Embodiments of the invention relate to the field of rendering of audio by a loudspeaker; and more specifically, to environmentally compensated audio rendering.
It is desirable to reproduce a sound recording so that it sounds as natural as in the original recording environment. The approach is to create around the listener a sound field whose spatial distribution more closely approximates that of the original recording environment. Early experiments in this field have revealed for example that outputting a music signal through a loudspeaker in front of a listener and a slightly delayed version of the same signal through a loudspeaker that is behind the listener gives the listener the impression that he is in a large room and music is being played in front of him. The arrangement may be improved by adding a further loudspeaker to the left of the listener and another to his right, and feeding the same signal to these side speakers with a delay that is different than the one between the front and rear loudspeakers. But using multiple speakers increases the cost and complexity of an audio system.
Loudspeaker reproduction is affected by nearby obstacles, such as walls. Such acoustic boundaries create reflections of the sound emitted by a loudspeaker. The reflections may enhance or degrade the sound. The effect of the reflections may vary depending on the frequency of the sound. Lower frequencies, particularly those below about 400 Hz, may be particularly susceptible to the effects of reflections from acoustic boundaries.
It would be desirable to provide an easier and more effective way to provide a natural sounding reproduction of a sound recording with fewer loudspeakers.
An audio system includes one or more loudspeaker cabinets, each having loudspeakers. Sensing logic determines an acoustic environment of the loudspeaker cabinets. The sensing logic may include an echo canceller. A low frequency filter corrects an audio program based on the acoustic environment of the loudspeaker cabinets. The system outputs an omnidirectional sound pattern, which may be low frequency sound, to determine the acoustic environment. The system may produce a directional pattern superimposed on an omnidirectional pattern, if the acoustic environment is in free space. The system may aim ambient content toward a wall and direct content away from the wall, if the acoustic environment is not in free space. The sensing logic automatically determines the acoustic environment upon initial power up and when position changes of loudspeaker cabinets are detected. Accelerometers may detect position changes of the loudspeaker cabinets.
Other features and advantages of the present invention will be apparent from the accompanying drawings and from the detailed description that follows below.
The invention may best be understood by referring to the following description and accompanying drawings that are used to illustrate embodiments of the invention by way of example and not limitation. In the drawings, in which like reference numerals indicate similar elements:
In the following description, numerous specific details are set forth. However, it is understood that embodiments of the invention may be practiced without these specific details. In other instances, well-known circuits, structures and techniques have not been shown in detail in order not to obscure the understanding of this description.
In the following description, reference is made to the accompanying drawings, which illustrate several embodiments of the present invention. It is understood that other embodiments may be utilized, and mechanical compositional, structural, electrical, and operational changes may be made without departing from the spirit and scope of the present disclosure. The following detailed description is not to be taken in a limiting sense, and the scope of the embodiments of the present invention is defined only by the claims of the issued patent.
The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. Spatially relative terms, such as “beneath”, “below”, “lower”, “above”, “upper”, and the like may be used herein for ease of description to describe one element's or feature's relationship to another element(s) or feature(s) as illustrated in the figures. It will be understood that the spatially relative terms are intended to encompass different orientations of the device in use or operation in addition to the orientation depicted in the figures. For example, if the device in the figures is turned over, elements described as “below” or “beneath” other elements or features would then be oriented “above” the other elements or features. Thus, the exemplary term “below” can encompass both an orientation of above and below. The device may be otherwise oriented (e.g., rotated 90 degrees or at other orientations) and the spatially relative descriptors used herein interpreted accordingly.
As used herein, the singular forms “a”, “an”, and “the” are intended to include the plural forms as well, unless the context indicates otherwise. It will be further understood that the terms “comprises” and/or “comprising” specify the presence of stated features, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, steps, operations, elements, components, and/or groups thereof.
The terms “or” and “and/or” as used herein are to be interpreted as inclusive or meaning any one or any combination. Therefore, “A, B or C” or “A, B and/or C” mean “any of the following: A; B; C; A and B; A and C; B and C; A, B and C.” An exception to this definition will occur only when a combination of elements, functions, steps or acts are in some way inherently mutually exclusive.
The sensing logic and the low frequency correction filter may use techniques disclosed in U.S. patent application Ser. No. 14/989,727, filed Jan. 6, 2016, titled LOUDSPEAKER EQUALIZER, which application is specifically incorporated herein, in its entirety, by reference.
Nine audio amplifiers 214 each provide an output coupled to an input of one of the nine loudspeaker drivers 202, 204. One audio amplifier is associated with each loudspeaker driver. Only one of the audio amplifiers is shown and the signal connections between the audio amplifiers and the loudspeaker drivers are omitted for clarity of illustration. The additional audio amplifiers and their connections to the loudspeaker drivers are suggested by ellipsis.
Sensing logic 208 determines an acoustic environment of the loudspeaker cabinet 200 as described below. One or more low frequency correction filters 212 receives an audio program 210 and produces an audio signal that corrects the audio program for room effects based on the acoustic environment of the loudspeaker cabinet 200 as described below. A low frequency correction filter 212 may be provided for every driver 202, 204 in the loudspeaker cabinet 200 or for only some of drivers, such as the drivers that provide the low frequency output, e.g. woofers and/or sub-woofers. The additional low frequency correction filters and their connections to the audio amplifiers are suggested by ellipsis for clarity.
Seven audio amplifiers 314 each provide an output coupled to an input of one of the seven loudspeaker drivers. One audio amplifier is associated with each loudspeaker driver. Only one of the audio amplifiers is shown and the signal connections between the audio amplifiers and the loudspeaker drivers are omitted for clarity of illustration.
Sensing logic 308 determines an acoustic environment for each of the loudspeaker cabinets 300A, 300B as described below. Two or more low frequency correction filters 312 each receive a channel of an audio program 310 and produce an audio signal that corrects the channel of the audio program for room effects based on the acoustic environment for each of the loudspeaker cabinets 300A, 300B as described below. A low frequency correction filter 312 may be provided for every driver 302, 304 in each of the loudspeaker cabinets 300A, 300B or for only some of drivers, such as the drivers that provide the low frequency output, e.g. woofers and/or sub-woofers. A low frequency correction filter may be provided for drivers in some, but not all, of the loudspeaker cabinets in an audio system that embodies the invention.
It will be appreciated that an audio system that includes two or more loudspeaker cabinets, may have one or more loudspeaker drivers arranged in various configurations, such as the configurations illustrated in
Audio systems that embody the invention include sensing logic to determine the acoustic environment of the loudspeaker drivers in the loudspeaker cabinets. It will be appreciated that the performance of loudspeaker drivers is affected by acoustic obstacles, such as walls, that can reflect and/or absorb sounds being output by the loudspeaker drivers. The acoustic properties of acoustic obstacles may be frequency dependent. Reflections may reinforce or cancel the sounds produced by the loudspeaker drivers depending on the position of the reflective acoustic surface and the frequency of the sound.
Eight audio amplifiers 414 each provide an output coupled to an input of one of the eight loudspeaker drivers 404. One audio amplifier is associated with each loudspeaker driver. Only one of the audio amplifiers is shown and the signal connections between the audio amplifiers and the loudspeaker drivers are omitted for clarity of illustration. The additional audio amplifiers and their connections to the loudspeaker drivers are suggested by ellipsis.
Sensing logic 408 determines an acoustic environment of the loudspeaker cabinet 400 as described below. A playback mode processor receives an audio program 410 and produces an audio signal that adjusts the audio program for room effects based on the acoustic environment of the loudspeaker cabinet 400 as described below. The playback mode processor is to adjust the audio program responsive to the acoustic environment of each of the one or more loudspeaker cabinets, and provide the one or more audio signals to the one or more audio amplifiers to output the corrected audio program through the one or more loudspeaker drivers in each of the one or more loudspeaker cabinets
Referring again to
The sensing logic 108 operates in part on information relating to signals received on microphones 118 that are responsive to the sound at the outer boundaries of the loudspeaker cabinet 100, and to those produced by various loudspeakers 102, which may be estimated by a microphone 116 inside the loudspeaker cabinet. The sensing logic 108 does so by looking, for example, at transfer function measurements between microphones 116, 118 and between loudspeakers 102 and microphones 118. The sensing logic 108 may receive a signal from an external microphone 118, which may be on an exterior surface of the loudspeaker cabinet 100 or placed to detect sound pressure levels near the exterior surface. For the purposes of this application the phrases “external microphone” and “microphone on the exterior of a loudspeaker cabinet” mean a microphone placed so that it produces signals responsive to sound pressure levels near the exterior surface of the loudspeaker cabinet.
The sensing logic 108 compares the signal from the external microphone 118 to a signal that indicates the amount of sound energy being output by the speaker driver 102. The indication of driver output sound energy may be provided by an internal microphone 116. In other embodiments, the indication of driver output sound energy may be provided by an optical system that measures the displacement of a speaker cone for the loudspeaker driver or an electrical system that derives the indication of driver output sound energy from the electrical energy being provided to the loudspeaker driver.
The sensing logic 108 estimates an acoustic path between the loudspeaker driver 102 in the loudspeaker cabinet 100 and the microphone 118 on the exterior of the loudspeaker cabinet. The sensing logic 108 may include an echo canceller to estimate the acoustic path between the loudspeaker driver 102 and the microphone 118.
The sensing logic may use other techniques to estimate the acoustic path between the loudspeaker driver and the microphone such as the techniques disclosed in U.S. patent application Ser. No. 14/920,611, filed Oct. 22, 2015, titled ENVIRONMENT SENSING USING COUPLED MICROPHONES AND LOUDSPEAKERS AND NOMINAL PLAYBACK, which application is specifically incorporated herein, in its entirety, by reference.
The sensing logic 108 may categorize the acoustic environment of the loudspeaker cabinet as being in free space, where there are no acoustic obstacles or boundaries close enough to the loudspeaker cabinet to significantly affect the sound produced by the loudspeaker drivers in the loudspeaker cabinet. For the purposes of this application the phrase “significantly affect the sound” means altering the sound to an extent that would be perceived by a listener without using a measuring apparatus. It may be assumed that the loudspeaker cabinet is designed to be supported on a surface in a way that the effects of the support surface are part of the sound intended to be produced. Thus, the support surface may not be considered to be an acoustic obstacle or boundary. A loudspeaker cabinet is in free space if it is sufficiently away from all walls and large pieces of furniture to avoid significant acoustic reflections from such obstacles.
When there are acoustic obstacles or boundaries close enough to the loudspeaker cabinet to significantly affect the sound produced by the loudspeaker drivers in the loudspeaker cabinet, i.e. when the loudspeaker cabinet is not in free space, the sensing logic 108 may further categorize the acoustic environment of the loudspeaker cabinet. The further categorization may be based on typical placements of the loudspeaker cabinet. For example, the acoustic environment may be further categorized as near a wall if there is a single reflective acoustic surface near the loudspeaker cabinet. The acoustic environment may be further categorized as in a corner if there are two reflective acoustic surfaces at right angles to each other near the loudspeaker cabinet. The acoustic environment may be further categorized as in a bookcase if there are three reflective acoustic surfaces at right angles to each other near the loudspeaker cabinet with one acoustic surface parallel to the support surface for the loudspeaker cabinet.
Referring again to
The playback mode processor 220 adjusts the portion of the audio program 210 directed to a loudspeaker cabinet 200 to affect how the audio program is output by the multiple loudspeaker drivers 202, 204 in the loudspeaker cabinet. The playback mode processor 220 will have multiple outputs for the multiple loudspeaker drivers as suggested by ellipsis for clarity. The low frequency correction filter 212, if used for a particular driver, may be placed before or after the playback mode processor 220.
The playback mode processor 220 may adjust the audio program 210 to output portions of the audio program in particular directions from the loudspeaker cabinet 200. Sound output directions may be controlled by directing portions of the audio program to loudspeaker drivers that are oriented in the desired direction. Some loudspeaker cabinets may include loudspeaker drivers that are arranged as a speaker array. The playback mode processor may control sound output directions by causing a speaker array to emit a beamformed sound pattern in the desired direction.
The playback mode processor 220 may adjust the audio program 210 to cause the loudspeaker drivers 202, 204 to produce a directional pattern superimposed on an omnidirectional pattern, if the acoustic environment is in free space. The directional pattern may include portions of the audio program 210 that are spatially located in the sound field, e.g. portions unique to a left or right channel. The directional pattern may be limited to higher frequency portions of the audio program 210, for example portions above 400 Hz, which a listener can more specifically locate spatially. The omnidirectional pattern may include portions of the audio program 210 that are heard throughout the sound field, e.g. portions common to both the left and right channels. The omnidirectional pattern may include lower frequency portions of the audio program 210, for example portions below 400 Hz, which are difficult for a listener to locate spatially.
The playback mode processor 220 may adjust the audio program 210 to cause the loudspeaker drivers 202, 204 to aim ambient content of the audio program toward a wall and to aim direct content of the audio program away from the wall, if the acoustic environment is not in free space.
If the acoustic environment is categorized as in a bookcase, the playback mode processor 220 may adjust the audio program 210 to cause the loudspeaker drivers 202, 204 to form a highly directional beam directed out of the bookcase.
The playback mode processor may adjust the audio program using techniques described in U.S. patent application Ser. No. 15/593,887, filed May 12, 2017, titled SPATIAL AUDIO RENDERING STRATEGIES FOR BEAMFORMING LOUDSPEAKER ARRAY, which application is specifically incorporated herein, in its entirety, by reference. The playback mode processor may separate the ambient content of the audio program from the direct content using techniques described in U.S. patent application Ser. No. 15/275,312, filed Sep. 23, 2016, titled CONSTRAINED LEAST-SQUARES AMBIENCE EXTRACTION FROM STEREO SIGNALS, which application is specifically incorporated herein, in its entirety, by reference.
The sensing logic 208 may make implicit assumptions on which signals and sound sources dominate various loudspeakers and microphones when the sensing logic 208 is making use of such metrics. Also, practically, it must also be true that there are sufficient signal levels, above internal device and environmental noises, in operation to allow for valid measurements and analyses. Such levels and transfer functions, and assumptions in their estimation, can be required in various frequency bands, during various time intervals, or during various “modes” of operation of the device.
Outside of a lab or controlled setting, in a real deployment of the device, it is necessary to ensure that the sensing logic 208 algorithms operate under such valid assumptions, as are necessary for a particular sensing logic operation and decision. To help ensure that the sensing logic 208 is operating with valid inputs, the sensing logic may include “oversight” logic.
Oversight logic, in its simplest form, takes in various signals and makes absolute and relative signal level measurements and comparisons. In particular, the oversight logic checks these measurements and comparisons against various targets and tuned assumptions, which constitute tests, and flags issues whenever one or more tests/assumptions are violated. The oversight logic can probe such flags to check the status of various tests before making sensing logic decisions and changes. Flags can also, optionally, drive or gate various “estimators” in the sensing logic, warning them that necessary assumptions or conditions are being violated.
The oversight logic is designed to be flexible in that it can be tuned to look at one or more user-defined frequency bands, it can take in one or more microphone signals, and it can be tuned with various absolute and relative signal level targets by the user. The oversight logic may have modes where one or more tests are either included or excluded, depending on the scenario what the sensing logic needs this particular oversight logic to do.
The oversight logic accommodates real audio signals, which are quite dynamic in time and frequency. This is especially true for music and speech. The “level” target may be dynamic to accommodate real audio signals. The “level” target may be statistical targets. The oversight logic may collect a particular type of measurement over short time intervals, e.g. intervals in the 10s to 100s of msec., which may be a user defined interval, and accumulates a number of such measurements over long time intervals, e.g. intervals in the order of 100s of msec. to seconds, which may also be a user defined interval. Passing a target for this measurement type is then defined by a target level and a proportion, where the “short” measurements, as collected over the defined “long” interval, meeting the target level must exceed the define proportion in order to pass the test. Setting such levels and proportions may relate to the frequency band of interest and the type of signals expected.
The sensing logic 208 may collect a number measurements from each of the microphones used by the sensing logic over a first period of time. Each of the measurements is taken for a second period of time that is shorter than the first period of time. The sensing logic 208 compares each of the measurements to a target level to determine a proportion of the measurements that meet the target level. The second period of time may be between 10 milliseconds and 500 milliseconds and the first period of time may be at least ten times the second period of time.
The sensing logic 208 may disable application of the low frequency correction filter 212 and determination of the acoustic environment of the audio system if the proportion of the plurality measurements that meet the target level is below a threshold value.
The sensing logic 208 may automatically determine the acoustic environment of the audio system upon initial power up of the audio system, without requiring any intervention by a user of the audio system. The sensing logic 208 may further detect when there has been a change in the acoustic environment of a loudspeaker cabinet and automatically re-determine the acoustic environment of the audio system, again without requiring any intervention by the user of the audio system. The acoustic environment may be changed by moving the loudspeaker cabinet or by placing an acoustic obstacle near the loudspeaker cabinet. The change in the acoustic environment of the loudspeaker cabinet may be detected by changes in the audio characteristics.
In some embodiments, an accelerometer 222 is coupled to the loudspeaker cabinet 200 to detect a change in the position of the loudspeaker cabinet. This may allow changes in position to be detected more quickly.
The sensing logic 208 may detect changes in the acoustic environment of a loudspeaker cabinet using techniques described in U.S. patent application Ser. No. 15/611,083, filed Jun. 1, 2017, ACOUSTIC CHANGE DETECTION, which application is specifically incorporated herein, in its entirety, by reference.
If change in the acoustic environment of a loudspeaker cabinet is detected, the sensing logic 208 may fade back to omnidirectional mode and start the calibration procedure. The recalibration is largely transparent to the user. The user may hear some sort of optimization but nothing dramatic.
The low frequency correction filter 212 and/or the playback mode processor 220 may be responsive to the re-determined acoustic environment after the loudspeaker cabinet is moved.
Referring again to
For example, if the acoustic environment is in free space, the playback mode processor 320 may adjust the audio program 310 to cause the loudspeaker drivers 302, 304 to produce a directional pattern superimposed on an omnidirectional pattern. The omnidirectional pattern may be the same for both loudspeaker cabinets 302A, 302B while the directional patterns are specific to each loudspeaker cabinet. The directional patterns may be directed to complement each other, such as aiming the patterns somewhat away from another loudspeaker cabinet to provide a more spread out sound.
As another example, if the acoustic environment is not in free space, the playback mode processor 320 may adjust the audio program 310 to cause the loudspeaker drivers 202, 204 to aim ambient content of the audio program toward a wall and to aim direct content of the audio program away from the wall. If there are multiple loudspeaker cabinets 302A, 302B, the ambient content may be separated to place the ambient content according to the positions of the loudspeaker cabinets. For example, with two loudspeaker cabinets 302A, 302B, the ambient content may be separated into left ambient and right ambient and sent to the left and right loudspeaker cabinets respectively. The direct content may be similarly directed to appropriately positioned loudspeaker cabinets.
The playback mode processor adjust the audio program using techniques disclosed in U.S. patent application Ser. No. 15/311,824, filed Nov. 16, 2016, titled USING THE LOCATION OF A NEAR-END USER IN A VIDEO STREAM TO ADJUST AUDIO SETTINGS OF A FAR-END SYSTEM, which application is specifically incorporated herein, in its entirety, by reference.
Referring again to
The playback mode processor 420 may adjust the audio program 410 to output portions of the audio program in particular directions from the loudspeaker cabinet 400. Sound output directions may be controlled by directing portions of the audio program to loudspeaker drivers that are oriented in the desired direction.
The playback mode processor 420 may adjust the audio program 410 to cause the loudspeaker drivers 402, 404 to produce a directional pattern superimposed on an omnidirectional pattern, if the acoustic environment is in free space. The directional pattern may include portions of the audio program 410 that are spatially located in the sound field, e.g. portions unique to a left or right channel. The directional pattern may be limited to higher frequency portions of the audio program 410, for example portions above 400 Hz, which a listener can more specifically locate spatially. The omnidirectional pattern may include portions of the audio program 410 that are heard throughout the sound field, e.g. portions common to both the left and right channels. The omnidirectional pattern may include lower frequency portions of the audio program 410, for example portions below 400 Hz, which are difficult for a listener to locate spatially.
The playback mode processor 420 may adjust the audio program 410 to cause the loudspeaker drivers 404 to aim ambient content of the audio program toward a wall and to aim direct content of the audio program away from the wall, if the acoustic environment is not in free space.
The sensing logic 408 may use oversight logic as described above for the system shown in
In some embodiments, an accelerometer 422 is coupled to the loudspeaker cabinet 400 to detect a change in the position of the loudspeaker cabinet. This may allow changes in position to be detected more quickly.
If a change in the acoustic environment of a loudspeaker cabinet is detected, the sensing logic 408 may fade back to omnidirectional mode and start the calibration procedure. The recalibration is largely transparent to the user. The user may hear some sort of optimization but nothing dramatic. The playback mode processor 420 may be responsive to the re-determined acoustic environment after the loudspeaker cabinet is moved.
While certain exemplary embodiments have been described and shown in the accompanying drawings, it is to be understood that such embodiments are merely illustrative of and not restrictive on the broad invention, and that this invention is not limited to the specific constructions and arrangements shown and described, since various other modifications may occur to those of ordinary skill in the art. Not every step or element described is necessary in audio systems that embody the invention. Individual steps or elements described in connection with one embodiment may be used in addition to or to replace steps or elements described in connection with another embodiment. The description is thus to be regarded as illustrative instead of limiting.
This application is a continuation of U.S. application Ser. No. 15/613,049, filed Jun. 2, 2017.
Number | Date | Country | |
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Parent | 15613049 | Jun 2017 | US |
Child | 16362048 | US |