The present invention provides for a system and apparatus for generating a real time head related audio transfer function. Specifically, unique structural components are utilized in connection with a microphone to reproduce certain acoustic characteristics of the human pinna in order to facilitate the communication of the location of a sound in three dimensional space to a user. The invention may further utilize an audio processor to digitally process the head related audio transfer function.
Human beings have just two ears, but can locate sounds in three dimensions, in distance and in direction. This is possible because the brain, the inner ears, and the external ears (pinna) work together to make inferences about the location of a sound. The location of a sound is estimated by taking cues derived from one ear (monoaural cues), as well as by comparing the difference between the cues received in both ears (binaural cues).
Binaural cues relate to the differences of arrival and intensity of the sound between the two ears, which assist with the relative localization of a sound source. Monoaural cues relate to the interaction between the sound source and the human anatomy, in which the original sound is modified by the external ear before it enters the ear canal for processing by the auditory system. The modifications encode the source location relative to the ear location and are known as head-related transfer functions (HRTF).
In other words, HRTFs describe the filtering of a sound source before it is perceived at the left and right ear drums, in order to characterize how a particular ear receives sound from a particular point in space. These modifications may include the shape of the listener's ear, the shape of the listener's head and body, the acoustical characteristics of the space in which the sound is played, and so forth. All these characteristics together influence how a listener can accurately tell what direction a sound is coming from. Thus, a pair of HRTFs accounting for all these characteristics, generated by the two ears, can be used to synthesize a binaural sound and accurately recognize it as originating from a particular point in space.
HRTFs have wide ranging applications, from virtual surround sound in media and gaming, to hearing protection in loud noise environments, and hearing assistance for the hearing impaired. Particularly, in fields hearing protection and hearing assistance, the ability to record and reconstruct a particular user's HRTF presents several challenges as it must occur in real time. In the case of an application for hearing protection in high noise environments, heavy hearing protection hardware must be worn over the ears in the form of bulky headphones, thus, if microphones are placed on the outside of the headphones, the user will hear the outside world but will not receive accurate positional data because the HRTF is not being reconstructed. Similarly, in the case of hearing assistance for the hearing impaired, a microphone is similarly mounted external to the hearing aid, and any hearing aid device that fully blocks a user's ear canal will not accurately reproduce that user's HRTF.
Thus, there is a need for an apparatus and system for reconstructing a user's HRTF in accordance to the user's physical characteristics, in order to accurately relay positional sound information to the user in real time.
The present invention meets the existing needs described above by providing for an apparatus, system, and method for generating a head related audio transfer function. The present invention also provides for the ability to enhance audio in real-time and tailors the enhancement to the physical characteristics of a user and the acoustic characteristics of the external environment.
Accordingly, in initially broad terms, an apparatus directed to the present invention, also known as an HRTF generator, comprises an external manifold and internal manifold. The external manifold is exposed at least partially to an external environment, while the internal manifold is disposed substantially within an interior of the apparatus and/or a larger device or system housing said apparatus.
The external manifold comprises an antihelix structure, a tragus structure, and an opening. The opening is in direct air flow communication with the outside environment, and is structured to receive acoustic waves. The tragus structure is disposed to partially enclose the opening, such that the tragus structure will partially impede and/or affect the characteristics of the incoming acoustic waves going into the opening. The antihelix structure is disposed to further partially enclose the tragus structure as well as the opening, such that the antihelix structure will partially impede and/or affect the characteristics of the incoming acoustic waves flowing onto the tragus structure and into the opening. The antihelix and tragus structures may comprise partial domes or any variation of partial-domes comprising a closed side and an open side. In a preferred embodiment, the open side of the antihelix structure and the open side of the tragus structure are disposed in confronting relation to one another.
The opening of the external manifold is connected to and in air flow communication with an opening canal inside the external manifold. The opening canal may be disposed in a substantially perpendicular orientation relative to the desired orientation of the user. The opening canal is in further air flow communication with an auditory canal, which is formed within the internal manifold but also be formed partially in the external manifold.
The internal manifold comprises the auditory canal and a microphone housing. The microphone housing is attached or connected to an end of the auditory canal on the opposite end to its connection with the opening canal. The auditory canal, or at least the portion of the portion of the auditory canal, may be disposed in a substantially parallel orientation relative to the desired listening direction of the user. The microphone housing may further comprise a microphone mounted against the end of the auditory canal. The microphone housing may further comprise an air cavity behind the microphone on an end opposite its connection to the auditory canal, which may be sealed with a cap.
In at least one embodiment, the apparatus or HRTF generator may form a part of a larger system. Accordingly, the system may comprise a left HRTF generator, a right HRTF generator, a left preamplifier, a right preamplifier, an audio processor, a left playback module, and a right playback module.
As such, the left HRTF generator may be structured to pick up and filter sounds to the left of a user. Similarly, the right HRTF generator may be structured to pick up and filter sounds to the right of the user. A left preamplifier may be structured and configured to increase the gain of the filtered sound of the left HRTF generator. A right preamplifier may be structured and configured to increase the gain of the filtered sound of the right HRTF generator. The audio processor may be structured and configured to process and enhance the audio signal received from the left and right preamplifiers, and then transmit the respective processed signals to each of the left and right playback modules. The left and right playback modules or transducers are structured and configured to convert the electrical signals into sound to the user, such that the user can then perceive the filtered and enhanced sound from the user's environment, which includes audio data that allows the user to localize the source of the originating sound.
In at least one embodiment, the system of the present invention may comprise a wearable device such as a headset or headphones having the HRTF generator embedded therein. The wearable device may further comprise the preamplifiers, audio processor, and playback modules, as well as other appropriate circuitry and components.
In a further embodiment, a method for generating a head related audio transfer function may be used in accordance with the present invention. As such, external sound is first filtered through an exterior of an HRTF generator which may comprise a tragus structure and an antihelix structure. The filtered sound is then passed to the interior of the HRTF generator, such as through the opening canal and auditory canal described above to create an input sound. The input sound is received at a microphone embedded within the HRTF generator adjacent to and connected to the auditory canal in order to create an input signal. The input signal is amplified with a preamplifier in order to create an amplified signal. The amplified signal is then processed with an audio processor, in order to create a processed signal. Finally, the processed signal is transmitted to the playback module in order to relay audio and/or locational audio data to a user.
In certain embodiments, the audio processor may receive the amplified signal and first filter the amplified signal with a high pass filter. The high pass filter, in at least one embodiment, is configured to remove ultra-low frequency content from the amplified signal resulting in the generation of a high pass signal.
The high pass signal from the high pass filter is then filtered through a first filter module to create a first filtered signal. The first filter module is configured to selectively boost and/or attenuate the gain of select frequency ranges in an audio signal, such as the high pass signal. In at least one embodiment, the first filter module boosts frequencies above a first frequency, and attenuates frequencies below a first frequency.
The first filtered signal from the first filter module is then modulated with a first compressor to create a modulated signal. The first compressor is configured for the dynamic range compression of a signal, such as the first filtered signal. Because the first filtered signal boosted higher frequencies and attenuated lower frequencies, the first compressor may, in at least one embodiment, be configured to trigger and adjust the higher frequency material, while remaining relatively insensitive to lower frequency material.
The modulated signal from the first compressor is then filtered through a second filter module to create a second filtered signal. The second filter module is configured to selectively boost and/or attenuate the gain of select frequency ranges in an audio signal, such as the modulated signal. In at least one embodiment, the second filter module is configured to be of least partially inverse relation relative to the first filter module. For example, if the first filter module boosted content above a first frequency by +X dB and attenuated content below a first frequency by −Y dB, the second filter module may then attenuate the content above the first frequency by −X dB, and boost the content below the first frequency by +Y dB. In other words, the purpose of the second filter module in one embodiment may be to “undo” the gain adjustment that was applied by the first filter module.
The second filtered signal from the second filter module is then processed with a first processing module to create a processed signal. In at least one embodiment, the first processing module may comprise a peak/dip module. In other embodiments, the first processing module may comprise both a peak/dip module and a first gain element. The first gain element may be configured to adjust the gain of the signal, such as the second filtered signal. The peak/dip module may be configured to shape the signal, such as to increase or decrease overshoots or undershoots in the signal.
The processed signal from the first processing module is then split with a band splitter into a low band signal, a mid band signal and a high band signal. In at least one embodiment, each band may comprise the output of a fourth order section, which may be realized as the cascade of second order biquad filters.
The low band signal is modulated with a low band compressor to create a modulated low band signal, and the high band signal is modulated with a high band compressor to create a modulated high band signal. The low band compressor and high band compressor are each configured to dynamically adjust the gain of a signal. Each of the low band compressor and high band compressor may be computationally and/or configured identically as the first compressor.
The modulated low band signal, the mid band signal, and the modulated high band signal are then processed with a second processing module. The second processing module may comprise a summing module configured to combine the signals. The summing module in at least one embodiment may individually alter the gain of each of the modulated low band, mid band, and modulated high band signals. The second processing module may further comprise a second gain element. The second gain element may adjust the gain of the combined signal in order to create a processed signal that is transmitted to the playback module.
The method described herein may be configured to capture and transmit locational audio data to a user in real time, such that it can be utilized as a hearing aid, or in loud noise environments to filter out loud noises.
In a further embodiment for generating a head related audio transfer function, the HRTF generator, rather than being embedded in a wearable device, may actually be configured as the wearable device itself. In the preferred embodiment, the HRTF generator will be configured into at least one, but most preferably two, in-ear assembly apparatus(es). The at least one in-ear assembly is operatively positioned, or in an operative position, when it is disposed on a user's ear, or worn by a user.
The in-ear assembly may comprise at least one shell or chamber to house the various HRTF structures, and provide an exterior surface to place or attach structures on the outside. The in-ear assembly may comprise a primary chamber proximal to a user's ear(s) and a secondary chamber distal to a user's ear(s), when in an operative position.
The exterior of the in-ear assembly's secondary chamber comprises a windscreen structure, an antihelix structure, a tragus structure, and a microphone opening or aperture. The windscreen structure, antihelix structure, and tragus structures can be removed from the exterior of the secondary chamber, providing a means of replacing the structures. Also, the windscreen structure, antihelix structure, and tragus structures may vary in size and shape.
One of the many purposes of the windscreen structure is to reduce wind and noise interference to ensure the in-ear assembly receives high-quality and undisturbed sound and audio signals from the external environment. The windscreen structure can attach to the exterior of the secondary chamber via at least one connecting point. A variety of materials may be utilized, but in a preferred embodiment open cell foam is housed within the windscreen structure to ensure the quality of the incoming signals. The windscreen structure and the material housed inside the windscreen structure will partially cover the antihelix structure, the tragus structure, and the microphone opening or aperture. The antihelix structure and the tragus structure can also cover, partially or fully, the microphone aperture in order to mimic the structure of a human ear. The microphone aperture is in direct air flow communication with the external environment via an opening and microphone channel. The microphone may be attached to an end of the microphone channel. In this way, the microphone will receive the external noise that filters through the windscreen structure, the antihelix structure, tragus structure, microphone aperture, and microphone channel, ensuring that the audio signal produced by the HRTF Generator will include the “directionality” that occurs when a human ear detects sound from a point in space.
The microphone disposed within the end of the microphone channel is located inside the in-ear assembly, and may be located within the secondary or primary chamber of a preferred embodiment of the in-ear assembly. The microphone channel and the microphone may be in a substantially parallel orientation, or alternatively, perpendicular orientation, relative to the listening direction of a user when wearing the in-ear assembly. The microphone is located adjacent to, or even directly connected to, a playback module, or one or more speakers or transducers, which transmits audio input signals to the playback module, and in turn the playback module transmits an audio output signal to a user via an auditory channel connected to a user's ear. In a preferred embodiment, the in-ear assembly will also comprise a preamplifier to amplify an audio input signal received from the microphone, and an audio processor to receive the amplified signal for processing. The audio processor will then transmit a processed, higher quality signal to the playback module. The playback module may be housed, and there may also be speaker drivers. The playback module may be mounted flush on an end of the auditory channel, or there may be an air cavity between the playback module and the end of the auditory channel. The auditory channel is disposed within the user's ear when the in-ear assembly is in an operative position, and a foam ear tip or other material may be attached to the end of the auditory channel to protect a user's ear(s) as well as insulate the user's ear(s) from ambient noise. The speaker(s) or playback module(s) is located inside the in-ear assembly, and in one embodiment, the playback module is located in the primary chamber of the in-ear assembly.
The microphone that receives audio input from the external environment and the playback module that sends audio output to the user are isolated from one another in a preferred embodiment, in order to avoid unwanted feedback. In one preferred embodiment, the interior of the in-ear assembly contains a baffle isolation structure that transverses the interior of the in-ear assembly, creating a physical isolation between the microphone and the playback module. In alternative embodiments, an acoustic isolation can be created without a physical barrier between the microphone and playback module. The isolation baffle achieves the goal of creating at least a 30 decibel noise isolation between the microphone and the playback module. Thus, the isolation of the microphone and playback module provides for reduction in noise interference and feedback noise between the microphone and playback module in a miniaturized apparatus such as the in-ear assembly, which has its exterior, or more specifically, the secondary chamber, exposed to the external environment's sound waves.
On the exterior of in-ear assembly, or the exterior of the primary chamber, is a stabilizing assembly or wingtip assembly, to ensure the in-ear assembly is securely placed on a user's ear, when in an operative position, and to provide the proper orientation(s) for the various structures, by way of example, the antihelix structure, to receive the input signals. The stabilizing assembly may comprise of a circular collar that is disposed about the exterior of the primary chamber, and a concha-shaped structure connected to the circular collar that is dimensioned and configured to be disposed on the external ear of a user when in an operative position, preferably within the concha. As such, the tragus and anti-helix structure can be oriented properly for generation of accurate HRTF signals, otherwise an improper orientation may generate misleading HRTF signals for the user.
In one embodiment, at least one in-ear assembly may form a system. In one embodiment of the system, the system may comprise a left ear-in assembly structured to pick up and filter sounds incoming from the left side of a user. The right in-ear assembly may be structured to pick up and filter sounds incoming from the right side of the user. A left preamplifier within the left in-ear assembly may be structured and configured to increase the gain of the filtered sound of the left in-ear assembly. A right preamplifier within the right in-ear assembly may be structured and configured to increase the gain of the filtered sound of the right in-ear assembly. The audio processor(s) located inside the left and right in-ear assemblies, or housed in a separate structure, may be configured to process and enhance the audio signal received from the left and right preamplifiers, and then transmit the respective processed signals to each of the left and right playback modules located in the left and right in-ear assemblies. The left and right playback modules or transducers are structured and configured to convert the electrical signals into sound waves perceptible by the user, such that the user can then perceive the filtered and enhanced sound form the user's environment, which includes the “directional” audio data that allows the user to localize the originating sound. The various structures, such as but not limited to the preamplifier(s), the audio processor(s), and the playback module(s) may be housed in the in-ear assembly(s) or in a separate interconnecting assembly attached to the in-ear assembly(s).
In at least one embodiment, the system of the present invention may comprise an in-ear assembly for each of a user's ear, as well as an interconnecting member which may further comprise the preamplifier(s), audio processor(s), playback module(s), as well as other appropriate circuitry and components. The interconnecting member may be worn around the neck, and connected to the in-ear assemblies, or in-ear bud assemblies, by wire connections, or may be wireless by use of Bluetooth or other suitable radio-frequency transmission technology. The interconnecting member may be formed from a flexible back section and stiff side sections. The interconnecting member may house a printed circuit board having various componentry, such as the audio processor. The interconnecting member can provide a user with volume control functions, providing a user a level of control with which to mix between environmental audio signals and voice communication signals. In one embodiment, the interconnecting member may have a listen mode and mute mode, providing a user with the ability to mute the microphone that receives environmental audio signals, allowing the user to receive and listen to phone calls, thereby providing a means of communication. The interconnecting member can also house a removable battery to charge the apparatus.
As can be seen, one particular use for the present invention lies in hearing protection systems for use in environments where situational awareness is critical. With suitable sound insulation and/or “anti-noise” signal generation capabilities, the system of the present invention provides a suitable noise-reduction assembly for the protection of the user's hearing against loud noises. Additionally, the microphone assembly allows external audio to be detected and delivered to at a safer level than would otherwise be perceived by the user. Finally, the tragus and anti-helix structure allow the “directional” information of ambient noises to be captured and faithfully recreated to the user by way of an HRTF signal. By way of example, the present invention may be useful in construction sites, where the need for hearing protection and situational awareness is a key component of on-site safety. By utilizing the present invention, user's need not sacrifice situational awareness for hearing protection.
These and other objects, features and advantages of the present invention will become clearer when the drawings as well as the detailed description are taken into consideration.
For a fuller understanding of the nature of the present invention, reference should be had to the following detailed description taken in connection with the accompanying drawings in which:
Like reference numerals refer to like parts throughout the several views of the drawings.
As illustrated by the accompanying drawings, the present invention is directed to an apparatus, system, and method for generating a head related audio transfer function for a user. Specifically, some embodiments relate to capturing surrounding sound in the external environment in real time, filtering that sound through unique structures formed on the apparatus in order to generate audio positional data, and then processing that sound to enhance and relay the positional audio data to a user, such that the user can determine the origination of the sound in three dimensional space.
As schematically represented,
The external manifold 110 may comprise a hexahedron shape having six faces. In at least one embodiment, the external manifold 110 is substantially cuboid. The external manifold 110 may comprise at least one surface that is concave or convex, such as an exterior surface exposed to the external environment. The internal manifold 120 may comprise a substantially cylindrical shape, which may be at least partially hollow. The external manifold 110 and internal manifold 120 may comprise sound dampening or sound proof materials, such as various foams, plastics, and glass known to those skilled in the art.
Drawing attention to
In at least one embodiment, the antihelix structure 101 comprises a partial dome structure having a closed side 105 and an open side 106. In a preferred embodiment, the open side 106 faces the preferred listening direction 104, and the closed side 105 faces away from the preferred listening direction 104. The tragus structure 102 may also comprise a partial dome structure having a closed side 107 and an open side 108. In a preferred embodiment, the open side 108 faces away from the preferred listening direction 104, while the closed side 107 faces towards the preferred listening direction 104. In other embodiments, the open side 106 of the antihelix structure 101 may be in direct confronting relation to the open side 108 of the tragus structure 102, regardless of the preferred listening direction 104.
Partial dome as defined for the purposes of this document may comprise a half-dome structure or any combination of partial-dome structures. For instance, the anti-helix structure 101 of
In at least one embodiment, the antihelix structure 101 and tragus structure 102 may be modular, such that different sizes or shapes (variations of different partial domes or partial-domes) may be swapped out based on a user's preference for particular acoustic characteristics.
Drawing attention now to
As previously discussed, the internal manifold 120 is formed wholly or substantially within an interior of the apparatus, such that it is not exposed directly to the outside air and will not be substantially affected by the external environment. In at least one embodiment, the auditory canal 121 formed within at least a portion of the internal manifold 121, will be disposed in a substantially parallel orientation relative to desired listening direction 104 of the user. In a preferred embodiment, the auditory canal comprises a length that is greater than two times its diameter.
A microphone housing 122 is attached to an end of the auditory canal 121. Within the microphone housing 122, a microphone generally at 123, not shown, is mounted against the end of the auditory canal 121. In at least one embodiment, the microphone 123 is mounted flush against the auditory canal 121, such that the connection may be substantially air tight to avoid interference sounds. In a preferred embodiment, an air cavity generally at 124 is created behind the microphone and at the end of the internal manifold 120. This may be accomplished by inserting the microphone 123 into the microphone housing 122, and then sealing the end of the microphone housing, generally at 124, with a cap. The cap may be substantially air tight in at least one embodiment. Different gasses having different acoustic characteristics may be used within the air cavity.
In at least one embodiment, apparatus 100 may form a part of a larger system 300 as illustrated in
The left and right HRTF generators 100 and 100′ may comprise the apparatus 100 described above, each having unique structures such as the antihelix structure 101 and tragus structure 102. Accordingly, the HRTF generators 100/100′ may be structured to generate a head related audio transfer function for a user, such that the sound received by the HRTF generators 100/100′ may be relayed to the user to accurately communicate position data of the sound. In other words, the HRTF generators 100/100′ may replicate and replace the function of the user's own left and right ears, where the HRTF generators would collect sound, and perform respective spectral transformations or a filtering process to the incoming sounds to enable the process of vertical localization to take place.
A left preamplifier 210 and right preamplifier 210′ may then be used to enhance the filtered sound coming from the HRTF generators, in order to enhance certain acoustic characteristics to improve locational accuracy, or to filter out unwanted noise. The preamplifiers 210/210′ may comprise an electronic amplifier, such as a voltage amplifier, current amplifier, transconductance amplifier, transresistance amplifier and/or any combination of circuits known to those skilled in the art for increasing or decreasing the gain of a sound or input signal. In at least one embodiment, the preamplifier comprises a microphone preamplifier configured to prepare a microphone signal to be processed by other processing modules. As it may be known in the art, microphone signals sometimes are too weak to be transmitted to other units, such as recording or playback devices with adequate quality. A microphone preamplifier thus increases a microphone signal to the line level by providing stable gain while preventing induced noise that might otherwise distort the signal.
Audio processor 230 may comprise a digital signal processor and amplifier, and may further comprise a volume control. Audio processor 230 may comprise a processor and combination of circuits structured to further enhance the audio quality of the signal coming from the microphone preamplifier, such as but not limited to shelf filters, equalizers, modulators. For example, in at least one embodiment the audio processor 230 may comprise a processor that performs the steps for processing a signal as taught by the present inventor's U.S. Pat. No. 8,160,274, the entire disclosure of which is incorporated herein by reference. Audio processor 230 may incorporate various acoustic profiles customized for a user and/or for an environment, such as those described in the present inventor's U.S. Pat. No. 8,565,449, the entire disclosure of which is incorporated herein by reference. Audio processor 230 may additionally incorporate processing suitable for high noise environments, such as those described in the present inventor's U.S. Pat. No. 8,462,963, the entire disclosure of which is incorporated herein by reference. Parameters of the audio processor 230 may be controlled and modified by a user via any means known to one skilled in the art, such as by a direct interface or a wireless communication interface.
The left playback module 230 and right playback module 230′ may comprise headphones, earphones, speakers, or any other transducer known to one skilled in the art. The purpose of the left and right playback modules 230/230′ is to convert the electrical audio signal from the audio processor 230 back into perceptible sound for the user. As such, a moving-coil transducer, electrostatic transducer, electret transducer, or other transducer technologies known to one skilled in the art may be utilized.
In at least one embodiment, the present system 200 comprises a device 200 as generally illustrated at
In a further embodiment as illustrated in
In a preferred embodiment of the present invention, the method of
In at least one embodiment, the method of
With regard to
The input device 1010 is at least partially structured or configured to transmit an input audio signal 2010, such as an amplified signal from a left or right preamplifier 210, 210′, into the system 1000 of the present invention, and in at least one embodiment into the high pass filter 1110.
The high pass filter 1110 is configured to pass through high frequencies of an audio signal, such as the input signal 2010, while attenuating lower frequencies, based on a predetermined frequency. In other words, the frequencies above the predetermined frequency may be transmitted to the first filter module 3010 in accordance with the present invention. In at least one embodiment, ultra-low frequency content is removed from the input audio signal, where the predetermined frequency may be selected from a range between 300 Hz and 3 kHz. The predetermined frequency however, may vary depending on the source signal, and vary in other embodiments to comprise any frequency selected from the full audible range of frequencies between 20 Hz to 20 kHz. The predetermined frequency may be tunable by a user, or alternatively be statically set. The high pass filter 1110 may further comprise any circuits or combinations thereof structured to pass through high frequencies above a predetermined frequency, and attenuate or filter out the lower frequencies.
The first filter module 3010 is configured to selectively boost or attenuate the gain of select frequency ranges within an audio signal, such as the high pass signal 2110. For example, and in at least one embodiment, frequencies below a first frequency may be adjusted by ±X dB, while frequencies above a first frequency may be adjusted by ±Y dB. In other embodiments, a plurality of frequencies may be used to selectively adjust the gain of various frequency ranges within an audio signal. In at least one embodiment, the first filter module 3010 may be implemented with a first low shelf filter 1120 and a first high shelf filter 1130, as illustrated in
The first compressor 1140 is configured to modulate a signal, such as the first filtered signal 4010. The first compressor 1120 may comprise an automatic gain controller. The first compressor 1120 may comprise standard dynamic range compression controls such as threshold, ratio, attack and release. Threshold allows the first compressor 1120 to reduce the level of the filtered signal 2110 if its amplitude exceeds a certain threshold. Ratio allows the first compressor 1120 to reduce the gain as determined by a ratio. Attack and release determines how quickly the first compressor 1120 acts. The attack phase is the period when the first compressor 1120 is decreasing gain to reach the level that is determined by the threshold. The release phase is the period that the first compressor 1120 is increasing gain to the level determined by the ratio. The first compressor 1120 may also feature soft and hard knees to control the bend in the response curve of the output or modulated signal 2120, and other dynamic range compression controls appropriate for the dynamic compression of an audio signal. The first compressor 1120 may further comprise any device or combination of circuits that is structured and configured for dynamic range compression.
The second filter module 3020 is configured to selectively boost or attenuate the gain of select frequency ranges within an audio signal, such as the modulated signal 2140. In at least one embodiment, the second filter module 3020 is of the same configuration as the first filter module 3010. Specifically, the second filter module 3020 may comprise a second low shelf filter 1150 and a second high shelf filter 1160. In certain embodiments, the second low shelf filter 1150 may be configured to filter signals between 100 Hz and 3000 Hz, with an attenuation of between −5 dB to −20 dB. In certain embodiments the second high shelf filter 1160 may be configured to filter signals between 100 Hz and 3000 Hz, with a boost of between +5 dB to +20 dB.
The second filter module 3020 may be configured in at least a partially inverse configuration to the first filter module 3010. For instance, the second filter module may use the same frequency, for instance the first frequency, as the first filter module. Further, the second filter module may adjust the gain inversely to the gain or attenuation of the first filter module, of content above the first frequency. Similarly second filter module may also adjust the gain inversely to the gain or attenuation of the of the first filter module, of content below the first frequency. In other words, the purpose of the second filter module in one embodiment may be to “undo” the gain adjustment that was applied by the first filter module.
The first processing module 3030 is configured to process a signal, such as the second filtered signal 4020. In at least one embodiment, the first processing module 3030 may comprise a peak/dip module, such as 1180 represented in
The band splitter 1190 is configured to split a signal, such as the processed signal 4030. In at least one embodiment, the signal is split into a low band signal 2200, a mid band signal 2210, and a high band signal 2220. Each band may be the output of a fourth order section, which may be further realized as the cascade of second order biquad filters. In other embodiments, the band splitter may comprise any combination of circuits appropriate for splitting a signal into three frequency bands. The low, mid, and high bands may be predetermined ranges, or may be dynamically determined based on the frequency itself, i.e. a signal may be split into three even frequency bands, or by percentage. The different bands may further be defined or configured by a user and/or control mechanism.
A low band compressor 1300 is configured to modulate the low band signal 2200, and a high band compressor 1310 is configured to modulate the high band signal 2220. In at least one embodiment, each of the low band compressor 1300 and high band compressor 1310 may be the same as the first compressor 1140. Accordingly, each of the low band compressor 1300 and high band compressor 1310 may each be configured to modulate a signal. Each of the compressors 1300, 1310 may comprise an automatic gain controller, or any combination of circuits appropriate for the dynamic range compression of an audio signal.
A second processing module 3040 is configured to process at least one signal, such as the modulated low band signal 2300, the mid band signal 2210, and the modulated high band signal 2310. Accordingly, the second processing module 3040 may comprise a summing module 1320 configured to combine a plurality of signals. The summing module 1320 may comprise a mixer structured to combine two or more signals into a composite signal. The summing module 1320 may comprise any circuits or combination thereof structured or configured to combine two or more signals. In at least one embodiment, the summing module 1320 comprises individual gain controls for each of the incoming signals, such as the modulated low band signal 2300, the mid band signal 2210, and the modulated high band signal 2310. In at least one embodiment, the second processing module 3040 may further comprise a second gain element 1330. The second gain element 1330, in at least one embodiment, may be the same as the first gain element 1170. The second gain element 1330 may thus comprise an amplifier or multiplier circuit to adjust the signal, such as the combined signal, by a predetermined amount.
The output device 1020 may comprise the left playback module 230 and/or right playback module 230′.
As diagrammatically represented,
Accordingly, an input audio signal, such as the amplified signal, is first filtered, as in 5010, with a high pass filter to create a high pass signal. The high pass filter is configured to pass through high frequencies of a signal, such as the input signal, while attenuating lower frequencies. In at least one embodiment, ultra-low frequency content is removed by the high-pass filter. In at least one embodiment, the high pass filter may comprise a fourth-order filter realized as the cascade of two second-order biquad sections. The reason for using a fourth order filter broken into two second order sections is that it allows the filter to retain numerical precision in the presence of finite word length effects, which can happen in both fixed and floating point implementations. An example implementation of such an embodiment may assume a form similar to the following:
The above computation comprising five multiplies and four adds is appropriate for a single channel of second-order biquad section. Accordingly, because the fourth-order high pass filter is realized as a cascade of two second-order biquad sections, a single channel of fourth order input high pass filter would require ten multiples, four memory locations, and eight adds.
The high pass signal from the high pass filter is then filtered, as in 5020, with a first filter module to create a first filtered signal. The first filter module is configured to selectively boost or attenuate the gain of select frequency ranges within an audio signal, such as the high pass signal. Accordingly, the first filter module may comprise a second order low shelf filter and a second order high shelf filter in at least one embodiment. In at least one embodiment, the first filter module boosts the content above a first frequency by a certain amount, and attenuates the content below a first frequency by a certain amount, before presenting the signal to a compressor or dynamic range controller. This allows the dynamic range controller to trigger and adjust higher frequency material, whereas it is relatively insensitive to lower frequency material.
The first filtered signal from the first filter module is then modulated, as in 5030, with a first compressor. The first compressor may comprise an automatic or dynamic gain controller, or any circuits appropriate for the dynamic compression of an audio signal. Accordingly, the compressor may comprise standard dynamic range compression controls such as threshold, ratio, attack and release. An example implementation of the first compressor may assume a form similar to the following:
The modulated signal from the first compressor is then filtered, as in 5040, with a second filter module to create a second filtered signal. The second filter module is configured to selectively boost or attenuate the gain of select frequency ranges within an audio signal, such as the modulated signal. Accordingly, the second filter module may comprise a second order low shelf filter and a second order high shelf filter in at least one embodiment. In at least one embodiment, the second filter module boosts the content above a second frequency by a certain amount, and attenuates the content below a second frequency by a certain amount. In at least one embodiment, the second filter module adjusts the content below the first specified frequency by a fixed amount, inverse to the amount that was removed by the first filter module. By way of example, if the first filter module boosted content above a first frequency by +X dB and attenuated content below a first frequency by −Y dB, the second filter module may then attenuate the content above the first frequency by −X dB, and boost the content below the first frequency by +Y dB. In other words, the purpose of the second filter module in one embodiment may be to “undo” the filtering that was applied by the first filter module.
The second filtered signal from the second filter module is then processed, as in 5050, with a first processing module to create a processed signal. The processing module may comprise a gain element configured to adjust the level of the signal. This adjustment, for instance, may be necessary because the peak-to-average ratio was modified by the first compressor. The processing module may comprise a peak/dip module. The peak/dip module may comprise ten cascaded second-order filters in at least one embodiment. The peak/dip module may be used to shape the desired output spectrum of the signal. In at least one embodiment, the first processing module comprises only the peak/dip module. In other embodiments, the first processing module comprises a gain element followed by a peak/dip module.
The processed signal from the first processing module is then split, as in 5060, with a band splitter into a low band signal, a mid band signal, and a high band signal. The band splitter may comprise any circuit or combination of circuits appropriate for splitting a signal into a plurality of signals of different frequency ranges. In at least one embodiment, the band splitter comprises a fourth-order band-splitting bank. In this embodiment, each of the low band, mid band, and high band are yielded as the output of a fourth-order section, realized as the cascade of second-order biquad filters.
The low band signal is modulated, as in 5070, with a low band compressor to create a modulated low band signal. The low band compressor may be configured and/or computationally identical to the first compressor in at least one embodiment. The high band signal is modulated, as in 5080, with a high band compressor to create a modulated high band signal. The high band compressor may be configured and/or computationally identical to the first compressor in at least one embodiment.
The modulated low band signal, mid band signal, and modulated high band signal are then processed, as in 5090, with a second processing module. The second processing module comprises at least a summing module. The summing module is configured to combine a plurality of signals into one composite signal. In at least one embodiment, the summing module may further comprise individual gain controls for each of the incoming signals, such as the modulated low band signal, the mid band signal, and the modulated high band signal. By way of example, an output of the summing module may be calculated by:
out=w0*low+w1*mid+w2*high
The coefficients w0, w1, and w2 represent different gain adjustments. The second processing module may further comprise a second gain element. The second gain element may be the same as the first gain element in at least one embodiment. The second gain element may provide a final gain adjustment. Finally, the second processed signal is transmitted as the output signal.
As diagrammatically represented,
Accordingly, an input audio signal is first filtered, as in 5010, with a high pass filter. The high pass signal from the high pass filter is then filtered, as in 6010, with a first low shelf filter. The signal from the first low shelf filter is then filtered with a first high shelf filter, as in 6020. The first filtered signal from the first low shelf filter is then modulated with a first compressor, as in 5030. The modulated signal from the first compressor is filtered with a second low shelf filter as in 6110. The signal from the low shelf filter is then filtered with a second high shelf filter, as in 6120. The second filtered signal from the second low shelf filter is then gain-adjusted with a first gain element, as in 6210. The signal from the first gain element is further processed with a peak/dip module, as in 6220. The processed signal from the peak/dip module is then split into a low band signal, a mid band signal, and a high band signal, as in 5060. The low band signal is modulated with a low band compressor, as in 5070. The high band signal is modulated with a high band compressor, as in 5080. The modulated low band signal, mid band signal, and modulated high band signal are then combined with a summing module, as in 6310. The combined signal is then gain adjusted with a second gain element in order to create the output signal, as in 6320.
It should be understood that the above steps may be conducted exclusively or nonexclusively and in any order. Further, the physical devices recited in the methods may comprise any apparatus and/or systems described within this document or known to those skilled in the art.
Since many modifications, variations and changes in detail can be made to the described preferred embodiment of the invention, it is intended that all matters in the foregoing description and shown in the accompanying drawings be interpreted as illustrative and not in a limiting sense. Thus, the scope of the invention should be determined by the appended claims and their legal equivalents.
In one preferred embodiment,
The in-ear assembly 400 comprises at least one chamber, shell, or chassis, which houses the various structures on the interior of the in-ear assembly 400, and provides exterior surfaces to house the structures that mimic the functions of a human ear for generating a head related audio transfer function (“HRTF”). Drawing attention to the embodiment in
As illustrated in
Drawing attention to
As illustrated in
In a preferred embodiment, as illustrated in
As illustrated in
As illustrated in
Drawing attention now to
The microphone channel 412 can be disposed in a substantially parallel orientation relative to the desired listening direction 104 of the user when the ear-in assembly 400 is worn by a user, generally illustrated in
Drawing attention to
Drawing further attention to
Furthermore, as illustrated in
In a preferred embodiment, the at least one in-ear assembly 400 also comprises the previously mentioned preamplifier 210 and audio processor 220, as schematically illustrated in
The audio processor 220 may comprise a digital signal processor and amplifier, and may further comprise a volume control. Audio processor 220 may comprise a processor and combination of circuits structured to further enhance the audio quality of the signal coming from the microphone preamplifier, such as but not limited to shelf filters, equalizers, modulators. For example, in at least one embodiment the audio processor 220 may comprise a processor that performs the steps for processing a signal as taught by the present inventor's U.S. Pat. No. 8,160,274, the entire disclosure of which is incorporated herein by reference. Audio processor 220 may incorporate various acoustic profiles customized for a user and/or for an environment, such as those described in the present inventor's U.S. Pat. No. 8,565,449, the entire disclosure of which is incorporated herein by reference. Audio processor 220 may additionally incorporate processing suitable for high noise environments, such as those described in the present inventor's U.S. Pat. No. 8,462,963, the entire disclosure of which is incorporated herein by reference. Parameters of the audio processor 220 may be controlled and modified by a user via any means known to one skilled in the art, such as by a direct interface or a wireless communication interface.
In another embodiment as illustrated in
Since many modifications, variations and changes in detail can be made to the described preferred embodiment of the invention, it is intended that all matters in the foregoing description and shown in the accompanying drawings be interpreted as illustrative and not in a limiting sense. Thus, the scope of the invention should be determined by the appended claims and their legal equivalents.
The present invention is a continuation-in-part of a previously filed, now pending application having Ser. No. 15/864,190 and a filing date of Jan. 8, 2018, which is a continuation-in-part of a previously filed application having Ser. No. 15/478,696 and a filing date of Apr. 4, 2017, which is a continuation application of a previously filed application having Ser. No. 14/485,145 and a filing date of Sep. 12, 2014, which matured into U.S. Pat. No. 9,615,189, and which is based on, and a claim of priority was made under 35 U.S.C. Section 119(e), to a provisional patent application having Ser. No. 62/035,025 and a filing date of Aug. 8, 2014, all of which are explicitly incorporated herein by reference, in their entireties. The previously filed, now pending application having Ser. No. 15/864,190, and a filing date of Jan. 8, 2018, is also a continuation-in-part of a previously filed application having Ser. No. 15/163,353 and a filing date of May 24, 2016, which matured into U.S. Pat. No. 10,069,471, and which is a continuation-in-part of Ser. No. 14/059,948, which matured into U.S. Pat. No. 9,348,904, and which is a continuation-in-part of Ser. No. 12/648,007 filed on Dec. 28, 2009, which matured into U.S. Pat. No. 8,565,449, and which is a continuation-in-part of Ser. No. 11/947,301, filed Nov. 29, 2007, which matured into U.S. Pat. No. 8,160,274, and which claims priority to U.S. Provisional Application No. 60/861,711 filed Nov. 30, 2006, each which are explicitly incorporated herein by reference, in there entireties. Further, Ser. No. 11/947,301 is a continuation-in-part of Ser. No. 11/703,216, filed Feb. 7, 2007, and which claims priority to U.S. Provisional Application No. 60/765,722 filed Feb. 7, 2006, each which are explicitly incorporated herein by reference, in their entireties. The present invention also claims priority to U.S. Provisional Application No. 62/948,409 filed on Dec. 16, 2019, which is explicitly incorporated herein by reference, in its entirety.
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