening to audio material at a first 902 and a second 904 ear of a listener 906. A first parametric ultrasonic signal source 908 supplies a first parametric ultrasonic channel signal having an ultrasonic carrier signal and at least one sideband. The first parametric ultrasonic channel signal is configured to be emitted and directed substantially exclusively at the first ear 902 of the listener 906. A second parametric ultrasonic signal source 910 supplies a second parametric ultrasonic channel signal having an ultrasonic carrier signal and at least one sideband. The second parametric ultrasonic channel signal is configured to be emitted and directed substantially exclusively at the second ear 904 of the listener 906. A first electro-acoustical emitter 912 is coupled to the first parametric ultrasonic signal source 908, and is capable of orienting a first parametric ultrasonic wave 914 corresponding to the first channel signal at the first ear 902, wherein a resultant first decoupled audio wave 914a is detected by the first ear 902 at an acoustic level substantially greater than at the second ear 904. A second parametric ultrasonic emitter 916 is coupled to the second parametric ultrasonic signal source 910, and is capable of orienting a second parametric ultrasonic wave 918 corresponding to the second channel signal for detection at the second ear 904, wherein a resultant second decoupled audio wave 918a is detected by the second ear 904 at an acoustic level substantial greater than at the first ear 902. As a result, acoustic differentiation of amplitudes arriving at each ear is thereby enabled.
Instead of projecting the first and second ultrasonic waves past the user, as illustrated in
In another embodiment of
While
An example of a focusing parametric transducer as described in
The above systems are primarily configured for a listener standing or sitting in one predefined location. These embodiments are ideal when the listener is watching a movie or television, sitting at a computer, playing video games; and various other uses that do not require or promote movement by the listener.
However, it may be beneficial to enable a listener to move while using the disclosed invention. For this purpose, the virtual headset may include a tracking circuit coupled to the parametric ultrasonic emitter structure for coordinating movement of a directional orientation of the emitted parametric ultrasonic waves to follow movement of a target element. Typically, the target element is the listener, or a device worn by the listener. A feedback loop may be provided, where the tracking circuit determines the location of the target element, and directs the parametric ultrasonic wave towards the target element in a substantially continuous manner.
Various techniques may be used to enable the emitted parametric ultrasonic waves to follow the target element. First, the phase controlling of the propagated wave may adjust the phase differential of the signals applied to each isolated emitting portion of the emission surface in response to the location of the target element. The changing phase differential will cause the orientation of the emitted parametric ultrasonic waves to follow the target element. For example,
a and 14b illustrate another technique used to enable the emitted parametric ultrasonic waves to follow the target element. Here, the electro-acoustical emitter 1402 includes a directional support structure 1404 configured to rotate in response to the movement of the target element. Thus, the orientation of the emission surface 1406 of the emitter 1402 will react accordingly, enabling the first parametric ultrasonic wave 1408 to follow movement of the target element. For example, when the listener 1410 moves from the position shown in
a and 15b illustrate a slightly more complex example of an emitter structure whose directional supports 1502 rotate to enable the emitted parametric ultrasonic waves 1504 and 1506 to follow the target element. In this example, two electro-acoustical emitters 1508 and 1510 are employed, each having directional support structures 1502 configured to rotate in response to the movement of the target element. Thus, the orientation of the emission surfaces 1509 and 1511 of the first and second electro-acoustical emitters 1508 and 1510 will be adjusted, enabling the first 1504 and second 1506 parametric ultrasonic waves to follow movement of the target element. There may be a separate target element which corresponds to each electro-acoustical emitter. In the present example, the first 1512 and second 1514 ears of a listener 1516 each serve as a target element. As the listener moves from the position shown in
In addition to producing audio, the above systems may also be used to eliminate unwanted noise at the ears of the listener. Traditionally, sound elimination has been difficult when the noise eliminating apparatus has not been placed in close proximity to the ears of the listener. The reason for this difficulty is because conventional loudspeakers were unable to focus a compression wave on the exact region where noise was to be eliminated. Instead, the emitted compression wave containing the noise-eliminating signal was dispersed over a comparatively large region, with only a fraction of the wave arriving at the area where noise was to be eliminated. Because of this difficulty, most effective noise elimination devices have traditionally been headphones, where unwanted noise could be eliminated directly at the ears of the listener. Using the technology disclosed in the present invention, effective noise elimination can be realized without the need of earphones or other physical audio producing devices attached to the listener. By including a noise cancellation circuit, a parametric ultrasonic wave containing noise cancellation information can be emitted from across a room, and can arrive directly at the ears of the user, where noise cancellation is desired.
In accordance with
In accordance with
In one embodiment, the orientation control technique employed in step 1806 may include the differential phase controlling technique described in
In accordance with
In accordance with
The listening locations of the methods 1700, 1900, and 2000 may be a predefined area wherein the first and second reception points are located. For example, the listening locations may be comprised of a three-dimensional volume, no larger than five foot by five foot by five foot in size, wherein the first and second reception points are located. Alternatively, the listening locations may be comprised of a personal space for an individual listener. In another embodiment, the listening locations may be comprised of an approximate environment surrounding a chair, wherein a listener may be situated.
The respective first and second reception points of the methods 1700, 1900, and 2000 may be first and second microphones, both situated within the listening location. In another embodiment, the respective first and second reception points are left and right ears of a listener, where the listener is the listening location.
In one embodiment, the above methods may include more than one listening location, each listening location having individual first and second reception points. By way of example,
The above embodiments of the invention have many useful applications in addition to providing audio to a listener in a home entertainment system setting. For example, the invention may be included in commercial theaters to provide each audience member with a full surround-sound experience. The invention may also be used in video games, either in a user's home, or at a video arcade. Similarly, the invention may be included on amusement rides to provide the effect that sounds are approaching from various directions. Another application may be to include one or more of the above embodiments in a vehicle, such that each occupant of the car may enjoy a full surround-sound experience. Many other entertainment applications may be apparent to one skilled in the art.
In addition to entertainment applications, the present invention may have other uses, such as providing warning signals in various settings. For example, the invention may provide a driver of a vehicle with a warning sound signal indicating the direction from which another object is approaching the vehicle. Because of the binaural sound capabilities of the present invention, a virtual sound source can be created indicating the exact direction from which the object is approaching. Another similar application includes warning a pilot, either in an actual plane or in a flight simulator, of an approaching object. Similarly, an engineer of a train or a trolley may be provided with warning signals indicating the direction of oncoming cars, pedestrians, or other objects. Participants in various sport may also benefit from a warning signal being provided to indicate the position of nearby objects, such as other participants. As another application, a person who has poor vision, or total loss of vision, may be provided with sound signals indicating the position of objects in the environment surrounding him or her.
It is to be understood that the above-referenced arrangements are illustrative of the application for the principles of the present invention. Numerous modifications and alternative arrangements can be devised without departing from the spirit and scope of the present invention while the present invention has been shown in the drawings and described above in connection with the exemplary embodiments(s) of the invention. It will be apparent to those of ordinary skill in the art that numerous modifications can be made without departing from the principles and concepts of the invention as set forth in the claims.
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/US04/33308 | 10/8/2004 | WO | 12/28/2006 |
| Number | Date | Country | |
|---|---|---|---|
| 60509731 | Oct 2003 | US |
