Acoustic wall assembly having active noise-disruptive properties, and/or method of making and/or using the same

Information

  • Patent Grant
  • 10354638
  • Patent Number
    10,354,638
  • Date Filed
    Tuesday, March 1, 2016
    8 years ago
  • Date Issued
    Tuesday, July 16, 2019
    5 years ago
  • Inventors
  • Original Assignees
    • Guardian Glass, LLC (Auburn Hills, MI, US)
  • Examiners
    • Goins; Davetta W
    • Ganmavo; Kuassi A
Abstract
Certain example embodiments relate to an acoustic wall assembly that uses active and/or passive sound reverberation to achieve noise-disruptive functionality, and/or a method of making and/or using the same. With the active approach, sound waves in a given frequency range are detected by a sound masking circuit. Responsive to detection of such sound waves, an air pump (e.g., speaker) is used to pump air in the wall assembly to actively mask the detected sound waves via reverberation and/or the like. The wall assembly may include one, two, or more walls, and the walls may be partial or full walls. With the passive approach, sound waves in a given frequency range are disrupted via features (e.g., holes, slits, etc.) formed in and/or on a wall itself. These techniques may be used together or separately, in different example embodiments.
Description
FIELD OF THE INVENTION

Certain example embodiments of this invention relate to an acoustic wall assembly having noise-disruptive properties, and/or a method of making and/or using the same. More particularly, certain example embodiments of this invention relate to an acoustic wall assembly that uses active and/or passive sound reverberation to achieve noise-disruptive functionality, and/or a method of making and/or using the same.


BACKGROUND AND SUMMARY OF EXAMPLE EMBODIMENTS OF THE INVENTION

Irritating noises, including outside speech, oftentimes is problematic in a wide range of settings including, for example, offices, homes, libraries, and/or the like. Interestingly, people tend to tolerate the noises that they themselves make, even though they sometimes are unaware of the trouble that they are making for others.


In fact, there are many known potential adverse effects elicited by enduring annoying sounds. These adverse effects can range from productivity losses for organizations (e.g., for failure to maintain and/or interruptions in concentration) to medical issues for people (e.g., the onset of headaches caused by annoying sounds, irritability, increased heart rate, and/or the like) and to even the urge to seek a new work environment. Misophonia, a learned condition relating to the association of sound with something unpleasant, also happens from time-to-time. Some people suffer from acoustic hyper-vigilance or oversensitivity to certain sounds.


In many settings, sound annoyance oftentimes is related to loudness, abruptness, high pitch and, in case of speech sounds, the speech content. In many cases, there are certain components in speech or noise that make them particularly disruptive or irritating. With respect to speech content, humans tend to strain to hear what is said, which has been found to subconsciously add to the annoyance. That is, once one is aware of somebody speaking, one oftentimes becomes involuntarily involved, adding a sort of subconscious annoyance.


People oftentimes are irritated by high frequencies (e.g., sounds in the 2,000-4,000 Hz range). These sounds do not need to be of high intensity to be perceived to be loud. In this regard, FIG. 1 is a graph showing perceived human hearing at a constant level, plotting sound pressure level against frequency. As can be seen, the “equal loudness sound curve” in FIG. 1 demonstrates that lower-frequency sounds with high sound pressure levels generally are perceived the same way that higher-frequency sounds with lower sound pressure levels are perceived. Typically, irritation increases with volume of the noise.


Sound waves propagate primarily in a longitudinal way, by alternating compressions and rarefactions of air. When the waves hit a wall, the distortion of molecules creates pressure on the outside of the wall that, in turn, emanates secondary sound.


It will be appreciated that it would be desirable to design a wall with noise-cancellation properties. Generally, the more porous a material is and the greater its thickness, the more soundproof it is. Glass is a good sound reflector but unfortunately is not a good sound insulator. Thus, it will be appreciated that it would be desirable to design a transparent wall with noise-cancellation properties.


Sound-insulating windows have been known in the art. One mainstream approach involves increasing the Sound Transmission Class (STC) of the wall. STC is an integer rating of how well a wall attenuates sound. It is weighted over 16 frequencies across the range of human hearing. STC can be increased by, for example, using of certain geometry of double-pane glass walls in order to destructively resonate sound; increasing the STC of single- or double-pane walls by increasing thickness of the glass, and/or using laminated glass.


Unfortunately, however, these techniques come at a cost. For example, increasing the thickness of single-pane glass allows only modest sound abatement, while adding to the cost. The use of double-pane glass, albeit more effective, typically requires the use of at least two comparatively thick (e.g., 6-12.5 mm) glass sheets. These approaches also typically require high tolerances in the wall construction, and the use of special pliant mechanical connections in order to avoid flanking effects. Glass of such thickness is heavy and expensive, and results in a high installation cost.


Furthermore, double-pane walls typically work well primarily for low-frequency sounds. This can limit their effectiveness to a smaller number of applications such as, for example, to exterior walls to counteract the low-frequency noise of jet and car engines, noise of seaports, railways, etc. At the same time, most speech sounds responsible for both annoyance and speech recognition lye within the 1800-2400 Hz range. It therefore would be desirable to achieve noise cancellation in this higher-frequency range, e.g., in order to help block irritating components and increase speech privacy.


Instead of abating higher-frequency noise, some solutions focus on sound masking. For instance, sounds of various frequencies may be electronically overlapped through a speaker, so that the extra sound is provided “on top of” the original noise. This approach obscures the irritation, but it unfortunately also creates additional noise, which some people perceive as irritating in itself.


Still another approach for achieving noise cancellation is used in Bose headphones, for example. This approach involves registering incoming noise and creating a counteracting noise that is out of phase with the registered incoming noise. One difficulty of this concept for walls, however, is that it typically only works well on a small area and it suitable primarily for continuous sounds (such as, for example, the hum of engines).


Thus, it will be appreciated that it would be desirable to provide for techniques that overcome some or all of the above-described and/or other problems. For example, it will be appreciated that it would be desirable to provide acoustic walls that help reduce or otherwise compensate for sounds that cause irritation and annoyance to users.


One aspect of certain example embodiments relates to an acoustic wall assembly that helps overcome some or all of the above-described and/or other problems.


Another aspect of certain example embodiments relates to an optically transparent interior glass wall assembly with a low STC.


Yet another aspect of certain example embodiments relates to improving the acoustics of rooms formed by and/or contained within the example wall assemblies disclosed herein. Acoustics of the room advantageously can be improved by, for example, increasing speech privacy, obscuring irritating outside noises otherwise perceivable in the room, providing counter-surveillance properties, and/or the like.


In certain example embodiments, an acoustic wall assembly is provided. A wall has an outside major surface and an inside major surface. An air pump is provided. A sound masking circuit is configured to: detect sound waves in a predetermined frequency range; and responsive to detection of sound waves in the predetermined frequency range, control the air pump to pump air to actively mask the detected sound waves as they pass from outside the outside major surface of the wall to inside the inside major surface of the wall.


In certain example embodiments, an acoustic wall assembly is provided. A wall has an outside major surface and an inside major surface. A receiver is sensitive to sound. A pump is controllable to generate pressure waves. A control circuit is operably coupled to the receiver and the pump, with the control circuit being configured to process a signal received from the receiver and control the pump to selectively generate pressure waves to disrupt, via a reverberative effect, noise in a predetermined frequency range that otherwise would pass through the wall.


In certain example embodiments, a kit for retrofitting a wall to provide an acoustic wall assembly with noise masking properties is provided. The kit comprises a receiver sensitive to sound; a pump controllable to generate pressure waves in and/or on the acoustic wall assembly; and a control circuit operably connectable to the receiver and the pump, with the control circuit being configured to process a signal received from the receiver and control the pump to selectively generate pressure waves to disrupt, via a reverberative effect, noise in a predetermined frequency range that otherwise would pass through the wall.


In certain example embodiments, a method of disrupting noise is provided. A wall includes an outside major surface and an inside major surface. Sound waves in a predetermined frequency range are detected via a sound masking circuit. Responsive to detection of sound waves in the predetermined frequency range, an air pump is controlled via the sound masking circuit to pump air in and/or around the wall to actively mask the detected sound waves as they pass from outside the outside major surface of the wall to inside the inside major surface of the wall.


In certain example embodiments, a method of making a sound-masking wall assembly that includes a wall is provided. A receiver sensitive to sound is provided. A pump controllable to generate pressure waves for the sound-masking wall assembly is provided. A control circuit is operably coupled to the receiver and the pump, with the control circuit being configured to process a signal received from the receiver and control the pump to selectively generate pressure waves to disrupt, via a reverberative effect, noise in a predetermined frequency range that otherwise would pass through the wall.


The features, aspects, advantages, and example embodiments described herein may be combined to realize yet further embodiments.





BRIEF DESCRIPTION OF THE DRAWINGS

These and other features and advantages may be better and more completely understood by reference to the following detailed description of exemplary illustrative embodiments in conjunction with the drawings, of which:



FIG. 1 is a graph showing perceived human hearing at a constant level, plotting sound pressure level against frequency;



FIG. 2 is a diagram with some examples of what happens with different reverberation times, and showing example applications suitable for different reverberation times;



FIG. 3 represents the calculated T60 in a room of variable dimensions with walls made out of three different materials, namely, glass, polycarbonate, and drywall;



FIGS. 4A-4B provide an example of the effect that reverberation can have;



FIG. 5 a graph plotting STC vs. T60, further confirming some advantages that result when using an active approach to sound masking, in accordance with certain example embodiments;



FIGS. 6A-6B are schematic views of acoustic wall assemblies incorporating active noise cancellation approaches in accordance with certain example embodiments;



FIG. 7 is another schematic view of an acoustic wall assembly incorporating an active noise cancellation approach in accordance with certain example embodiments;



FIGS. 8A-8B are schematic views of acoustic wall assemblies incorporating active noise cancellation approaches usable in connection with two walls, in accordance with certain example embodiments;



FIG. 9 is a flowchart showing an example approach for active noise cancellation, which may be used in connection with certain example embodiments; and



FIG. 10 is a schematic view of an acoustic wall assembly incorporating a passive noise cancellation approach in accordance with certain example embodiments.





DETAILED DESCRIPTION OF EXAMPLE EMBODIMENTS OF THE INVENTION

Certain example embodiments relate to an acoustic wall assembly that uses active and/or passive sound reverberation to achieve noise-disruptive functionality, and/or a method of making and/or using the same. Reverberation, added in an active and/or passive manner, helps to mask irritating sounds that originate from outside of a room equipped with such a wall assembly and/or from beyond such a wall assembly. This approach includes, for example, helping to make speech taking place outside of the room and/or beyond the wall assembly to be perceived as unintelligible, in certain example embodiments.


Certain example embodiments add noise-cancelling and speech-disruptive properties to walls with a low STC, advantageously allowing for low-cost, low-weight solutions with speech-privacy qualities. Certain example embodiments may be used in high-STC walls, e.g., as a measure to further improve speech privacy and/or noise cancellation.


Reverberation sometimes is advantageous when compared to common sound-abating and masking techniques. For example, reverberation in some instances adds only the loudness necessary to disrupt speech or noise. No unnecessary additional noise is created in some embodiments. Reverberation also advantageously is not restricted to specific wall assembly dimensions and/or geometries, can work equally well at low and high frequencies, and is forgoing with respect to the presence of flanking losses (which otherwise sometimes undermine sound isolation as a result of sound vibrations passing through a structure along an incident path such as, for example, through framing connections, electrical outlets, recessed lights, plumbing pipes, ductwork, etc.). Reverberation also advantageously is resistant to surveillance. Speech masked by white noise sometimes can be easy to decipher (e.g., by removing the additional noise from the signal), reverberation is difficult to decode because there basically is no reference signal (e.g., it is basically self-referenced). Furthermore, reverberation in at least some instances can be activated as-needed, and its volume can be controlled. An additional benefit of using reverberation relates to its ability to disrupt so-called “beating,” which is a potentially irritating infra-sound constructed by two different sound frequencies. Although infra-sound cannot be heard per se, it has an adverse subconscious effect. Still further, reverberation may be advantageous from a cost perspective, because it merely disrupts sound rather than trying to eliminate it completely or cover over it. Indeed, reverberation oftentimes will require less energy than the addition of white noise.


When it comes to speech in particular, certain example embodiments are effective in There are following areas of interest in disrupting the speech: disrupting fundamental frequencies of speech and their harmonics; masking key acoustic cues of overlapping syllables and vowels; eliminating artificially created infra-sound with sub-threshold frequencies that resonate adversely with the brain waves (e.g., in the 4-60 Hz range, with the envelope fluctuation of speech coincidentally having a maximum at about 4 Hz, which corresponds to the number of syllables pronounced per second); providing sound disruption in frequency domain by adding frequencies; providing sound disruption in time domain using reverberation; and/or the like.


Reverberation time, T60, is one measure associated with reverberation. It represents the time required for sound to decay 60 decibels from its initial level. Rooms with different purposes benefit from different reverberation times. FIG. 2 is a diagram with some examples of what happens with different reverberation times, and showing example applications suitable for different reverberation times. In general, values of T60 that are too low (e.g., little to no reverberation) tend to make speech sound “dead,” whereas values of T60 that are too high (e.g., providing a lot of reverberation) tend to make speech unintelligible. Also in general, optimal reverberation times make speech and music sound rich.


T60 can be calculated based on the Sabine formula:







T
60

=

0.16


V

S
e







In this formula, V is the volume and Se is a combined effective surface area of the room. The Se of each wall is calculated by multiplying the physical area by the absorption coefficient, which is a textbook value that varies for different materials. The following table provides the sound absorption coefficients of some common interior building materials.



















125 Hz
250 Hz
500 Hz
1 kHz
2 kHz
4 kHz





















Floor Materials








Carpet on foam
0.08
0.24
0.57
0.69
0.71
0.73


Wall Materials


Brick: unglazed
0.03
0.03
0.03
0.04
0.05
0.07


Curtain:
0.03
0.04
0.11
0.17
0.24
0.35


10 oz./sq. yd.


Fiberglass: 2″
0.17
0.55
0.80
0.90
0.85
0.80


Glass: ¼″
0.18
0.06
0.04
0.03
0.02
0.02


plate large


Polycarbonate
0.27
0.38
0.25
0.18
0.1
0.07


Ceiling


Materials


Acoustic
0.70
0.66
0.72
0.92
0.88
0.75


ceiling tiles


⅜″ plywood
0.28
0.22
0.17
0.09
0.10
0.11


panel










FIG. 3 represents the calculated T60 in a room of variable dimensions with walls made out of three different materials, namely, glass, polycarbonate, and drywall.


An example of the effect that reverberation can have is presented in FIGS. 4A-4B. FIG. 4A represents an original speech pattern, and FIG. 4B shows an example effect that reverberation can have. As can be seen from FIGS. 4A-4B, reverberation disrupts speech articulation by (among other things) filling in “spaces” between formants, which are clusters of vocal energy. Adding signal to these speech building blocks (namely, vowels and especially consonants) and disrupting the space between formants helps to make speech unintelligible and reduce the potentially adverse psychoacoustic effects of speech.


As indicated above, certain example embodiments may use active and/or passive approaches for triggering reverberation to serve in noise-cancelling roles. As will become clearer from the description below, active approaches may involve electronic, electromechanical, and/or selectively-controllable mechanical apparatus, to disrupt sound waves incident on a wall assembly or the like. Passive approaches may involve wall assemblies specifically engineered to trigger reverberation, e.g., through the incorporation of holes in the wall assemblies and/or the attachment or other formation of sound reverberating components therein and/or thereon, using natural properties of the thus-formed wall itself.


Referring once again to FIG. 3, it can be seen that reverberation in walls is primarily noticeable in the low-frequency range. Thus, it may be desirable to use an active approach in order to use reverberation in a high-frequency range to mask irritating sounds and speech. FIG. 5 is a graph plotting STC vs. T60, further confirming some advantages that result when using an active approach to sound masking, in accordance with certain example embodiments. That is, as can be seen in FIG. 5, a high STC can be desirable to make speech and/or the like unintelligible when dealing with a low T60 value. By contrast, an electronically-created regime can help to remove intelligibility even at low STC values.



FIG. 6A is a schematic view of an acoustic wall assembly that incorporates an active noise cancellation approach in accordance with certain example embodiments. As shown in FIG. 6A, a wall 600 includes outer and inner major surfaces 600a and 600b. It is desirable in the FIG. 6A embodiment to reduce the disruption and annoyance caused by the sound 602 relative to the listener(s) 604. Thus, a microphone or other listening device 606 picks up or otherwise receives this sound, and a signal is passed to the sound masking circuit 608 embedded in or otherwise provided in connection with the wall 600 in the broader wall assembly of FIG. 6A. The signal from the microphone 606 may be an analog or digital signal in different example embodiments, and the sound masking circuit 608 may include an analog-digital converter, e.g., in the event that an analog signal that is provided is to be processed digitally. In certain example embodiments, the microphone 606 may be installed within the wall 600.


The sound masking circuit 608 determines whether the signal that is provided to it from the microphone 606 is within one or more predetermined frequency ranges, and/or contains noise with the one or more predetermined frequency ranges therein. A bandpass or other filter that is a part of the sound masking circuit 608 may be used in this regard. One of the one or more predetermined frequency ranges may correspond to speech and/or noise determined to be psychoacoustically disruptive, disturbing, or annoying. One of the one or more predetermined frequency ranges may correspond to the 28-3200 Hz range, which helps to mask the sounds of most consonants (which may be the most statistically effective manner of masking sounds) and the sounds of at least some syllables.


Responsive to the detection of sound waves in the one or more predetermined frequency ranges, the sound masking circuit 608 actuates the air pump 610, e.g., to generate pressure waves to disrupt, via a reverberative and/or other effect, noise in a predetermined frequency range that otherwise would pass through the wall. The air pump 610 may be a speaker, part of an HVAC system, and/or the like. The air pump 610 creates reverberation 612 in the wall 600 between the outer and inner major surfaces 600a and 600b. This helps to actively mask the detected sound waves as they pass from outside the outside major surface 600a of the wall 600 to inside the inside major surface 600b of the wall 600, thereby helping to reduce annoyance caused to the listener(s) 604. That is, the reverberation 612 in certain example embodiments helps disrupt perceived speech and/or irritating noises. The reverberation 612 is substantially uniform throughout the entire wall 600 in certain example embodiments, as the air pump 610 in essence is not a point source of added noise. Thus, listeners basically will hear the same thing at any point beyond the wall 600, as noise in essence is concealed in the wall 600 in a non-constant, potentially “on demand” or dynamic manner. Advantageously, this effect helps guard against surveillance, as laser microphones (for example) cannot pickup discrete sounds, reverberation is self-referencing and thus harder to decipher, there is no added white noise that can be subtracted, etc.


In addition to or in place of reverberation, certain example embodiments may implement active masking by means of reverse masking. The noise masking enabled by the sound masking circuit 608 may be performed in accordance with an algorithm (e.g., a reverberation algorithm) that uses a technique such as, for example, standard convolution, enhanced convolution, reverse reverberation, delay-controlled reverberation, and/or the like. The sound masking circuit 608 may process incoming noise 602 and control the air pump 610 in accordance with output from the algorithm, in certain example embodiments. In certain example embodiments, the algorithm may change the perceived loudness of incident noise in the time domain.


The wall 600 may be formed from any suitable material such as, for example, one or more sheets of drywall, glass, polycarbonate, plaster, and/or the like. In certain example embodiments, the wall or material(s) comprising the wall has/have acoustic absorption coefficients ranging from: 0.03-0.3 at 125 Hz, 0.03-0.6 at 250 Hz, 0.03-0.6 Hz at 500 Hz; 0.03-0.9 at 1000 Hz, 0.02-0.9 at 2000 Hz, and 0.02-0.8 at 4000 Hz. In this regard, FIG. 6A may be thought of as being either a plan view or a cross-sectional view. In the case of the former (i.e., a plan view), the air pump 610 and/or sound masking circuit 608 may be provided above the wall 600 (e.g., in the ceiling and below, for example, an upper slab) or to the side of the wall 600. In certain example embodiments, the sound masking circuit 608 may be connected to a side of the wall 600 but concealed from view (e.g., by being hidden in the ceiling, behind molding, etc.). The same may be true for the microphone 606. The air pump 610 may force air onto the top and/or sides of the wall 600, triggering reverberation therein or thereof.


With respect to a cross-sectional view, the outer and inner major surfaces 600a and 600b may be separate drywall surfaces separated, for example, by metal and/or wooden studs, or the like. The air pump 610 and/or sound masking circuit 608 may be provided above the wall 600 (e.g., in the ceiling and below, for example, an upper slab), to the side of the wall 600, or within the gap between the outer and inner major surfaces 600a and 600b. Similar to the above, the sound masking circuit 608 may be connected to a side of the wall 600 but concealed from view (e.g., by being hidden in the ceiling, behind molding, within the gap between the outer and inner major surfaces 600a and 600b, etc.). The same may be true for the microphone 606. The air pump 610 may force air onto the top and/or sides of the wall 600, and/or within the gap between the outer and inner major surfaces 600a and 600b of the wall 600. Thus, in certain example embodiments, the wall 600 may be said to comprise first and second substantially parallel spaced apart substrates (of or including glass and/or the like), with the air pump 610 and the sound masking circuit 608 being located therebetween.


As alluded to above, the wall may be of or include glass. That is, certain example embodiments may be directed to a glass wall used in connection with an acoustic wall assembly. The glass wall may comprise, one, two, three, or another number of sheets of glass. The glass may be regular float, heat-strengthened, tempered, and/or laminated glass. In certain example embodiments, the wall may be of or include an insulated glass (IG) unit, a vacuum insulated glass (VIG) unit, and/or the like. An IG unit may include first and second substantially parallel spaced apart substrates, with an edge seal formed around peripheral edges, and with the cavity between the substrates optionally being filled with an inert gas (e.g., Ar, Xe, and/or the like) with or without air. A VIG unit may include first and second substantially parallel spaced apart substrates, with an edge seal formed around peripheral edges, and spacers, with the cavity between the substrates being evacuated to a pressure less than atmospheric. Framing may be provided around the IG unit and/or the VIG unit in some instances, and that framing may be a part of the acoustic wall assembly. In certain example embodiments, other transparent materials may be used. In certain example embodiments, the naturally high sound-reflection coefficient of glass may be advantageous, e.g., when triggering reverberation and/or other noise masking effects.



FIG. 6B is similar to FIG. 6A, except that first and second microphones 606a and 606b are provided so that incident noise 602a and 602b can be registered and compensated for, thereby reducing annoyance to listeners 604a and 604b, on both sides of the wall 600. In certain example embodiments, the same air pump 610 can be used to generate reverberation 612. In certain example embodiments, the sound masking circuit 608 may trigger the same or different actions with respect to the air pump 610, e.g., based on which side of the wall 600 the noise comes from. In this regard, the sound masking circuit 608 may be able to determine which side of the wall 600 the sound is coming from, e.g., based on intensity and/or the like. The effectiveness of the reverberation 612 may be picked up by the other microphone and fed back into the sound masking circuit 608, e.g., to improve the noise cancelling effects. In different embodiments, one or both of the first and second microphones 606a and 606b may be provided on inner or outer surfaces of the wall 600. In certain example embodiments, one of the first and second microphones 606a and 606b may be formed on an outer surface of the wall 600, and the other of the first and second microphones 606a and 606b may be formed on an inner surface of the wall 600. In the FIG. 6B example, reverberation may be said to work actively “in both directions” (although it will be appreciated that it may be possible to realize the same or similar functionality in connection with a single microphone in some cases).



FIG. 7 is another schematic view of an acoustic wall assembly incorporating an active noise cancellation approach in accordance with certain example embodiments. FIG. 7 shows a wall 700 formed outside of a “quiet” or “secure” room. Noise 702 from inside the room is detected by microphone 606. The sound masking circuit 608 receives signals from the microphone 606 and triggers the air pump 710, which triggers reverberation 712a-712d in the wall 700. The reverberation 712a-712d is substantially uniform throughout the entire wall 700 in certain example embodiments, so that listeners 704a-704d around the room (and around the wall 700) cannot perceive sounds and/or annoyance from within. It will be appreciated that the FIG. 7 example may be modified so as to include one or more microphones inside of the room in certain example embodiments. Additionally, or in the alternative, it will be appreciated that the FIG. 7 example may be modified so as to include one or more microphones so as to detect and compensate for sounds originating from outside of the room, e.g., in a manner similar to that described in connection with FIG. 6B. One or more microphones provided to receive sounds originating from outside of the room, regardless of their placement, may be useful in turning FIG. 7 into a private or quiet room, where sounds from the outside are compensated for and masked.



FIGS. 8A-8B are schematic views of acoustic wall assemblies incorporating active noise cancellation approaches usable in connection with two walls, in accordance with certain example embodiments. FIGS. 8A-8B are similar to FIGS. 6A-6B. However, rather than having outer and inner surfaces of a single wall, outer and inner walls 800a and 800b are provided. The noise masking circuit 608 and/or the pump 610 may be placed within the cavity 800 defined by the outer and inner walls 800a and 800b, and they may cooperate to create reverberation 812 in the cavity 800.


It is believed that a wall's lateral dimensions may mostly affect the fundamental spectral regions of speech and their lower harmonics, while the distance between the two sheets of a wall primarily will affect high-frequency components and their higher harmonics. An example embodiment of a glass wall has dimensions 10 ft.×12 ft., with air spacing between two sheets of glass preferably in the range of 1-20 cm, more preferably in the range of 7-17 cm, and an example separation of 10 cm.



FIG. 9 is a flowchart showing an example approach for active noise cancellation, which may be used in connection with certain example embodiments. FIG. 9 assumes that a wall or wall assembly is already provided (step S902). Incident sound waves are detected (step S904). If the detected sound waves are not in or do not include a frequency range of interest (as determined in step S906), then the process simply returns to step S904 and waits for further incident sound waves to be detected. On the other hand, if the detected sound waves are in or include a frequency range of interest (as determined in step S906), air is pumped to mask the incident sound waves (step S908). This behavior thus provides for dynamic or “on-demand” masking of noises, e.g., through a system that is not always on. If the sound is not terminated (as determined in step S910), then the process returns to step S908 and further air is pumped. On the other hand, if the sound is terminated, then information about the incident may be logged (step S912), and the process may return to step S904 and wait for further incident sound waves to be detected.


The logging of step S912 may include, for example, creation of a record in a data file stored to a non-transitory computer readable storage medium and/or the like (e.g., a flash memory, a USB drive, RAM, etc.). The record may include a timestamp indicating the start and stop times of the event, as well as a location identifier (e.g., specifying the wall at which the sound was detected for instance in the event that there are multiple walls implementing the technology disclosed herein, the microphone that detected the sound for instance in the event that there are multiple microphones in a given wall, etc.). Information about the frequency range(s) detected may be stored to the record, as well. In certain example embodiments, circuitry may store a digital or other representation of the detected sound, e.g., in the record or in an associated data file. As a result, speech or other noises may be recorded, potentially with entire conversations being captured and archived for potential subsequent analysis. For example, the sound masking circuit (for example) may be used as a recording device (e.g., like a security camera, eavesdropping device, sound statistics monitoring device, and/or the like). In certain example embodiments, information may be stored locally and transmitted to a remote computer terminal or the like for potential follow-up action such as, for example, playback of noise events and/or conversations, analysis of same (e.g., to help reveal what types of noises were recorded most, what time of day is the noisiest, who makes the most kinds of different noises, etc.). Transmission may be accomplished by removing physical media (such as a flash drive, USB drive, and/or the like), through a wired connection (e.g., including transmissions over a serial, USB, or other cable), wirelessly (e.g., by Wi-Fi, Bluetooth, over the Internet, and/or other like), etc. Information may be transmitted periodically and/or on-demand in different example embodiments.


In certain example embodiments, the sound masking circuit may be programmed to determine whether incident noise corresponds to a known pattern or type. For example, although annoying, alarm sounds, sirens, and/or the like, may be detected by the sound masking circuit and allowed to go through the wall assembly for safety, informational, and/or other purposes.


In certain example embodiments, the sound masking circuit may be programmed to operate as both a sound disrupter (e.g., through the use of reverberation and/or the like), as well as a sound sweetener. With respect to the latter, the sound masking circuit may generate reverberative and/or pleasant sounds to help mask potentially annoying noises. Pleasant sounds may be nature sounds (e.g., the sound of the ocean), sounds of animals (e.g., dolphins), soothing music, and/or the like. These sounds may be stored to a data store accessible by the sound masking circuit. When appropriate (e.g., when triggering reverberation as described above), the sound masking circuit may retrieve the sound sweetener and provide it as output to a speaker or the like (which may be, for example, the same or different speaker as is used as the air pump in certain example embodiments).


Another example embodiment uses a more passive approach to an acoustic wall assembly. For example, a passive approach may use the wall itself as a reverberation-inducing resonator that involves acoustic contrast. This may be accomplished by having one or more (and preferably two or more) openings, slits, and/or the like, formed in the acoustic wall assembly, thereby using natural properties of the wall itself to create reverberative effects of a desired type. These features may be formed on one side of the acoustic wall assembly, adding to the acoustics of the wall assembly directional properties. For example, at least one opening may be made in the outside pane of a double-pane wall in order to make the effect directional, and so that the effect of reverberation is more pronounced outside of the wall. As another example, at least one opening may be made in the inside pane of the double-pane wall. This may be advantageous for some applications, like music halls, which may benefit from additional sound reverberation that makes sounds seem richer.


In certain example embodiments, additional reverberating elements may be affixed to a wall. The sound-masking reverberation-inducing element(s) may be provided in a direct contact with a single or partial wall, so the wall can act as a sound source in certain example embodiments. In certain example embodiments, the sound-masking reverberation-inducing element(s) may be provided between the walls in a wall assembly. Sound masking advantageously results in an increased noise/signal contrast, which makes speech perceived behind a single or partial wall less comprehensible and irritating sounds less annoying.


In certain example embodiments, a first set of features may be formed in and/or on an inner pane and a second set of features may be formed in and/or on an outer pane, e.g., keeping some annoying or disruptive sounds out and improving the acoustics “on the inside.” In certain example embodiments, multiple sets of features may be formed in and/or on one or both panes of a two-pane wall assembly, with each set of features targeting a different range to be eliminated and/or emphasized.


Other natural properties of the wall assembly (including size, space between adjacent upright walls, etc.) also may be selected to trigger desirable reverberative effects, e.g., as described above.


It will be appreciated that these more passive techniques may be used in addition to the active techniques discussed above, e.g., with single- or two-wall acoustic wall assemblies. It also will be appreciated that these more passive techniques may be used by themselves. In this latter regard, FIG. 10 is a schematic view of an acoustic wall assembly 1000 incorporating a passive noise cancellation approach in accordance with certain example embodiments.


The acoustic wall assembly 1000 includes outer and inner walls 1000a and 1000b, which define a gap or cavity therebetween. Noise 602 is incident on the outer wall 1000, and a series of features formed in the wall set up reverberation 1012. As shown in the FIG. 10 example, these features include first and second sets of slits 1002a and 1002b and first and second holes 1004a and 1004b. The sets of slits 1002a-1002b and the holes 1004a-1004b are designed to address different frequency ranges of the noise 602 and contribute the reverberation 1012 in different ways. Although not shown in FIG. 10, additional features may be affixed to the walls 1002a-1002b to cause it to resonate in a manner that creates the desired reverberation.


The wall assembly 1002 thus is made in the manner of a sound resonator with specifically designed fundamental resonant frequencies. As above, any suitable material may be used in constructing the walls 1002a-1002b. For example, because glass is a naturally good resonator, certain example embodiments are able to make use of a variety of resonant harmonics, which are the integer multiples of the fundamental frequency. Regardless of the material, tailoring of the incoming sound via the features may help to disrupt the frequency ranges of the speech and noise in order to make it unintelligible and/or less annoying. For example, it is possible to target those frequency ranges associated with consonants when dealing with speech, etc. Moreover, because such a wall assembly is designed for selective sound disruption, it is possible in certain example embodiments to use thin glass and longer-lasting rigid joints in the wall assembly. This construction advantageously may make the entire design more solid and reliable. When glass is used, high tolerances may be desirable in order to help maximize the effectiveness of sound resonating properties by avoiding leakage, etc.


The walls described herein may be partial walls, e.g., walls that leave open space between separated areas.


Methods of making the above-described and/or other walls and wall assemblies are also contemplated herein. For the example active approaches described herein, such methods may include, for example, erecting walls, connecting microphones and air pumps to sound masking circuits, etc. Configuration steps for sound masking circuits (e.g., specifying one or more frequency ranges of interest, when/how to actuate an air pump, etc.) also are contemplated. Mounting operations may be used, e.g., with respect to the microphone and/or the air pump (including the hanging of speakers), etc. Integration with HVAC systems and/or the like also is contemplated. For the example passive approaches described herein, such methods may include, for example, erecting walls, and forming reverberation-inducing elements therein and/or affixing reverberation-inducing elements thereto.


In a similar vein, methods of retrofitting existing walls and/or wall assemblies also are contemplated and may include the same or similar steps. Retrofit kits also are contemplated herein.


Certain example embodiments have been described in connection with acoustic walls and acoustic wall assemblies. It will be appreciated that these acoustic walls and acoustic wall assemblies may be used in a variety of applications to alter perceived speech patterns, obscure certain irritating sound components emanated from adjacent areas, and/or the like. Example applications include, for example, acoustic walls and acoustic wall assemblies for rooms in a house; rooms in an office; defined waiting areas at doctors' offices, airports, convenience stores, malls, etc.; exterior acoustic walls and acoustic wall assemblies for homes, offices, and/or other structures; outer elements (e.g., doors, sunroofs, or the like) for vehicles; etc. Sound masking may be provided for noises emanating from an adjacent area, regardless of whether that adjacent area is another room, outside of the confines of the structure housing the acoustic wall and acoustic wall assembly, etc. Similarly, sound masking may be provided to prevent noises from entering into an adjacent area of this or other sort.


The acoustic walls and acoustic wall assemblies may be full-height or partial-height in different instances.


In certain example embodiments, an acoustic wall assembly is provided. A wall has an outside major surface and an inside major surface. An air pump is provided. A sound masking circuit is configured to: detect sound waves in a predetermined frequency range; and responsive to detection of sound waves in the predetermined frequency range, control the air pump to pump air to actively mask the detected sound waves as they pass from outside the outside major surface of the wall to inside the inside major surface of the wall.


In addition to the features of the previous paragraph, in certain example embodiments, the wall may be a glass wall.


In addition to the features of either of the two previous paragraphs, in certain example embodiments, the air pump may be embedded in the wall and may be arranged to pump air therein.


In addition to the features of any of the three previous paragraphs, in certain example embodiments, the air pump may be a speaker.


In addition to the features of any of the four previous paragraphs, in certain example embodiments, a microphone embedded may be in the wall.


In addition to the features of any of the five previous paragraphs, in certain example embodiments, active acoustic masking may be performed using reverse masking.


In addition to the features of any of the six previous paragraphs, in certain example embodiments, active masking may be performed using reverberation.


In addition to the features of any of the seven previous paragraphs, in certain example embodiments, the sound masking circuit may comprise a controller configured to (a) process detected sound waves in the predetermined frequency range in accordance with an algorithm and (b) control the air pump to pump air to actively mask the detected sound waves in accordance with output from the algorithm.


In addition to the features of the previous paragraph, in certain example embodiments, the algorithm may be a reverberation algorithm selected from the group consisting of: standard convolution, enhanced convolution, reverse reverberation, and delay-controlled reverberation.


In addition to the features of any of the nine previous paragraphs, in certain example embodiments, the predetermined frequency range may correspond to speech and/or noise determined to be psychoacoustically disruptive, disturbing, or annoying.


In addition to the features of any of the 10 previous paragraphs, in certain example embodiments, a first microphone may be embedded in the wall and a second microphone may be installed on the outside major surface of the wall.


In addition to the features of the previous paragraph, in certain example embodiments, the sound masking circuit may be further configured to: control the air pump to pump air to actively mask detected sound waves as they pass from outside the outside major surface of the wall to inside the inside major surface of the wall, in response to detection of the sound waves via the first microphone, and control the air pump to pump air to actively mask detected sound waves as they pass to outside the outside major surface of the wall from inside the inside major surface of the wall, in response to detection of the sound waves via the second microphone.


In addition to the features of either of the two previous paragraphs, in certain example embodiments, active masking may be performed using reverberation.


In addition to the features of any of the 13 previous paragraphs, in certain example embodiments, at least one opening may be formed in the wall, e.g., with the at least one opening causing generated reverberation to be directional relative to the outside and inside major surfaces of the wall.


In addition to the features of any of the 14 previous paragraphs, in certain example embodiments, at least one opening formed in the wall may be formed in the wall, e.g., with the at least one opening having a size, shape, and dimension selected to trigger reverberation at a desired frequency range.


In addition to the features of any of the 15 previous paragraphs, in certain example embodiments, the wall may have acoustic absorption coefficients ranging from: 0.03-0.3 at 125 Hz, 0.03-0.6 at 250 Hz, 0.03-0.6 Hz at 500 Hz; 0.03-0.9 at 1000 Hz, 0.02-0.9 at 2000 Hz, and 0.02-0.8 at 4000 Hz.


In certain example embodiments, an acoustic wall assembly is provided. A wall has an outside major surface and an inside major surface. A receiver is sensitive to sound. A pump is controllable to generate pressure waves. A control circuit is operably coupled to the receiver and the pump, with the control circuit being configured to process a signal received from the receiver and control the pump to selectively generate pressure waves to disrupt, via a reverberative effect, noise in a predetermined frequency range that otherwise would pass through the wall.


In certain example embodiments, a kit for retrofitting a wall to provide an acoustic wall assembly with noise masking properties is provided. The kit comprises a receiver sensitive to sound; a pump controllable to generate pressure waves in and/or on the acoustic wall assembly; and a control circuit operably connectable to the receiver and the pump, with the control circuit being configured to process a signal received from the receiver and control the pump to selectively generate pressure waves to disrupt, via a reverberative effect, noise in a predetermined frequency range that otherwise would pass through the wall.


In certain example embodiments, a method of disrupting noise is provided. A wall includes an outside major surface and an inside major surface. Sound waves in a predetermined frequency range are detected via a sound masking circuit. Responsive to detection of sound waves in the predetermined frequency range, an air pump is controlled via the sound masking circuit to pump air in and/or around the wall to actively mask the detected sound waves as they pass from outside the outside major surface of the wall to inside the inside major surface of the wall.


In addition to the features of the previous paragraph, in certain example embodiments, the air pump and/or the sound masking circuit may be embedded in the wall.


In addition to the features of either of the two previous paragraphs, in certain example embodiments, active acoustic masking may be performed using reverse masking.


In addition to the features of any of the three previous paragraphs, in certain example embodiments, active masking may be performed using reverberation.


In addition to the features of any of the four previous paragraphs, in certain example embodiments, the sound masking circuit may comprise a controller configured to (a) process detected sound waves in the predetermined frequency range in accordance with an algorithm and (b) control the air pump to pump air to actively mask the detected sound waves in accordance with output from the algorithm.


In addition to the features of any of the five previous paragraphs, in certain example embodiments, a first microphone may be embedded in the wall and a second microphone may be installed on the outside major surface of the wall.


In addition to the features of the previous paragraph, in certain example embodiments, the sound masking circuit may be further configured to: control the air pump to pump air to actively mask detected sound waves as they pass from outside the outside major surface of the wall to inside the inside major surface of the wall, in response to detection of the sound waves via the first microphone, and control the air pump to pump air to actively mask detected sound waves as they pass to outside the outside major surface of the wall from inside the inside major surface of the wall, in response to detection of the sound waves via the second microphone.


In certain example embodiments, a method of making a sound-masking wall assembly that includes a wall is provided. A receiver sensitive to sound is provided. A pump controllable to generate pressure waves for the sound-masking wall assembly is provided. A control circuit is operably coupled to the receiver and the pump, with the control circuit being configured to process a signal received from the receiver and control the pump to selectively generate pressure waves to disrupt, via a reverberative effect, noise in a predetermined frequency range that otherwise would pass through the wall.


While the invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not to be limited to the disclosed embodiment, but on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

Claims
  • 1. An acoustic wall assembly, comprising: a wall having an outside major surface and an inside major surface;an air pump;a sound masking circuit configured to: detect sound waves in a predetermined frequency range, andresponsive to detection of sound waves in the predetermined frequency range, control the air pump to pump air to actively mask the detected sound waves as they pass from outside the outside major surface of the wall to inside the inside major surface of the wall; andat least one opening formed in the wall, the at least one opening having a size, shape, and dimension selected to trigger reverberation at a desired frequency range,wherein the reverberation is generatable to account for sound flanking and infra-sound beating.
  • 2. An acoustic wall assembly, comprising: a wall having an outside major surface and an inside major surface;an air pump; anda sound masking circuit configured to: detect sound waves in a predetermined frequency range, andresponsive to detection of sound waves in the predetermined frequency range, control the air pump to pump air to actively mask the detected sound waves as they pass from outside the outside major surface of the wall to inside the inside major surface of the wall,wherein the air pump is embedded in the wall and is arranged to pump air therein, the air pump being controllable by the sound masking circuit to create a dynamic non-point source of reverberative noise that is concealed in, and substantially uniform throughout, the wall,wherein the reverberative noise is generated in an on-demand manner to disrupt intelligibility of the detected sound waves as they pass from outside the outside major surface of the wall to inside the inside major surface of the wall without substantial sound abatement of the detected sound waves, andwherein the wall has acoustic absorption coefficients ranging from: 0.03-0.3 at 125 Hz, 0.03-0.6 at 250 Hz, 0.03-0.6 Hz at 500 Hz; 0.03-0.9 at 1000 Hz, 0.02-0.9 at 2000 Hz, and 0.02-0.8 at 4000 Hz.
  • 3. An acoustic wall assembly, comprising: a wall having an outside major surface and an inside major surface;a receiver sensitive to sound;a pump controllable to generate pressure waves; anda control circuit operably coupled to the receiver and the pump, the control circuit being configured to process a signal received from the receiver and control the pump to dynamically generate pressure waves to disrupt, by making the wall itself reverberate in an on-demand manner, noise in a predetermined frequency range that otherwise would pass through the wall,wherein the pressure waves are generatable to respond to detected beating and/or to noise caused by sound flanking.
  • 4. The acoustic wall assembly of claim 3, further comprising at least one opening formed in the wall, the at least one opening causing generated reverberation to be directional relative to the outside and inside major surfaces of the wall.
  • 5. A kit for retrofitting a wall to provide an acoustic wall assembly with noise masking properties, the kit comprising: a receiver sensitive to sound;a pump controllable to generate pressure waves in and/or on the acoustic wall assembly; anda control circuit operably connectable to the receiver and the pump, the control circuit being configured to process a signal received from the receiver and control the pump to dynamically generate pressure waves to cause the wall itself to reverberate to disrupt noise in a predetermined frequency range that otherwise would pass through the wall, wherein the pressure waves are generatable to respond to detected beating and/or to noise caused by sound flanking.
  • 6. A method of making a sound-masking wall assembly, the method comprising: having a wall;providing a receiver sensitive to sound;providing a pump controllable to generate pressure waves for the sound-masking wall assembly; andoperably coupling a control circuit to the receiver and the pump, the control circuit being configured to process a signal received from the receiver and control the pump to dynamically generate pressure waves to disrupt, via a reverberative effect, psychoacoustically disruptive noise in a predetermined frequency range that otherwise would pass through the wall,wherein the generated pressure waves are generated so as to disrupt, without substantially cancelling and without substantially completely covering over, the psychoacoustically disruptive noise, while also accounting for sound flanking and infra-sound beating.
US Referenced Citations (97)
Number Name Date Kind
1483365 Mazer Feb 1824 A
2132642 Parsons Oct 1938 A
2159488 Parkinson May 1939 A
2966954 Sabine Jan 1961 A
3239973 Hannes et al. Mar 1966 A
3384199 Eckel May 1968 A
3621934 Thrasher Nov 1971 A
3879578 Wildi Apr 1975 A
4059726 Watters Nov 1977 A
4098370 McGregor Jul 1978 A
4099027 Whitten Jul 1978 A
4195202 McCalmont Mar 1980 A
4268717 Moore May 1981 A
4476572 Horrall et al. Oct 1984 A
5024288 Shepherd Jun 1991 A
5202174 Capaul Apr 1993 A
5368917 Rehfeld et al. Nov 1994 A
5438624 Lewiner Aug 1995 A
5491310 Jen Feb 1996 A
5627897 Gagliardini et al. May 1997 A
5668744 Varadan et al. Sep 1997 A
5724432 Bouvet Mar 1998 A
5754662 Jolly May 1998 A
5997985 Clarke Dec 1999 A
6078673 von Flotow Jun 2000 A
6119807 Benson, Jr. et al. Sep 2000 A
6483926 Yamashita Nov 2002 B1
6771791 Shelley Aug 2004 B2
7194094 Horrall Mar 2007 B2
7363227 Mapes-Riordan Apr 2008 B2
7754338 Anderson Jul 2010 B2
7756281 Goldstein Jul 2010 B2
7761291 Renevey et al. Jul 2010 B2
7763334 Berkowitz Jul 2010 B2
7854295 Kakuhari Dec 2010 B2
8100225 Bartha Jan 2012 B2
8180067 Soulodre May 2012 B2
8739927 Kang Jun 2014 B2
8925678 Tizzoni Jan 2015 B2
9186865 Blanchard et al. Nov 2015 B2
9390702 Mathur Jul 2016 B2
9980041 Kawakami et al. May 2018 B2
20020017426 Takahashi et al. Feb 2002 A1
20030048910 Roy Mar 2003 A1
20030091199 Horrall May 2003 A1
20030215108 Shelley Nov 2003 A1
20040057584 Kakuhari et al. Mar 2004 A1
20040102975 Eide May 2004 A1
20040125922 Specht Jul 2004 A1
20040189475 Cooper Sep 2004 A1
20040191474 Yamagiwa Sep 2004 A1
20050065778 Mastrianni et al. Mar 2005 A1
20050157891 Johansen Jul 2005 A1
20060009969 L'Esperance Jan 2006 A1
20060109983 Young May 2006 A1
20060147051 Smith Jul 2006 A1
20060289229 Yamaguchi Dec 2006 A1
20080002833 Kuster Jan 2008 A1
20080187147 Berner Aug 2008 A1
20080235008 Ito Sep 2008 A1
20090084627 Tsugihashi Apr 2009 A1
20100014683 Maeda Jan 2010 A1
20100028134 Slapak Feb 2010 A1
20100175949 Yamaguchi Jul 2010 A1
20100266138 Sachau Oct 2010 A1
20110182438 Koike Jul 2011 A1
20110274283 Athanas Nov 2011 A1
20120197641 Akechi et al. Aug 2012 A1
20120240486 Borroni Sep 2012 A1
20120247867 Yang Oct 2012 A1
20120316869 Xiang Dec 2012 A1
20130016847 Steiner Jan 2013 A1
20130028443 Pance Jan 2013 A1
20130163772 Kobayashi Jun 2013 A1
20130182866 Kobayashi Jul 2013 A1
20130185061 Arvanaghi Jul 2013 A1
20130259254 Xiang Oct 2013 A1
20130315413 Yamakawa Nov 2013 A1
20130332157 Lyengar et al. Dec 2013 A1
20140153744 Brannmark Jun 2014 A1
20140200887 Nakadai Jul 2014 A1
20150055790 Kawakami Feb 2015 A1
20150065788 Rapoport Mar 2015 A1
20150104026 Kappus et al. Apr 2015 A1
20150139435 Forrest May 2015 A1
20150245137 Sugano Aug 2015 A1
20150341722 Iyengar Nov 2015 A1
20150348530 Findlay Dec 2015 A1
20160269828 Smith et al. Sep 2016 A1
20160365079 Scherrer Dec 2016 A1
20160381453 Ushakov Dec 2016 A1
20170256250 Krasnov Sep 2017 A1
20170360347 Bowles Dec 2017 A1
20180039478 Sung Feb 2018 A1
20180040338 Schiro Feb 2018 A1
20180047126 Falkenstern Feb 2018 A1
20180233161 Kagoshima Aug 2018 A1
Foreign Referenced Citations (11)
Number Date Country
33335210 Apr 1985 DE
10 2014 111 365 Feb 2016 DE
10 2014 111365 Feb 2016 DE
102014111365 Feb 2016 DE
H05 181488 Jul 1993 JP
H08 144390 Jun 1996 JP
2011-123141 Jun 2011 JP
WO2000047012 Aug 2000 WO
2009156928 Dec 2009 WO
WO 2012007746 Jan 2012 WO
WO 2016116330 Jul 2016 WO
Non-Patent Literature Citations (42)
Entry
Vorlander, Matreial Data the basic parameters of acoustic material, 2007.
Wenger, Acoustic probem solution, 2000.
HermanMiller, Sound Masking in the Office,2003.
Arai et al, Effects of suppressing steady state portions of speech on intelligibility in reverberant environments, AST, 2002.
Wikipedia—Sound Masking, retrieved Mar. 2, 2016, 36 pages. https://en.wikipedia.org/wiki/Sound_masking.
U.S. Appl. No. 15/057,890, filed Mar. 1, 2016, Krasnov et al.
U.S. Appl. No. 15/057,842, filed Mar. 1, 2016, Krasnov et al.
Forrest et al., “Effects of white noise masking and low pass filtering on speech kinematics,” J. Speech Hear. Res. 29, Dec. 1986, pp. 549-562.
Simon Arnfield, “Emotional stress and speech tempo variability.” Proc. ESCA/NATO Workshop on Speech Under Stress, Lisbon, Portugal, Sep. 14-15, 1995, 3 pages. http://www.isca-speech.org/archive_open/archive_papers/sus_95/sus5_013.pdf.
Richard M. Warren, “Perceptual Restoration of Missing Speech Sounds,” Science, New Series, vol. 167, No. 3917, Jan. 23, 1970, 3 pages. http://web.cse.ohio-state.edu/˜dwang/teaching/cse788/papers/Warren70.pdf.
Makio Kashino, “Phonemic Restoration: The Brain Creates Missing Speech Sounds,” Acoustical Science and Technology, Jan. 2006, 5 pages. https://www.researchgate.net/publication/252169039_Phonemic_restoration_The_brain_creates_missing_speech_sounds.
R. Carhart et al., “Perceptual Masking of Spondees by Combinations of Talkers,” The Journal of Acoustical Society of America, 1975, 2 pages. http://asa.scitation.org/doi/pdf/10.1121/1.2002082.
Yi Hu et al., “Effects of Early and Late Reflections on Intelligibility of Reverberated Speech by Cochlear Implant Listeners,” Jan. 2014, 7 pages. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3874051/.
Michael Rugg et al., “How Does Background Noise Affect our Concentration?” Jan. 2010, 7 pages. https://www.scientificamerican.com/article/ask-the-brains-background-noise/#.
Adelbert W. Bronkhorst, “The Cocktail Party Phenomenon: A Review of Research on Speech Intelligibility in Multiple-Talker Conditions,” Acta Acustica United with Acustica, vol. 86, Jan. 2000, 13 pages. https://www.researchgate.net/publication/230739432_The_Cocktail_Party_Phenomenon_A_Review_of_Research_on_Speech_Intelligibility_in_Multiple-Talker_Conditions.
Jungsoo Kim et al., “Workspace Satisfaction: The Privacy-Communication Trade-off in Open-Plan Offices,” Journal of Environmental Psychology. UC Berkeley: Center for the Built Environment, Jun. 2013, 22 pages. http://escholarship.org/uc/item/2gq017pb.
Manna Navai et al., “Acoustic Satisfaction in Open-Plan Offices: Review and Recommendation,” National Research Council Canada, Institute for Research in Construction, IRC-RR-151, Jul. 17, 2003, 24 pages. https://www.researchgate.net/publication/44063658_Acoustic_Satisfaction_in_Open-Plan_Offices_Review_and_Recommendations.
U.S. Appl. No. 15/459,220, filed Mar. 15, 2016, Krasnov.
U.S. Appl. No. 15/459,273, filed Mar. 15, 2016, Krasnov.
U.S. Appl. No. 15/459,307, filed Mar. 15, 2016, Krasnov.
U.S. Appl. No. 15/459,352, filed Mar. 15, 2016, Krasnov.
Moeller, Retrofitting Sound Masking Improving Speech Privacy and Noise Control in Occupied Spaces, Feb. 2014, 4 pages.
Bao et al, Active Acoustic Control of Noise Transmission Through Double Walls Effects of Mechanical Paths, JSV, Feb. 1998, 4 pages.
Kaiser, Active Control of Sound Transmission through a Double Wall Structure, 2001, 249 pages.
Taylor et al, Sound Masking Systems, Atlas Sound, 2000, 56 pages.
Boothroyd, A., Mulhearn, B., Gong, J., and Ostroff, J., “Effects of spectral smearing on phoneme and word recognition,” J. Acoust. Soc. Am. 100, Sep. 1996, 1807-1818.
Childers, D.G. and Wu, K., “Gender recognition from speech. Part II: Fine Analysis,” J. Acoust. Soc. Am. 90, Oct. 1991, 1841-1856.
DeLoach, A., “Tuning the cognitive environment: Sound masking with “natural” sounds in open-plan offices,” J. Acoust. Soc. Am. 137, Apr. 2015, 2291-2293.
Festen, J.M., “Effects of fluctuating noise and interfering speech on the speech-reception threshold for impared and normal hearing,” J. Acoust. Soc. Am. 88, Oct. 1990, 1725-1736.
Festen, J.M., “Contributions of comodulation masking release and temporal resolution to the speech-reception threshold masked by an interfering voice,” J. Acoust. Soc. Am. 94, Sep. 1993, 1295-1300.
Plomp, R., “Auditory handicap of hearing impairment and the limited benefit of hearing aids,” J. Acoust. Soc. Am. 63, Feb. 1978, 533-549.
Rosen, S. and Fourcin, A., “Frequency Selective and the Perception of Speech,” Frequency Selectivity of Hearing, edited by B.C.J. Moore (AP London), (1986), pp. 373-487.
Simpson, A., “Phonetic differences between male and female speech,” Language and Linguistics Compass 3/2, Mar. 2009, 621-640.
Ter Keurs, M., Festen, J.M., and Plomp, R., “Effect of spectral envelope smearing on speech reception. I,” J. Acoust. Soc. Am. 91, May 1992, 2872-2880.
PCT International Search Report for PCT/US2017/018836 dated May 15, 2017.
UCSC, “Room Modes,” May 2, 2016, 4 pages.
Bolt, Theory of speech masking by reverberation, JASA, Jun. 2005, 2 pages.
Noxon, Coherent and Incoherent Diffusion, Sep. 1990, 10 pages.
Wilson, Rhonda J. “The Loudspeaker—Room Interface—Controlling Excitation of Room Modes”, AES Conference May 23, 2003 pp. 1-14.
Ndo, G. et al., “An Hybrid Approach of Low Frequency Room Equalization: Notch Filters based on Common Acoustical Pole Modeling”, 2007 15th EP Signal Processing Sep. 3, 2007, pp. 1600-1604.
Assmann (“The perception of Speech under Adverse Conditions”, p. 231-308. https://pdfs.semanticscholar.org/f9e9/75030e84f2181b92cacl 656f5f796f3c0c3e.pdf).
Green et al.; “A Method of Enhancing Speech Privacy”, NOISE-CON; Jun. 12-14, 2017; pp. 479-482.
Related Publications (1)
Number Date Country
20170256250 A1 Sep 2017 US