Multifunction system and method for integrated hearing and communication with noise cancellation and feedback management

Abstract
Systems, devices and methods for communication include an ear canal microphone configured for placement in the ear canal to detect high frequency sound localization cues. An external microphone positioned away from the ear canal can detect low frequency sound, such that feedback can be substantially reduced. The canal microphone and the external microphone are coupled to a transducer, such that the user perceives sound from the external microphone and the canal microphone with high frequency localization cues and decreased feedback. Wireless circuitry can be configured to connect to many devices with a wireless protocol, such that the user can receive and transmit audio signals. A bone conduction sensor can detect near-end speech of the user for transmission with the wireless circuitry in noisy environment. Noise cancellation of background sounds near the user can improve the user's hearing of desired sounds.
Description
BACKGROUND OF THE INVENTION

1. Field of the Invention


The present invention is related to systems, devices and methods for communication.


People like to communicate with others. Hearing and speaking are forms of communication that many people use and enjoy. Many devices have been proposed that improve communication including the telephone and hearing aids.


Hearing impaired subjects need hearing aids to verbally communicate with those around them. Open canal hearing aids have proven to be successful in the marketplace because of increased comfort. Another reason why they are popular is reduced occlusion, which is a tunnel-like hearing effect that is problematic to most hearing aid users. Another common complaint is feedback and whistling from the hearing aid. Increasingly, hearing impaired subjects also make use of audio entertainment and communication devices. Often the use of these devices interferes with the use of hearing aids and more often are cumbersome to use together. Another problem is use of entertainment and communication systems in noisy environments, which requires active noise cancellation. There is a need to integrate open canal hearing aids with audio entertainment and communication systems and still allow their use in noisy places. For improving comfort, it is desirable to use these modalities in an open ear canal configuration.


Several approaches to improved hearing, improve feedback suppression and noise cancellation. Although sometimes effective, current methods and devices for feedback suppression and noise cancellation may not be effective in at least some instances. For example, when an acoustic hearing aid with a speaker positioned in the ear canal is used to amplify sound, placement of a microphone in the ear canal can result in feedback when the ear canal is open, even when feedback and noise cancellation are used.


One promising approach to improving hearing with an ear canal microphone has been to use a direct-drive transducer coupled to middle-ear transducer, rather than an acoustic transducer, such that feedback is significantly reduced and often limited to a narrow range of frequencies. The EARLENS™ transducer as described by Perkins et al (U.S. Pat. No. 5,259,032; US20060023908; US20070100197) and many other transducers that directly couple to the middle ear such as described by Puria et al (U.S. Pat. No. 6,629,922) may have significant advantages due to reduced feedback that is limited in a narrow frequency range. The EARLENS™ system may use an electromagnetic coil placed inside the ear canal to drive the middle ear, for example with the EARLENS™ transducer magnet positioned on the eardrum. A microphone can be placed inside the ear canal integrated in a wide-bandwidth system to provide pinna-diffraction cues. The pinna diffraction cues allow the user to localize sound and thus hear better in multi-talker situations, when combined with the wide-bandwidth system. Although effective in reducing feedback, these systems may result in feedback in at least some instances, for example with an open ear canal that transmits sound to a canal microphone with high gain for the hearing impaired.


Although at least some implantable hearing aid systems may result in decreased feedback, surgical implantation can be complex, expensive and may potentially subject the user to possible risk of surgical complications and pain such that surgical implantation is not a viable option for many users.


In at least some instances known hearing aides may not be fully integrated with telecommunications systems and audio system, such that the user may use more devices than would be ideal. Also, current combinations of devices may be less than ideal, such that the user may not receive the full benefit of hearing with multiple devices. For example, known hands free wireless BLUETOOTH™ devices, such as the JAWBONE™, may not work well with hearing aid devices as the hands free device is often placed over the ear. Also, such devices may not have sounds configured for optimal hearing by the user as with hearing aid devices. Similarly, a user of a hearing aid device, may have difficulty using direct audio from device such as a headphone jack for listening to a movie on a flight, an iPod or the like. In many instances, the result is that the combination of known hearing devices with communication and audio systems can be less than ideal.


The known telecommunication and audio systems may have at least some shortcomings, even when used alone, that may make at least some of these systems less than ideal, in at least some instances. For example, many known noise cancellation systems use headphones that can be bulky, in at least some instances. Further, at least some of the known wireless headsets for telecommunications can be some what obtrusive and visible, such that it would be helpful if the visibility and size could be minimized.


In light of the above, it would be desirable to provide an improved system for communication that overcomes at least some of the above shortcomings. It would be particularly desirable if such a communication system could be used without surgery to provide: high frequency localization cues, open ear canal hearing with minimal feedback, hearing aid functionality with amplified sensation level, a wide bandwidth sound with frequencies from about 0.1 to 10 kHz, noise cancellation, reduced feedback, communication with a mobile device or audio entertainment system.


2. Description of the Background Art


The following U.S. patents and publications may be relevant to the present application: U.S. Pat. Nos. 5,117,461; 5,259,032; 5,402,496; 5,425,104; 5,740,258; 5,940,519; 6,068,589; 6,222,927; 6,629,922; 6,445,799; 6,668,062; 6,801,629; 6,888,949; 6,978,159; 7,043,037; 7,203,331; 2002/20172350; 2006/0023908; 2006/0251278; 2007/0100197; Carlile and Schonstein (2006) “Frequency bandwidth and multi-talker environments,” Audio Engineering Society Convention, Paris, France 118:353-63; Killion, M. C. and Christensen, L. (1998) “The case of the missing dots: AI and SNR loss,” Hear Jour 51(5):32-47; Moore and Tan (2003) “Perceived naturalness of spectrally distorted speech and music,” J Acoust Soc Am 114(1):408-19; Puria (2003) “Measurements of human middle ear forward and reverse acoustics: implications for otoacoustic emissions,” J Acoust Soc Am 113(5):2773-89.


BRIEF SUMMARY OF THE INVENTION

Embodiments of the present invention provide improved systems, devices and methods for communication. Although specific reference is made to communication with a hearing aid, the systems methods and devices, as described herein, can be used in many applications where sound is used for communication. At least some of the embodiments can provide, without surgery, at least one of: hearing aid functionality, an open ear canal; an ear canal microphone; wide bandwidth, for example with frequencies from about 0.1 to about 10 kHz; noise cancellation; reduced feedback, communication with at least one of a mobile device; or communication with an audio entertainment system. The ear canal microphone can be configured for placement to detect high frequency sound localization cues, for example within the ear canal or outside the ear canal within about 5 mm of the ear canal opening so as to detect high frequency sound comprising localization cues from the pinna of the ear. The high frequency sound detected with the ear canal microphone may comprise sound frequencies above resonance frequencies of the ear canal, for example resonance frequencies from about 2 to about 3 kHz. An external microphone can be positioned away from the ear canal to detect low frequency sound at or below the resonance frequencies of the ear canal, such that feedback can be substantially reduced, even minimized or avoided. The canal microphone and the external microphone can be coupled to at least one output transducer, such that the user perceives sound from the external microphone and the canal microphone with high frequency localization cues and decreased feedback. Wireless circuitry can be configured to connect to many devices with a wireless protocol, such that the user can receive and transmit audio signals. A bone conduction sensor can detect near-end speech of the user for transmission with the wireless circuitry, for example in a noisy environment with a piezo electric positioner configured for placement in the ear canal. Noise cancellation of background sounds near the user can improve the user's hearing of desired sounds, for example noised cancellation of background sounds detected with the external microphone.


In a first aspect, embodiments of the present invention provide a communication device for use with an ear of a user. A first input transducer is configured for placement at least one of inside an ear canal or near an opening of the ear canal. A second input transducer is configured for placement outside the ear canal. At least one transducer configured for placement inside the ear canal of the user. The at least one output transducer is coupled to the first microphone and the second microphone to transmit sound from the first microphone and the second microphone to the user.


In many embodiments, the first input transducer comprises at least one of a first microphone configured to detect sound from air or a first acoustic sensor configured to detect vibration from tissue. The second input transducer comprises at least one of a second microphone configured to detect sound from air or a second acoustic sensor configured to detect vibration from tissue. The first input transducer may comprise a microphone configured to detect high frequency localization cues and wherein the at least one output transducer is acoustically coupled to first input transducer when the transducer is positioned in the ear canal. The second input transducer can be positioned away from the ear canal opening to minimize feedback when the first input transducer detects the high frequency localization cues.


In many embodiments, the first input transducer is configured to detect high frequency sound comprising spatial localization cues when placed inside the ear canal or near the ear canal opening and transmit the high frequency localization cues to the user. The high frequency localization cues may comprise frequencies above about 4 kHz. The first input transducer can be coupled to the at least one output transducer to transmit high frequencies above at least about 4 kHz to the user with a first gain and to transmit low frequencies below about 3 kHz with a second gain. The first gain can be greater than the second gain so as to minimize feedback from the transducer to the first input transducer. The first input transducer can be configured to detect at least one of a sound diffraction cue from a pinna of the ear of the user or a head shadow cue from a head of the user when the first input transducer is positioned at least one of inside the ear canal or near the opening of the ear canal.


In many embodiments, the first input transducer is coupled to the at least one output transducer to vibrate an eardrum of the ear in response to high frequency sound localization cues above a resonance frequency of the ear canal. The second input transducer is coupled to the at least one output transducer to vibrate the eardrum in response sound frequencies at or below the resonance frequency of the ear canal. The resonance frequency of the ear canal may comprise frequencies within a range from about 2 to 3 kHz.


In many embodiments, the first input transducer is coupled to the at least one output transducer to vibrate the eardrum with a resonance gain for first sound frequencies corresponding to the resonance frequencies of the ear canal and a cue gain for sound localization cue comprising frequencies above the resonance frequencies of the ear canal, and wherein the cue gain is greater than the resonance gain to minimize feedback.


In many embodiments, the first input transducer is coupled to the at least one output transducer to vibrate the eardrum with a first gain for first sound frequencies corresponding to the resonance frequencies of the ear canal. The second input transducer is coupled to the at least one output transducer to vibrate the eardrum with a second gain for the sound frequencies corresponding to the resonance frequencies of the ear canal, and the first gain is less than the second gain to minimize feedback.


In many embodiments, the second input transducer is configured to detect low frequency sound without high frequency localization cues from a pinna of the ear when placed outside the ear canal to minimize feedback from the transducer. The low frequency sound may comprise frequencies below about 3 kHz.


In many embodiments, the device comprises circuitry coupled to the first input transducer, the second input transducer and the at least one output transducer, and the circuitry is coupled to the first input transducer and the at least one output transducer to transmit high frequency sound comprising frequencies above about 4 kHz from the first input transducer to the user. The circuitry can be coupled to the second input transducer and the at least one output transducer to transmit low frequency sound comprising frequencies below about 4 kHz from the second input transducer to the user. The circuitry may comprise at least one of a sound processor or an amplifier coupled to the first input transducer, the second input transducer and the at least one output transducer to transmit high frequencies from the first input transducer and low frequencies from the second input transducer to the user so as to minimize feedback.


In many embodiments, the at least one output transducer comprises a first transducer and a second transducer, in which the first transducer is coupled to the first input transducer to transmit high frequency sound and the second transducer coupled to the second input transducer to transmit low frequency sound.


In many embodiments, the first input transducer is coupled to the at least one output transducer to transmit first frequencies to the user with a first gain and the second input transducer is coupled to the at least one output transducer to transmit second frequencies to the user with a second gain.


In many embodiments, the at least one output transducer comprises at least one of an acoustic speaker configured for placement inside the ear canal, a magnet supported with a support configured for placement on an eardrum of the user, an optical transducer supported with a support configured for placement on the eardrum of the user, a magnet configured for placement in a middle ear of the user, and an optical transducer configured for placement in the middle ear of the user. The at least one output transducer may comprise the magnet supported with the support configured for placement on an eardrum of the user, and the at least one output transducer may further comprises at least one coil configured for placement in the ear canal to couple to the magnet to transmit sound to the user. The at least one coil may comprises a first coil and a second coil, in which the first coil is coupled to the first input transducer and configured to transmit first frequencies from the first input transducer to the magnet, and in which the second coil is coupled to the second input transducer and configured to transmit second frequencies from the second input transducer to the magnet. The at least one output transducer may comprise the optical transducer supported with the support configured for placement on the eardrum of the user, and the optical transducer may further comprise a photodetector coupled to at least one of a coil or a piezo electric transducer supported with the support and configured to vibrate the eardrum.


In many embodiments, the first input transducer is configured to generate a first audio signal and the second input transducer is configured to generate a second audio signal and wherein the at least one output transducer is configured to vibrate with a first gain in response to the first audio signal and a second gain in response to the second audio signal to minimize feedback.


In many embodiments, the device further comprises wireless communication circuitry configured to transmit near-end speech from the user to a far-end person when the user speaks. The wireless communication circuitry can be configured to transmit the near-end sound from at least one of the first input transducer or the second input transducer. The wireless communication circuitry can be configured to transmit the near-end sound from the second input transducer. A third input transducer can be coupled to the wireless communication circuitry, in which the third input transducer configured to couple to tissue of the patient and transmit near-end speech from the user to the far end person in response to bone conduction vibration when the user speaks.


In many embodiments, the device further comprises a second device for use with a second contralateral ear of the user. The second device comprises a third input transducer configured for placement inside a second ear canal or near an opening of the second ear canal to detect second high frequency localization cues. A fourth input transducer is configured for placement outside the second ear canal. A second at least one output transducer is configured for placement inside the second ear canal, and the second at least one output transducer is acoustically coupled to the third input transducer when the second at least one output transducer is positioned in the second ear canal. The fourth input transducer is positioned away from the second ear canal opening to minimize feedback when the third input transducer detects the second high frequency localization cues. The combination of the first and second input transducers on an ipsilateral ear and the third and fourth input transducers on a contralateral ear can lead to improved binaural hearing.


In another aspect, embodiments of the present invention provide a communication device for use with an ear of a user. The device comprises a first at least one input transducer configured to detect sound. A second input transducer is configured to detect tissue vibration when the user speaks. Wireless communication circuitry is coupled to the second input transducer and configured to transmit near-end speech from the user to a far-end person when the user speaks. At least one output transducer is configured for placement inside an ear canal of the user, in which the at least one output transducer is coupled to the first input transducer to transmit sound from the first input transducer to the user.


In many embodiments, the first at least one input transducer comprises a microphone configured for placement at least one of inside an ear canal or near an opening of the ear canal to detect high frequency localization cues. Alternatively or in combination, the first at least one input transducer may comprise a microphone configured for placement outside the ear canal to detect low frequency speech and minimize feedback from the at least one output transducer.


In many embodiments, the second input transducer comprises at least one of an optical vibrometer or a laser vibrometer configured to generate a signal in response to vibration of the eardrum when the user speaks.


In many embodiments, the second input transducer comprises a bone conduction sensor configured to couple to a skin of the user to detect tissue vibration when the user speaks. The bone conduction sensor can be configured for placement within the ear canal.


In many embodiments, the device further comprises an elongate support configured to extend from the opening toward the eardrum to deliver energy to the at least one output transducer, and a positioner coupled to the elongate support. The positioner can be sized to fit in the ear canal and position the elongate support within the ear canal, and the positioner may comprise the bone conduction sensor. The bone conduction sensor may comprise a piezo electric transducer configured to couple to the ear canal to bone vibration when the user speaks.


In many embodiments, the at least one output transducer comprises a support configured for placement on an eardrum of the user.


In many embodiments, the wireless communication circuitry is configured to receive sound from at least one of a cellular telephone, a hands free wireless device of an automobile, a paired short range wireless connectivity system, a wireless communication network, or a WiFi network.


In many embodiments, the wireless communication circuitry is coupled to the at least one output transducer to transmit far-end sound to the user from a far-end person in response to speech from the far-end person.


In another aspect, embodiments of the present invention provide an audio listening system for use with an ear of a user. The system comprises a canal microphone configured for placement in an ear canal of the user, and an external microphone configured for placement external to the ear canal. A transducer is coupled to the canal microphone and the external microphone. The transducer is configured for placement inside the ear canal on an eardrum of the user to vibrate the eardrum and transmit sound to the user in response to the canal microphone and the external microphone.


In many embodiments, the transducer comprises a magnet and a support configured for placement on the eardrum to vibrate the eardrum in response to a wide bandwidth signal comprising frequencies from about 0.1 kHz to about 10 kHz.


In many embodiments, the system further comprises a sound processor coupled to the canal microphone and configured to receive an input from the canal microphone. The sound processor is configured to vibrate the eardrum in response to the input from the canal microphone. The sound processor can be configured to minimize feedback from the transducer.


In many embodiments, the sound processor is coupled to the external microphone and configured to vibrate the eardrum in response to an input from the external microphone.


In many embodiments, the sound processor is configured to cancel feedback from the transducer to the canal microphone with a feedback transfer function.


In many embodiments, the sound processor is coupled to the external microphone and configured to cancel noise in response to input from the external microphone. The external microphone can be configured to measure external sound pressure and wherein the sound processor is configured to minimize vibration of the eardrum in response to the external sound pressure measured with the external microphone. The sound processor can be configured to measure feedback from the transducer to the canal microphone and wherein the processor is configured to minimize vibration of the eardrum in response to the feedback.


In many embodiments, the external microphone is configured to measure external sound pressure, and the canal microphone is configured to measure canal sound pressure and wherein the sound processor is configured to determine feedback transfer function in response to the canal sound pressure and the external sound pressure.


In many embodiments, the system further comprises an external input for listening.


In many embodiments, the external input comprises an analog input configured to receive an analog audio signal from an external device.


In many embodiments, the system further comprises a bone vibration sensor to detect near-end speech of the user.


In many embodiments, the system further comprises wireless communication circuitry coupled to the transducer and configured to vibrate the transducer in response to far-end speech.


In many embodiments, the system further comprises a sound processor coupled to the wireless communication circuitry and wherein the sound processor is configured to process the far-end speech to generate processed far-end speech, and the processor is configured to vibrate the transducer in response to the processed far-end speech.


In many embodiments, wireless communication circuitry is configured to receive far-end speech from a communication channel of a mobile phone.


In many embodiments, the wireless communication circuitry is configured to transmit near-end speech of the user to a far-end person.


In many embodiments, the system further comprises a mixer configured to mix a signal from the canal microphone and a signal from the external microphone to generate a mixed signal comprising near-end speech, and the wireless communication circuitry is configured to transmit the mixed signal comprising the near-end speech to a far-end person.


In many embodiments, the sound processor is configured to provide mixed near-end speech to the user.


In many embodiments, the system is configured to transmit near-end speech from a noisy environment to a far-end person.


In many embodiments, the system further comprises a bone vibration sensor configured to detect near-end speech, the bone vibration sensor coupled to the wireless communication circuitry, and wherein the wireless communication circuitry is configured to transmit the near-end speech to the far-end person in response to bone vibration when the user speaks.


In another aspect, embodiments of the present invention provide a method of transmitting sound to an ear of a user. High frequency sound comprising high frequency localization cues is detected with a first microphone placed at least one of inside an ear canal or near an opening of the ear canal. A second microphone is placed external to the ear canal. At least one output transducer is placed inside the ear canal of the user. The at least one output transducer is coupled to the first microphone and the second microphone and transmits sound from the first microphone and the second microphone to the user.


In another aspect, embodiments of the present invention provide a device to detect sound from an ear canal of a user. The device comprises a piezo electric transducer configured for placement in the ear canal of the user.


In many embodiments, the piezo electric transducer comprises at least one elongate structure configured to extend at least partially across the ear canal from a first side of the ear canal to a second side of the ear canal to detect sound when the user speaks, in which the first side of the ear canal can be opposite the second side. The at least one elongate structure may comprise a plurality of elongate structures configured to extend at least partially across the long dimension of the ear canal, and a gap may extend at least partially between the plurality of elongate structures to minimize occlusion when the piezo electric transducer is placed in the canal.


In many embodiments, the device further comprises a positioner coupled to the transducer, in which the positioner is configured to contact the ear canal and support the piezoelectric transducer in the ear canal to detect vibration when the user speaks. The at least one of the positioner or the piezo electric transducer can be configured to define at least one aperture to minimize occlusion when the user speaks.


In many embodiments, the positioner comprises an outer portion configured extend circumferentially around the piezo electric transducer to contact the ear canal with an outer perimeter of the outer portion when the positioner is positioned in the ear canal.


In many embodiments, the device further comprises an elongate support comprising an elongate energy transmission structure, the elongate energy transmission structure passing through at least one of the piezo electric transducer or the positioner to transmit an audio signal to the eardrum of the user, the elongate energy transmission structure comprising at least one of an optical fiber to transmit light energy or a wire configured to transmit electrical energy.


In many embodiments, the piezo electric transducer comprises at least one of a ring piezo electric transducer, a bender piezo electric transducer, a bimorph bender piezo electric transducer or a piezoelectric multi-morph transducer, a stacked piezoelectric transducer with a mechanical multiplier or a ring piezoelectric transducer with a mechanical multiplier or a disk piezo electric transducer.


In another aspect, embodiments of the present invention provide an audio listening system having multiple functionalities. The system comprises a body configured for positioning in an open ear canal, the functionalities include a wide-bandwidth hearing aid, a microphone within the body, a noise suppression system, a feedback cancellation system, a mobile phone communication system, and an audio entertainment system.





BRIEF DESCRIPTION OF THE DRAWINGS


FIG. 1 shows a hearing aid integrated with communication sub-system, noise suppression sub-system and feedback-suppression sub-system, according to embodiments of the present invention;



FIG. 1A shows (1) a wide bandwidth EARLENS™ hearing aid of the prior art suitable for use with a mode of the system as in FIG. 1 with an ear canal microphone for sound localization;



FIG. 2A shows (2) a hearing aide mode of the system as in FIGS. 1 and 1A with feedback cancellation;



FIG. 3A shows (3) a hearing aid mode of the system as in FIGS. 1 and 1A operating with noise cancellation;



FIG. 4A shows (4) the system as in FIG. 1 where the audio input is from an RF receiver, for example a BLUETOOTH™ device connected to the far-end speech of the communication channel of a mobile phone.



FIG. 5A shows (5) the system as in FIGS. 1 and 4A configured to transmit the near-end speech, in which the speech can be a mix of the signal generated by the external microphone and the ear canal microphone from sensors including a small vibration sensor;



FIG. 6A shows the system as in FIGS. 1, 1A, 4A and 5A configured to transduce and transmit the near-end speech, from a noisy environment, to the far-end listener;



FIG. 7A shows a piezoelectric positioner configured for placement in the ear canal to detect near-end speech, according to embodiments of the present invention;



FIG. 7B shows a positioner as in FIG. 7A in detail, according to embodiments of the present invention;



FIG. 8A shows an elongate support with a pair of positioners adapted to contact the ear canal, and in which at least one of the positioners comprises a piezoelectric positioner configured to detect near end speech of the user, according to embodiments of the present invention;



FIG. 8B shows an elongate support as in FIG. 8A attached to two positioners placed in an ear canal, according to embodiments of the present invention;



FIG. 8B-1 shows an elongate support configured to position a distal end of the elongate support with at least one positioner placed in an ear canal, according to embodiments of the present invention;



FIG. 8C shows a positioner adapted for placement near the opening to the ear canal, according to embodiments of the present invention;



FIG. 8D shows a positioner adapted for placement near the coil assembly, according to embodiments of the present invention;



FIG. 9 illustrates a body comprising the canal microphone installed in the ear canal and coupled to a BTE unit comprising the external microphone, according to embodiments of the present invention;



FIG. 10A shows feedback pressure at the canal microphone and feedback pressure at the external microphone for a transducer coupled to the middle ear, according to embodiments of the present invention;



FIG. 10B shows gain versus frequency at the output transducer for sound input to canal microphone and sound input to the external microphone to detect high frequency localization cues and minimize feedback, according to embodiments of the present invention;



FIG. 10C shows a canal microphone with high pass filter circuitry and an external microphone with low pass filter circuitry, both coupled to a transducer to provide gain in response to frequency as in FIG. 10B;


FIG. 10D1 shows a canal microphone coupled to first transducer and an external microphone coupled to a second transducer to provide gain in response to frequency as in FIG. 10B;


FIG. 10D2 shows the canal microphone coupled to a first transducer comprising a first coil wrapped around a core and the external microphone coupled to a second transducer comprising second a coil wrapped around the core, as in FIG. 10D1;



FIG. 11A shows an elongate support comprising a plurality of optical fibers configured to transmit light and receive light to measure displacement of the eardrum, according to embodiments of the present invention;



FIG. 11B shows a positioner for use with an elongate support as in FIG. 11A and adapted for placement near the opening to the ear canal, according to embodiments of the present invention; and



FIG. 11C shows a positioner adapted for placement near a distal end of the elongate support as in FIG. 11A, according to embodiments of the present invention.





DETAILED DESCRIPTION OF THE INVENTION

Embodiments of the present invention provide a multifunction audio system integrated with communication system, noise cancellation, and feedback management, and non-surgical transduction. A multifunction hearing aid integrated with communication system, noise cancellation, and feedback management system with an open ear canal is described, which provides many benefits to the user.



FIGS. 1A to 6A illustrate different functionalities embodied in the integrated system. The present multifunction hearing aid comprises with wide bandwidth, sound localization capabilities, as well as communication and noise-suppression capabilities. The configurations for system 10 include configurations for multiple sensor inputs and direct drive of the middle ear.



FIG. 1 shows a hearing aid system 10 integrated with communication sub-system, noise suppression sub-system and feedback-suppression sub-system. System 10 is configured to receive sound input from an acoustic environment. System 10 comprises a canal microphone CM configured to receive input from the acoustic environment, and an external microphone configured to receive input from the acoustic environment. When the canal microphone is placed in the ear canal, the canal microphone can receive high frequency localization cues, similar to natural hearing, that help the user localize sound. System 10 includes a direct audio input, for example an analog audio input from a jack, such that the user can listen to sound from the direct audio input. System 10 also includes wireless circuitry, for example known short range wireless radio circuitry configured to connect with the BLUETOOTH™ short range wireless connectivity standard. The wireless circuitry can receive input wirelessly, such as input from a phone, input from a stereo, and combinations thereof. The wireless circuitry is also coupled to the external microphone EM and bone vibration circuitry, to detect near-end speech when the user speaks. The bone vibration circuitry may comprise known circuitry to detect near-end speech, for example known JAWBONE™ circuitry that is coupled to the skin of the user to detect bone vibration in response to near-end speech. Near end speech can also be transmitted to the middle ear and cochlea, for example with acoustic bone conduction, such that the user can hear him or her self speak.


System 10 comprises a sound processor. The sound processor is coupled to the canal microphone CM to receive input from the canal microphone. The sound processor is coupled to the external microphone EM to receive sound input from the external microphone. An amplifier can be coupled to the external microphone EM and the sound processor so as to amplify sound from the external microphone to the sound processor. The sound processor is also coupled to the direct audio input. The sound processor is coupled to an output transducer configured to vibrate the middle ear. The output transducer may be coupled to an amplifier. Vibration of the middle ear can induce the stapes of the ear to vibrate, for example with velocity, such that the user perceives sound. The output transducer may comprise, for example, the EARLENS™ transducer described by Perkins et al in the following US Patents and Application Publications: 5,259,032; 20060023908; 20070100197, the full disclosures of which are incorporated herein by reference and may include subject matter suitable for combination in accordance with some embodiments of the present invention. The EARLENS™ transducer may have significant advantages due to reduced feedback that can be limited to a narrow frequency range. The output transducer may comprise an output transducer directly coupled to the middle ear, so as to reduce feedback. For example, the EARLENS™ transducer can be coupled to the middle ear, so as to vibrate the middle ear such that the user perceives sound. The output transducer of the EARLENS™ can comprise, for example a core/coil coupled to a magnet. When current is passed through the coil, a magnetic field is generated, which magnetic field vibrates the magnet of the EARLENS™ supported on the eardrum such that the user perceives sound. Alternatively or in combination, the output transducer may comprise other types of transducers, for example, many of the optical transducers or transducer systems described herein.


System 10 is configured for an open ear canal, such that there is a direct acoustic path from the acoustic environment to the eardrum of the user. The direct acoustic path can be helpful to minimize occlusion of the ear canal, which can result in the user perceiving his or her own voice with a hollow sound when the user speaks. With the open canal configuration, a feedback path can exist from the eardrum to the canal microphone, for example the EL Feedback Acoustic Pathway. Although use of a direct drive transducer such as the coil and magnet of the EARLENS™ system can substantially minimize feedback, it can be beneficial to minimize feedback with additional structures and configurations of system 10.



FIG. 1A shows (1) a wide bandwidth EARLENS™ hearing aid of the prior art suitable for use with a mode of the system as in FIG. 1 with ear canal microphone CM for sound localization. The canal microphone CM is coupled to sound processor SP. Sound processor SP is coupled to an output amplifier, which amplifier is coupled to a coil to drive the magnet of the EARLENS™ EL.



FIG. 2A shows (2) a hearing aide mode of the system as in FIGS. 1 and 1A with a feedback cancellation mode. A free field sound pressure PFF may comprise a desired signal. The desired signal comprising the free field sound pressure is incident the external microphone and on the pinna of the ear. The free field sound is diffracted by the pinna of the ear and transformed to form sound with high frequency localization cues at canal microphone CM. As the canal microphone is placed in the ear canal along the sound path between the free field and the eardrum, the canal transfer function HC may comprise a first component HC1 and a second component HC2, in which HC1 corresponds to sound travel between the free field and the canal microphone and HC2 corresponds to sound travel between the canal microphone and the eardrum.


As noted above, acoustic feedback can travel from the EARLENS™ EL to the canal microphone CM. The acoustic feedback travels along the acoustic feedback path to the canal microphone CM, such that a feedback sound pressure PFB is incident on canal microphone CM. The canal microphone CM senses sound pressure from the desired signal PCM and the feedback sound pressure PFB. The feedback sound pressure PFB can be canceled by generating an error signal EFB. A feedback transfer function HFB is shown from the output of the sound processor to the input to the sound processor, and an error signal c is shown as input to the sound processor. Sound processor SP may comprise a signal generator SG. HFB can be estimated by generating a wide band signal with signal generator SG and nulling out the error signal e. HFB can be used to generate an error signal EFB with known signal processing techniques for feedback cancellation. The feedback suppression may comprise or be combined with known feedback suppression methods, and the noise cancellation may comprise or be combined with known noise cancellation methods.



FIG. 3A shows (3) a hearing aid mode of the system as in FIGS. 1 and 1A operating with a noise cancellation mode. The external microphone EM is coupled to the sound processor SP, through an amplifier AMP. The canal microphone CM is coupled to the sound processor SP. External microphone EM is configured to detect sound from free field sound pressure PFF. Canal microphone CM is configured to detect sound from canal sound pressure PCM. The sound pressure PFF travels through the ear canal and arrives at the tympanic membrane to generate a pressure at the tympanic membrane PTM2. The free field sound pressure PFF travels through the ear canal in response to an ear canal transfer function HC to generate a pressure at the tympanic membrane PTM1. The system is configured to minimize V0 corresponding to vibration of the eardrum due to PFF. The output transducer is configured to vibrate with—PTM1 such that V0 corresponding to vibration of the eardrum is minimized, and thus PFB at the canal microphone may also be minimized. The transfer function of the ear canal HC1 can be determined in response to PCM and PFF, for example in response to the ratio of PCM to PFF with the equation HC1=PCM/PFF.


The sound processor can be configured to pass an output current IC through the coil which minimizes motion of the eardrum. The current through the coil for a desired PTM2 can be determined with the following equation and approximation:

IC=PTM1/PTM2=(PTM1/PEFF)mA

where PEFF comprises the effective pressure at the tympanic membrane per milliamp of the current measured on an individual subject.


The ear canal transfer function HC may comprise a first ear canal transfer function HC1 and a second ear canal transfer function HC2. As the canal microphone CM is placed in the ear canal, the second ear canal transfer function HC2 may correspond to a distance along the ear canal from ear canal microphone CM to the eardrum. The first ear canal transfer function HC1 may correspond to a portion of the ear canal from the ear canal microphone CM to the opening of the ear canal. The first ear canal transfer function may also comprise a pinna transfer function, such that first ear canal transfer function HC1 corresponds to the ear canal sound pressure PCM at the canal microphone in response to the free field sound pressure PCM after the free field sound pressure has been diffracted by the pinna so as to provide sound localization cues near the entrance to the ear canal.


The above described noise cancellation and feedback suppression can be combined in many ways. For example, the noise cancellation can be used with an input, for example direct audio input during a flight while the user listens to a movie, and the surrounding noise of the flight cancelled with the noise cancellation from the external microphone, and the sound processor configured to transmit the direct audio to the transducer, for example adjusted to the user's hearing profile, such that the user can hear the sound, for example from the movie, clearly.



FIG. 4A shows (4) the system as in FIG. 1 where the audio input is from an RF receiver, for example a BLUETOOTH™ device connected to the far-end speech of the communication channel of a mobile phone. The mobile system may comprise a mobile phone system, for example a far end mobile phone system. The system 10 may comprise a listen mode to listen to an external input. The external input in the listen mode may comprise at least one of a) the direct audio input signal or b) far-end speech from the mobile system.



FIG. 5A shows (5) the system as in FIGS. 1, 1A and 4A configured to transmit the near-end speech with an acoustic mode. The acoustic signal may comprise near end speech detected with a microphone, for example. The near-end speech can be a mix of the signal generated by the external microphone and the mobile phone microphone. The external microphone EM is coupled to a mixer. The canal microphone may also be coupled to the mixer. The mixer is coupled to the wireless circuitry to transmit the near-end speech to the far-end. The user is able to hear both near end speech and far end speech.



FIG. 6A shows the system as in FIGS. 1, 1A, 4A and 5A configured to transduce and transmit the near-end speech from a noisy environment to the far-end listener. The system 10 comprises a near-end speech transmission with a mode configured for vibration and acoustic detection of near end speech. The acoustic detection comprises the canal microphone CM and the external microphone EM mixed with the mixer and coupled to the wireless circuitry. The near end speech also induces vibrations in the user's bone, for example the user's skull, that can be detected with a vibration sensor. The vibration sensor may comprise a commercially available vibration sensor such as components of the JAWBONE™. The skull vibration sensor is coupled to the wireless circuitry. The near-end sound vibration detected from the bone conduction vibration sensor is combined with the near-end sound from at least one of the canal microphone CM or the external microphone EM and transmitted to the far-end user of the mobile system.



FIG. 7A shows a piezoelectric positioner 710 configured to detect near end speech of the user. Piezo electric positioner 710 can be attached to an elongate support near a transducer, in which the piezoelectric positioner is adapted to contact the ear in the canal near the transducer and support the transducer. Piezoelectric positioner 710 may comprise a piezoelectric ring 720 configured to detect near-end speech of the user in response to bone vibration when the user speaks. The piezoelectric ring 720 can generate an electrical signal in response to bone vibration transmitted through the skin of the ear canal. A piezo electric positioner 710 comprises a wise support attached to elongate support 750 near coil assembly 740. Piezoelectric positioner 710 can be used to center the coil in the canal to avoid contact with skin 765, and also to maintain a fixed distance between coil assembly 740 and magnet 728. Piezoelectric positioner 710 is adapted for direct contact with a skin 765 of ear canal. For example, piezoelectric positioner 710 includes a width that is approximately the same size as the cross sectional width of the ear canal where the piezoelectric positioner contacts skin 765. Also, the width of piezoelectric positioner 710 is typically greater than a cross-sectional width of coil assembly 740 so that the piezoelectric positioner can suspend coil assembly 740 in the ear canal to avoid contact between coil assembly 40 and skin 765 of the ear canal.


The piezo electric positioner may comprise many known piezoelectric materials, for example at least one of Polyvinylidene Fluoride (PVDF), PVF, or lead zirconate titanate (PZT).


System 10 may comprise a behind the ear unit, for example BTE unit 700, connected to elongate support 750. The BTE unit 700 may comprise many of the components described above, for example the wireless circuitry, the sound processor, the mixer and a power storage device. The BTE unit 700 may comprise an external microphone 748. A canal microphone 744 can be coupled to the elongate support 750 at a location 746 along elongate support 750 so as to position the canal microphone at least one of inside the near canal or near the ear canal opening to detect high frequency sound localization cues in response to sound diffraction from the Pinna. The canal microphone and the external microphone may also detect head shadowing, for example with frequencies at which the head of the user may cast an acoustic shadow on the microphone 744 and microphone 748.


Positioner 710 is adapted for comfort during insertion into the user's ear and thereafter. Piezoelectric positioner 710 is tapered proximally (and laterally) toward the ear canal opening to facilitate insertion into the ear of the user. Also, piezoelectric positioner 710 has a thickness transverse to its width that is sufficiently thin to permit piezoelectric positioner 710 to flex while the support is inserted into position in the ear canal. However, in some embodiments the piezoelectric positioner has a width that approximates the width of the typical ear canal and a thickness that extends along the ear canal about the same distance as coil assembly 740 extends along the ear canal. Thus, as shown in FIG. 7A piezoelectric positioner 710 has a thickness no more than the length of coil assembly 740 along the ear canal.


Positioner 710 permits sound waves to pass and provides and can be used to provide an open canal hearing aid design. Piezoelectric positioner 710 comprises several spokes and openings formed therein. In an alternate embodiment, piezoelectric positioner 710 comprises soft “flower” like arrangement. Piezoelectric positioner 710 is designed to allow acoustic energy to pass, thereby leaving the ear canal mostly open.



FIG. 7B shows a piezoelectric positioner 710 as in FIG. 7A in detail, according to embodiments of the present invention. Spokes 712 and piezoelectric ring 720 define apertures 714. Apertures 714 are shaped to permit acoustic energy to pass. In an alternate embodiment, the rim is elliptical to better match the shape of the ear canal defined by skin 765. Also, the rim can be removed so that spokes 712 engage the skin in a “flower petal” like arrangement. Although four spokes are shown, any number of spokes can be used. Also, the apertures can be any shape, for example circular, elliptical, square or rectangular.



FIG. 8A shows an elongate support with a pair of positioners adapted to contact the ear canal, and in which at least one of the positioners comprises a piezoelectric positioner configured to detect near end speech of the user, according to embodiments of the present invention. An elongate support 810 extends to a coil assembly 819. Coil assembly 819 comprises a coil 816, a core 817 and a biocompatible material 818. Elongate support 810 includes a wire 812 and a wire 814 electrically connected to coil 816. Coil 816 can include any of the coil configurations as described above. Wire 812 and wire 814 are shown as a twisted pair, although other configurations can be used as described above. Elongate support 810 comprises biocompatible material 818 formed over wire 812 and wire 814. Biocompatible material 818 covers coil 816 and core 817 as described above.


Wire 812 and wire 814 are resilient members and are sized and comprise material selected to elastically flex in response to small deflections and provide support to coil assembly 819. Wire 812 and wire 814 are also sized and comprise material selected to deform in response to large deflections so that elongate support 810 can be deformed to a desired shape that matches the ear canal. Wire 812 and wire 814 comprise metal and are adapted to conduct heat from coil assembly 819. Wire 812 and wire 814 are soldered to coil 816 and can comprise a different gauge of wire from the wire of the coil, in particular a gauge with a range from about 26 to about 36 that is smaller than the gauge of the coil to provide resilient support and heat conduction. Additional heat conducting materials can be used to conduct and transport heat from coil assembly 819, for example shielding positioned around wire 812 and wire 814. Elongate support 810 and wire 812 and wire 814 extend toward the driver unit and are adapted to conduct heat out of the ear canal.



FIG. 8B shows an elongate support as in FIG. 8A attached to two piezoelectric positioners placed in an ear canal, according to embodiments of the present invention. A first piezoelectric positioner 830 is attached to elongate support 810 near coil assembly 819. First piezoelectric positioner 830 engages the skin of the ear canal to support coil assembly 819 and avoid skin contact with the coil assembly. A second piezoelectric positioner 840 is attached to elongate support 810 near ear canal opening 817. In some embodiments, microphone 820 may be positioned slightly outside the ear canal and near the canal opening so as to detect high frequency localization cues, for example within about 7 mm of the canal opening. Second piezoelectric positioner 840 is sized to contact the skin of the ear canal near opening 17 to support elongate support 810. A canal microphone 820 is attached to elongate support 810 near ear canal opening 17 to detect high frequency sound localization cues. The piezoelectric positioners and elongate support are sized and shaped so that the supports substantially avoid contact with the ear between the microphone and the coil assembly. A twisted pair of wires 822 extends from canal microphone 820 to the driver unit and transmits an electronic auditory signal to the driver unit. Alternatively, other modes of signal transmission, as described below with reference to FIG. 8B-1, may be used. Although canal microphone 820 is shown lateral to piezoelectric positioner 840, microphone 840 can be positioned medial to piezoelectric positioner 840. Elongate support 810 is resilient and deformable as described above. Although elongate support 810, piezoelectric positioner 830 and piezoelectric positioner 840 are shown as separate structures, the support can be formed from a single piece of material, for example a single piece of material formed with a mold. In some embodiments, elongate support 81, piezoelectric positioner 830 and piezoelectric positioner 840 are each formed as separate pieces and assembled. For example, the piezoelectric positioners can be formed with holes adapted to receive the elongate support so that the piezoelectric positioners can be slid into position on the elongate support.



FIG. 8C shows a piezoelectric positioner adapted for placement near the opening to the ear canal according to embodiments of the present invention. Piezoelectric positioner 840 includes piezoelectric flanges 842 that extend radially outward to engage the skin of the ear canal. Flanges 842 are formed from a flexible material. Openings 844 are defined by piezoelectric flanges 842. Openings 844 permit sound waves to pass piezoelectric positioner 840 while the piezoelectric positioner is positioned in the ear canal, so that the sound waves are transmitted to the tympanic membrane. Although piezoelectric flanges 842 define an outer boundary of support 840 with an elliptical shape, piezoelectric flanges 842 can comprise an outer boundary with any shape, for example circular. In some embodiments, the piezoelectric positioner has an outer boundary defined by the shape of the individual user's ear canal, for example embodiments where piezoelectric positioner 840 is made from a mold of the user's ear. Elongate support 810 extends transversely through piezoelectric positioner 840.



FIG. 8D shows a piezoelectric positioner adapted for placement near the coil assembly, according to embodiments of the present invention. Piezoelectric positioner 830 includes piezoelectric flanges 832 that extend radially outward to engage the skin of the ear canal. Flanges 832 are formed from a flexible piezoelectric material, for example a biomorph material. Openings 834 are defined by piezoelectric flanges 832. Openings 834 permit sound waves to pass piezoelectric positioner 830 while the piezoelectric positioner is positioned in the ear canal, so that the sound waves are transmitted to the tympanic membrane. Although piezoelectric flanges 832 define an outer boundary of support 830 with an elliptical shape, piezoelectric flanges 832 can comprise an outer boundary with any shape, for example circular. In some embodiments, the piezoelectric positioner has an outer boundary defined by the shape of the individual user's ear canal, for example embodiments where piezoelectric positioner 830 is made from a mold of the user's ear. Elongate support 810 extends transversely through piezoelectric positioner 830.


Although an electromagnetic transducer comprising coil 819 is shown positioned on the end of elongate support 810, the piezoelectric positioner and elongate support can be used with many types of transducers positioned at many locations, for example optical electromagnetic transducers positioned outside the ear canal and coupled to the support to deliver optical energy along the support, for example through at least one optical fiber. The at least one optical fiber may comprise a single optical fiber or a plurality of two or more optical fibers of the support. The plurality of optical fibers may comprise a parallel configuration of optical fibers configured to transmit at least two channels in parallel along the support toward the eardrum of the user.



FIG. 8B-1 shows an elongate support configured to position a distal end of the elongate support with at least one piezoelectric positioner placed in an ear canal. Elongate support 810 and at least one piezoelectric positioner, for example at least one of piezoelectric positioner 830 or piezoelectric positioner 840, or both, are configured to position support 810 in the ear canal with the electromagnetic energy transducer positioned outside the ear canal, and the microphone positioned at least one of in the ear canal or near the ear canal opening so as to detect high frequency spatial localization clues, as described above. For example, the output energy transducer, or emitter, may comprise a light source configured to emit electromagnetic energy comprising optical frequencies, and the light source can be positioned outside the ear canal, for example in a BTE unit. The light source may comprise at least one of an LED or a laser diode, for example. The light source, also referred to as an emitter, can emit visible light, or infrared light, or a combination thereof. Light circuitry may comprise the light source and can be coupled to the output of the sound processor to emit a light signal to an output transducer placed on the eardrum so as to vibrate the eardrum such that the user perceives sound. The light source can be coupled to the distal end of the support 810 with a waveguide, such as an optical fiber with a distal end of the optical fiber 810D comprising a distal end of the support. The optical energy delivery transducer can be coupled to the proximal portion of the elongate support to transmit optical energy to the distal end. The piezoelectric positioner can be adapted to position the distal end of the support near an eardrum when the proximal portion is placed at a location near an ear canal opening. The intermediate portion of elongate support 810 can be sized to minimize contact with a canal of the ear between the proximal portion to the distal end.


The at least one piezoelectric positioner, for example piezoelectric positioner 830, can improve optical coupling between the light source and a device positioned on the eardrum, so as to increase the efficiency of light energy transfer from the output energy transducer, or emitter, to an optical device positioned on the eardrum. For example, by improving alignment of the distal end 810D of the support that emits light and a transducer positioned at least one of on the eardrum or inside the middle ear, for example positioned on an ossicle of the middle ear. The device positioned on the eardrum may comprise an optical transducer assembly OTA. The optical transducer assembly OTA may comprise a support configured for placement on the eardrum, for example molded to the eardrum and similar to the support used with transducer EL. The optical transducer assembly OTA may comprise an optical transducer configured to vibrate in response to transmitted light λT. The transmitted light λT may comprise many wavelengths of light, for example at least one of visible light or infrared light, or a combination thereof. The optical transducer assembly OTA vibrates on the eardrum in response to transmitted light λT. The at least one piezoelectric positioner and elongate support 810 comprising an optical fiber can be combined with many known optical transducer and hearing devices, for example as described in U.S. U.S. 2006/0189841, entitled “Systems and Methods for Photo-Mechanical Hearing Transduction”; and U.S. Pat. No. 7,289,639, entitled “Hearing Implant”, the full disclosure of which are incorporated herein by reference and may include subject matter suitable for combination in accordance with some embodiments of the present invention. The piezoelectric positioner and elongate support may also be combined with photo-electro-mechanical transducers positioned on the ear drum with a support, as described in U.S. Pat. Ser. Nos. 61/073,271; and 61/073,281, both filed on Jun. 17, 2008, the full disclosure of which are incorporated herein by reference and may include subject matter suitable for combination in accordance with some embodiments of the present invention.


In specific embodiments, elongate support 810 may comprise an optical fiber coupled to piezoelectric positioner 830 to align the distal end of the optical fiber with an output transducer assembly supported on the eardrum. The output transducer assembly may comprise a photodiode configured to receive light transmitted from the distal end of support 810 and supported with support component 30 placed on the eardrum, as described above. The output transducer assembly can be separated from the distal end of the optical fiber, and the proximal end of the optical fiber can be positioned in the BTE unit and coupled to the light source. The output transducer assembly can be similar to the output transducer assembly described in U.S. 2006/0189841, with piezoelectric positioner 830 used to align the optical fiber with the output transducer assembly, and the BTE unit may comprise a housing with the light source positioned therein.



FIG. 9 illustrates a body 910 comprising the canal microphone installed in the ear canal and coupled to a BTE unit comprising the external microphone, according to embodiments of system 10. The body 910 comprises the transmitter installed in the ear canal coupled to the BTE unit. The transducer comprises the EARLENS™ installed on the tympanic membrane. The transmitter assembly 960 is shown with shell 966 cross-sectioned. The body 910 comprising shell 966 is shown installed in a right ear canal and oriented with respect to the transducer EL. The transducer assembly EL is positioned against tympanic membrane, or eardrum at umbo area 912. The transducer may also be placed on other acoustic members of the middle ear, including locations on the malleus, incus, and stapes. When placed in the umbo area 912 of the eardrum, the transducer EL will be naturally tilted with respect to the ear canal. The degree of tilt will vary from individual to individual, but is typically at about a 60-degree angle with respect to the ear canal. Many of the components of the shell and transducer can be similar to those described in U.S. Pub. No. 2006/0023908, the full disclosure of which has been previously incorporated herein by reference and may include subject matter suitable for combination in accordance with some embodiments of the present invention.


A first microphone for high frequency sound localization, for example canal microphone 974, is positioned inside the ear canal to detect high frequency localization cues. A BTE unit is coupled to the body 910. The BTE unit has a second microphone, for example an external microphone positioned on the BTE unit to receive external sounds. The external microphone can be used to detect low frequencies and combined with the high frequency microphone input to minimize feedback when high frequency sound is detected with the high frequency microphone, for example canal microphone 974. A bone vibration sensor 920 is supported with shell 966 to detect bone conduction vibration when the user speaks. An outer surface of bone vibration sensor 920 can be disposed along outer surface of shell 966 so as to contact tissue of the ear canal, for example substantially similar to an outer surface of shell 966 near the sensor to minimize tissue irritation. Bone vibration sensor 920 may also extend through an outer surface shell 966 to contact the tissue of the ear canal. Additional components of system 10, such as wireless communication circuitry and the direct audio input, as described above, can be located in the BTE unit. The sound processor may be located in many places, for example in the BTE unit or within the ear canal.


The transmitter assembly 960 has shell 966 configured to mate with the characteristics of the individual's ear canal wall. Shell 966 can be preferably matched to fit snug in the individual's ear canal so that the transmitter assembly 960 may repeatedly be inserted or removed from the ear canal and still be properly aligned when re-inserted in the individual's ear. Shell 966 can also be configured to support coil 964 and core 962 such that the tip of core 962 is positioned at a proper distance and orientation in relation to the transducer 926 when the transmitter assembly is properly installed in the ear canal. The core 962 generally comprises ferrite, but may be any material with high magnetic permeability.


In many embodiments, coil 964 is wrapped around the circumference of the core 962 along part or all of the length of the core. Generally, the coil has a sufficient number of rotations to optimally drive an electromagnetic field toward the transducer. The number of rotations may vary depending on the diameter of the coil, the diameter of the core, the length of the core, and the overall acceptable diameter of the coil and core assembly based on the size of the individual's ear canal. Generally, the force applied by the magnetic field on the magnet will increase, and therefore increase the efficiency of the system, with an increase in the diameter of the core. These parameters will be constrained, however, by the anatomical limitations of the individual's ear. The coil 964 may be wrapped around only a portion of the length of the core allowing the tip of the core to extend further into the ear canal.


One method for matching the shell 966 to the internal dimensions of the ear canal is to make an impression of the ear canal cavity, including the tympanic membrane. A positive investment is then made from the negative impression. The outer surface of the shell is then formed from the positive investment which replicated the external surface of the impression. The coil 964 and core 962 assembly can then be positioned and mounted in the shell 966 according to the desired orientation with respect to the projected placement of the transducer 926, which may be determined from the positive investment of the ear canal and tympanic membrane. Other methods of matching the shell to the ear canal of the user, such as imaging of the user may be used.


Transmitter assembly 960 may also comprise a digital signal processing (DSP) unit 972, microphone 974, and battery 978 that are supported with body 910 and disposed inside shell 966. A BTE unit may also be coupled to the transmitter assembly, and at least some of the components, such as the DSP unit can be located in the BTE unit. The proximal end of the shell 966 has a faceplate 980 that can be temporarily removed to provide access to the open chamber 986 of the shell 966 and transmitter assembly components contained therein. For example, the faceplate 980 may be removed to switch out battery 978 or adjust the position or orientation of core 962. Faceplate 980 may also have a microphone port 982 to allow sound to be directed to microphone 974. Pull line 984 may also be incorporated into the shell 966 of faceplate 980 so that the transmitter assembly can be readily removed from the ear canal. In some embodiments, the external microphone may be positioned outside the ear near a distal end of pull line 984, such that the external microphone is sufficiently far from the ear canal opening so as to minimized feedback from the external microphone.


In operation, ambient sound entering the pinna, or auricle, and ear canal is captured by the microphone 974, which converts sound waves into analog electrical signals for processing by the DSP unit 972. The DSP unit 972 may be coupled to an input amplifier to amplify the signal and convert the analog signal to a digital signal with a analog to digital converter commonly used in the art. The digital signal can then be processed by any number of known digital signal processors. The processing may consist of any combination of multi-band compression, noise suppression and noise reduction algorithms. The digitally processed signal is then converted back to analog signal with a digital to analog converter. The analog signal is shaped and amplified and sent to the coil 964, which generates a modulated electromagnetic field containing audio information representative of the audio signal and, along with the core 962, directs the electromagnetic field toward the magnet of the transducer EL. The magnet of transducer EL vibrates in response to the electromagnetic field, thereby vibrating the middle-ear acoustic member to which it is coupled, for example the tympanic membrane, or, for example the malleus 18 in FIGS. 3A and 3B of U.S. 2006/0023908, the full disclosure of which has been previously incorporated herein by reference.


In many embodiments, face plate 980 also has an acoustic opening 970 to allow ambient sound to enter the open chamber 986 of the shell. This allows ambient sound to travel through the open volume 986 along the internal compartment of the transmitter assembly and through one or more openings 968 at the distal end of the shell 966. Thus, ambient sound waves may reach and vibrate the eardrum and separately impart vibration on the eardrum. This open-channel design provides a number of substantial benefits. First, the open channel minimizes the occlusive effect prevalent in many acoustic hearing systems from blocking the ear canal. Second, the natural ambient sound entering the ear canal allows the electromagnetically driven effective sound level output to be limited or cut off at a much lower level than with a design blocking the ear canal.


With the two microphone embodiments, for example the external microphone and canal microphone as described herein, acoustic hearing aids can realize at least some improvement in sound localization, because of the decrease in feedback with the two microphones, which can allow at least some sound localization. For example a first microphone to detect high frequencies can be positioned near the ear canal, for example outside the ear canal and within about 5 mm of the ear canal opening, to detect high frequency sound localization cues. A second microphone to detect low frequencies can be positioned away from the ear canal opening, for example at least about 10 mm, or even 20 mm, from the ear canal opening to detect low frequencies and minimize feedback from the acoustic speaker positioned in the ear canal.


In some embodiments, the BTE components can be placed in body 910, except for the external microphone, such that the body 910 comprises the wireless circuitry and sound processor, battery and other components. The external microphone may extend from the body 910 and/or faceplate 980 so as to minimize feedback, for example similar to pull line 984 and at least about 10 mm from faceplate 980 so as to minimize feedback.



FIG. 10A shows feedback pressure at the canal microphone and feedback pressure at the external microphone versus frequency for an output transducer configured to vibrate the eardrum and produce the sensation of sound. The output transducer can be directly coupled to an ear structure such as an ossicle of the middle ear or to another structure such as the eardrum, for example with the EARLENS™ transducer EL. The feedback pressure PFB(Canal, EL) for the canal microphone with the EARLENS™ transducer EL is shown from about 0.1 kHz (100 Hz) to about 10 kHz, and can extend to about 20 kHz at the upper limit of human hearing. The feedback pressure can be expressed as a ratio in dB of sound pressure at the canal microphone to sound pressure at the eardrum. The feedback pressure PFB(External, EL) is also shown for external microphone with transducer EL and can be expressed as a ratio of sound pressure at the external microphone to sound pressure at the eardrum. The feedback pressure at the canal microphone is greater than the feedback pressure at the external microphone. The feedback pressure is generated when a transducer, for example a magnet, supported on the eardrum is vibrated. Although feedback with this approach can be minimal, the direct vibration of the eardrum can generate at least some sound that is transmitted outward along the canal toward the canal microphone near the ear canal opening. The canal microphone feedback pressure PFB(Canal) comprises a peak around 2-3 kHz and decreases above about 3 kHz. The peak around 2-3 kHz corresponds to resonance of the ear canal. Although another sub peak may exist between 5 and 10 kHz for the canal microphone feedback pressure PFB(Canal), this peak has much lower amplitude than the global peak at 2-3 kHz. As the external microphone is farther from the eardrum than the canal microphone, the feedback pressure PFB(External) for the external microphone is lower than the feedback pressure PFB(Canal) for the canal microphone. The external microphone feedback pressure may also comprise a peak around 2-3 kHz that corresponds to resonance of the ear canal and is much lower in amplitude than the feedback pressure of the canal microphone as the external microphone is farther from the ear canal. As the high frequency localization cues can be encoded in sound frequencies above about 3 kHz, the gain of canal microphone and external microphone can be configured to detect high frequency localization cues and minimize feedback.


The canal microphone and external microphone may be used with many known transducers to provide at least some high frequency localization cues with an open ear canal, for example surgically implanted output transducers and hearing aides with acoustic speakers. For example, the canal microphone feedback pressure PFB(Canal, Acoustic) when an acoustic speaker transducer placed near the eardrum shows a resonance similar to transducer EL and has a peak near 2-3 kHz. The external microphone feedback pressure PFB(External, Acoustic) is lower than the canal microphone feedback pressure PFB(Canal, Acoustic) at all frequencies, such that the external microphone can be used to detect sound comprising frequencies at or below the resonance frequencies of the ear, and the canal microphone may be used to detect high frequency localization cues at frequencies above the resonance frequencies of the ear canal. Although the canal microphone feedback pressure PFB(Canal, Acoustic) is greater for the acoustic speaker output transducer than the canal microphone feedback pressure PFB(Canal, EL) for the EARLENS™ transducer EL, the acoustic speaker may deliver at least some high frequency sound localization cues when the external microphone is used to amply frequencies at or below the resonance frequencies of the ear canal.



FIG. 10B shows gain versus frequency at the output transducer for sound input to canal microphone and sound input to the external microphone to detect high frequency localization cues and minimize feedback. As noted above, the high frequency localization cues of sound can be encoded in frequencies above about 3 kHz. These spatial localization cues can include at least one of head shadowing or diffraction of sound by the pinna of the ear. Hearing system 10 may comprise a binaural hearing system with a first device in a first ear canal and a second device in a second ear contralateral ear canal of a second contralateral ear, in which the second device is similar to the first device. To detect head shadowing a microphone can be positioned such that the head of the user casts an acoustic shadow on the input microphone, for example with the microphone placed on a first side of the user's head opposite a second side of the users head such that the second side faces the sound source. To detect high frequency localization cues from sound diffraction of the pinna of the user, the input microphone can be positioned in the ear canal and also external of the ear canal and within about 5 mm of the entrance of the ear canal, or therebetween, such that the pinna of the ear diffracts sound waves incident on the microphone. This placement of the microphone can provide high frequency localization cues, and can also provide head shadowing of the microphone. The pinna diffraction cues that provide high frequency localization of sound can be present with monaural hearing. The gain for sound input to the external microphone for low frequencies below about 3 kHz is greater than the gain for the canal microphone. This can result in decreased feedback as the canal microphone has decreased gain as compared to the external microphone. The gain for sound input to the canal microphone for high frequencies above about 3 kHz is greater than the gain for the external microphone, such that the user can detect high frequency localization cues above 3 kHz, for example above 4 kHz, when the feedback is minimized.


The gain profiles comprise an input sound to the microphone and an output sound from the output transducer to the user, such that the gain profiles for each of the canal microphone and external microphone can be achieved in many ways with many configurations of at least one of the microphone, the circuitry and the transducer. The gain profile for sound input to the external microphone may comprise low pass components configured with at least one of a low pass microphone, low pass circuitry, or a low pass transducer. The gain profile for sound input to the canal microphone may comprise low pass components configured with at least one of a high pass microphone, high pass circuitry, or a high pass transducer. The circuitry may comprise the sound processor comprising a tangible medium configured to high pass filter the sound input from the canal microphone and low pass filter the sound input from the external microphone.



FIG. 10C shows a canal microphone with high pass filter circuitry and an external microphone with low pass filter circuitry, both coupled to a transducer to provide gain in response to frequency as in FIG. 10B. Canal microphone CM is coupled to high pass filer circuitry HPF. The high pass filter circuitry may comprise known low pass filters and is coupled to a gain block, GAIN2, which may comprise at least one of an amplifier AMP1 or a known sound processor configured to process the output of the high pass filter. External microphone EM is coupled to low pass filer circuitry LPF. The low pass filter circuitry comprise may comprise known low pass filters and is coupled to a gain block, GAIN2, which may comprise at least one of an amplifier AMP2 or a known sound processor configured to process the output of the high pass filter. The output can be combined at the transducer, and the transducer configured to vibrate the eardrum, for example directly. In some embodiments, the output of the canal microphone and output of the external microphone can be input separately to one sound processor and combined, which sound processor may then comprise a an output adapted for the transducer.


FIG. 10D1 shows a canal microphone coupled to first transducer TRANSDUCER1 and an external microphone coupled to a second transducer TRANSDUCER2 to provide gain in response to frequency as in FIG. 10B. The first transducer may comprise output characteristics with a high frequency peak, for example around 8-10 kHz, such that high frequencies are passed with greater energy. The second transducer may comprise a low frequency peak, for example around 1 kHz, such that low frequencies are passed with greater energy. The input of the first transducer may be coupled to output of a first sound processor and a first amplifier as described above. The input of the second transducer may be coupled to output of a second sound processor and a second amplifier. Further improvement in the output profile for the canal microphone can be obtained with a high pass filter coupled to the canal microphone. A low pass filter can also be coupled to the external microphone. In some embodiments, the output of the canal microphone and output of the external microphone can be input separately to one sound processor and combined, which sound processor may then comprise a separate output adapted for each transducer.


FIG. 10D2 shows the canal microphone coupled to a first transducer comprising a first coil wrapped around a core, and the external microphone coupled to a second transducer comprising second a coil wrapped around the core, as in FIG. 10D1. A first coil COIL1 is wrapped around the core and comprises a first number of turns. A second coil COIL2 is wrapped around the core and comprises a second number of turns. The number of turns for each coil can be optimized to produce a first output peak for the first transducer and a second output peak for the second transducer, with the second output peak at a frequency below the a frequency of the first output peak. Although coils are shown, many transducers can be used such as piezoelectric and photostrictive materials, for example as described above. The first transducer may comprise at least a portion of the second transducer, such that first transducer at least partially overlaps with the second transducer, for example with a common magnet supported on the eardrum.


The first input transducer, for example the canal microphone, and second input transducer, for example the external microphone, can be arranged in many ways to detect sound localization cues and minimize feedback. These arrangements can be obtained with at least one of a first input transducer gain, a second input transducer gain, high pass filter circuitry for the first input transducer, low pass filter circuitry for the second input transducer, sound processor digital filters or output characteristics of the at least one output transducer.


The canal microphone may comprise a first input transducer coupled to at least one output transducer to vibrate an eardrum of the ear in response to high frequency sound localization cues above the resonance frequencies of the ear canal, for example resonance frequencies from about 2 kHz to about 3 kHz. The external microphone may comprise a second input transducer coupled to at least one output transducer to vibrate the eardrum in response sound frequencies at or below the resonance frequency of the ear canal. The resonance frequency of the ear canal may comprise frequencies within a range from about 2 to 3 kHz, as noted above.


The first input transducer can be coupled to at least one output transducer to vibrate the eardrum with a first gain for first sound frequencies corresponding to the resonance frequencies of the ear canal. The second input transducer can be coupled to the at least one output transducer to vibrate the eardrum with a second gain for the sound frequencies corresponding to the resonance frequencies of the ear canal, in which the first gain is less than the second gain to minimize feedback.


The first input transducer can be coupled to the at least one output transducer to vibrate the eardrum with a resonance gain for first sound frequencies corresponding to the resonance frequencies of the ear canal and a cue gain for sound localization cue comprising frequencies above the resonance frequencies of the ear canal. The cue gain can be greater than the resonance gain to minimize feedback and allow the user to perceive the sound localization cues.



FIG. 11A shows an elongate support 1110 comprising a plurality of optical fibers 1110P configured to transmit light and receive light to measure displacement of the eardrum. The plurality of optical fibers 1110P comprises at least a first optical fiber 1110A and a second optical fiber 1110B. First optical fiber 1110A is configured to transmit light from a source. Light circuitry comprises the light source and can be configured to emit light energy such that the user perceives sound. The optical transducer assembly OTA can be configured for placement on an outer surface of the eardrum, as described above.


The displacement of the eardrum and optical transducer assembly can be measured with second input transducer which comprises at least one of an optical vibrometer, a laser vibrometer, a laser Doppler vibrometer, or an interferometer configured to generate a signal in response to vibration of the eardrum. A portion of the transmitted light λT can be reflected from at the eardrum and the optical transducer assembly OTA and comprises reflected light λR. The reflected light enters second optical fiber 1110B and is received by an optical detector coupled to a distal end of the second optical fiber 1110B, for example a laser vibrometer detector coupled to detector circuitry to measure vibration of the eardrum. The plurality of optical fibers may comprise a third optical fiber for transmission of light from a laser of the laser vibrometer toward the eardrum. For example, a laser source comprising laser circuitry can be coupled to the proximal end of the support to transmit light toward the ear to measure eardrum displacement. The optical transducer assembly may comprise a reflective surface to reflect light from the laser used for the laser vibrometer, and the optical wavelengths to induce vibration of the eardrum can be separate from the optical wavelengths used to measure vibration of the eardrum. The optical detection of vibration of the eardrum can be used for near-end speech measurement, similar to the piezo electric transducer described above. The optical detection of vibration of the eardrum can be used for noise cancellation, such that vibration of the eardrum is minimized in response to the optical signal reflected from at least one of eardrum or the optical transducer assembly.


Elongate support 1110 and at least one positioner, for example at least one of positioner 1130 or positioner 1140, or both, can be configured to position support 1110 in the ear canal with the electromagnetic energy transducer positioned outside the ear canal, and the microphone positioned at least one of in the ear canal or near the ear canal opening so as to detect high frequency spatial localization clues, as described above. For example, the output energy transducer, or emitter, may comprise a light source configured to emit electromagnetic energy comprising optical frequencies, and the light source can be positioned outside the ear canal, for example in a BTE unit. The light source may comprise at least one of an LED or a laser diode, for example. The light source, also referred to as an emitter, can emit visible light, or infrared light, or a combination thereof. The light source can be coupled to the distal end of the support with a waveguide, such as an optical fiber with a distal end of the optical fiber 110D comprising a distal end of the support. The optical energy delivery transducer can be coupled to the proximal portion of the elongate support to transmit optical energy to the distal end. The positioner can be adapted to position the distal end of the support near an eardrum when the proximal portion is placed at a location near an ear canal opening. The intermediate portion of elongate support 1110 can be sized to minimize contact with a canal of the ear between the proximal portion to the distal end.


The at least one positioner, for example positioner 1130, can improve optical coupling between the light source and a device positioned on the eardrum, so as to increase the efficiency of light energy transfer from the output energy transducer, or emitter, to an optical device positioned on the eardrum. For example, by improving alignment of the distal end 1110D of the support that emits light and a transducer positioned at least one of on the eardrum or in the middle ear. The at least one positioner and elongate support 1110 comprising an optical fiber can be combined with many known optical transducer and hearing devices, for example as described in U.S. application Ser. No. 11/248,459, entitled “Systems and Methods for Photo-Mechanical Hearing Transduction”, the full disclosure of which has been previously incorporated herein by reference, and U.S. Pat. No. 7,289,63, entitled “Hearing Implant”, the full disclosure of which is incorporated herein by reference. The positioner and elongate support may also be combined with photo-electro-mechanical transducers positioned on the ear drum with a support, as described in U.S. Pat. Ser. Nos. 61/073,271; and 61/073,281, both filed on Jun. 17, 2008, the full disclosures of which have been previously incorporated herein by reference.


In specific embodiments, elongate support 1110 may comprise an optical fiber coupled to positioner 1130 to align the distal end of the optical fiber with an output transducer assembly supported on the eardrum. The output transducer assembly may comprise a photodiode configured to receive light transmitted from the distal end of support 1110 and supported with support component 30 placed on the eardrum, as described above. The output transducer assembly can be separated from the distal end of the optical fiber, and the proximal end of the optical fiber can be positioned in the BTE unit and coupled to the light source. The output transducer assembly can be similar to the output transducer assembly described in U.S. 2006/0189841, with positioner 1130 used to align the optical fiber with the output transducer assembly, and the BTE unit may comprise a housing with the light source positioned therein.



FIG. 11B shows a positioner for use with an elongate support as in FIG. 11 A and adapted for placement near the opening to the ear canal. Positioner 1140 includes flanges 1142 that extend radially outward to engage the skin of the ear canal. Flanges 1142 are formed from a flexible material. Openings 1144 are defined by flanges 1142. Openings 1144 permit sound waves to pass positioner 1140 while the positioner is positioned in the ear canal, so that the sound waves are transmitted to the tympanic membrane. Although flanges 1142 define an outer boundary of support 1140 with an elliptical shape, flanges 1142 can comprise an outer boundary with any shape, for example circular. In some embodiments, the positioner has an outer boundary defined by the shape of the individual user's ear canal, for example embodiments where positioner 1140 is made from a mold of the user's ear. Elongate support 1110 extends transversely through positioner 1140.



FIG. 11C shows a positioner adapted for placement near a distal end of the elongate support as in FIG. 11A. Positioner 1130 includes flanges 1132 that extend radially outward to engage the skin of the ear canal. Flanges 1132 are formed from a flexible material. Openings 1134 are defined by flanges 1132. Openings 1134 permit sound waves to pass positioner 1130 while the positioner is positioned in the ear canal, so that the sound waves are transmitted to the tympanic membrane. Although flanges 1132 define an outer boundary of support 1130 with an elliptical shape, flanges 1132 can comprise an outer boundary with any shape, for example circular. In some embodiments, the positioner has an outer boundary defined by the shape of the individual user's ear canal, for example embodiments where positioner 1130 is made from a mold of the user's ear. Elongate support 1110 extends transversely through positioner 1130.


Although an electromagnetic transducer comprising coil 1119 is shown positioned on the end of elongate support 1110, the positioner and elongate support can be used with many types of transducers positioned at many locations, for example optical electromagnetic transducers positioned outside the ear canal and coupled to the support to deliver optical energy along the support, for example through at least one optical fiber. The at least one optical fiber may comprise a single optical fiber or a plurality of two or more optical fibers of the support. The plurality of optical fibers may comprise a parallel configuration of optical fibers configured to transmit at least two channels in parallel along the support toward the eardrum of the user.


While the exemplary embodiments have been described above in some detail for clarity of understanding and by way of example, a variety of additional modifications, adaptations, and changes may be clear to those of skill in the art. Hence, the scope of the present invention is limited solely by the appended claims.

Claims
  • 1. A communication device for use with an ear of a user, the ear comprising a pinna, an eardrum, an ear canal and an opening of the ear canal, the device comprising: an ear canal input transducer to detect high frequency localization cues of the pinna comprising high frequencies of sound above a resonance frequency of the ear canal when placed at least one of inside the ear canal or near the opening of the ear canal;an external input transducer to detect sound comprising frequencies of sound at or below the resonance frequency when placed outside the ear canal away from the ear canal opening;at least one output transducer sized for placement inside the ear canal to vibrate the eardrum of the user; andcircuitry comprising a processor and amplifiers coupled to the ear canal input transducer, the external input transducer and the at least one output transducer, the processor configured to output the high frequencies of sound with a first high frequency gain from the ear canal input transducer and a second high frequency gain from the external input transducer, the first high frequency gain greater than the second high frequency gain in order to vibrate the eardrum with amplified high frequency localization cues of the pinna from the ear canal input transducer and wherein the processor outputs the frequencies of sound at or below the resonance frequency with a first gain from the ear canal input transducer and a second gain from the external input transducer, the second gain greater than the first gain to provide sound from the external input transducer to the user.
  • 2. The device of claim 1 wherein the ear canal input transducer comprises at least one of a first microphone configured to detect sound from air or a first acoustic sensor configured to detect vibration from tissue and wherein the external input transducer comprises at least one of a second microphone configured to detect sound from air or a second acoustic sensor configured to detect vibration from tissue.
  • 3. The device of claim 1 wherein the ear canal input transducer comprises a microphone configured to detect the localization cues comprising the high frequencies and wherein the at least one output transducer is acoustically coupled to the ear canal input transducer when the ear canal input transducer is positioned in the ear canal and wherein the external input transducer is positioned away from the ear canal opening to reduce feedback when the ear canal input transducer detects the high frequency localization cues.
  • 4. The device of claim 1 wherein the localization cues comprising the high frequencies of sound comprise frequencies above about 4 kHz and wherein the ear canal input transducer is coupled to the circuitry and at least one output transducer to transmit the frequencies above at least about 4 kHz to the user with the first high frequency gain and to transmit low frequencies below about 3 kHz with the first gain and wherein the first high frequency gain is greater than the first gain so as to reduce feedback from the output transducer to the ear canal input transducer.
  • 5. The device of claim 4 wherein the high frequency localization cues from the pinna comprise a sound diffraction cue from the pinna and wherein the ear canal input transducer, the circuitry and the at least one output transducer are configured to detect and amplify the sound diffraction cue from the pinna of the ear of the user.
  • 6. The device of claim 1 wherein the resonance frequency-of the ear canal comprises frequencies within a range from about 2 to 3 kHz.
  • 7. The device of claim 1 wherein the ear canal input transducer is coupled to the at least one output transducer to vibrate the eardrum with a first resonance gain for first sound frequencies corresponding to the resonance frequencies of the ear canal and wherein the first high frequency gain is greater than the first resonance gain to reduce feedback.
  • 8. The device of claim 1 wherein the ear canal input transducer is coupled to the at least one output transducer to vibrate the eardrum with a first resonance gain for sound frequencies corresponding to the resonance frequencies of the ear canal and wherein the external input transducer is coupled to the at least one output transducer to vibrate the eardrum with a second resonance gain for the sound frequencies corresponding to the resonance frequencies of the ear canal and wherein the second resonance gain is greater than the first resonance gain amplify the sound frequencies corresponding to the resonance frequencies and to reduce feedback.
  • 9. The device of claim 1 wherein the external input transducer is configured to detect low frequency sound without high frequency localization cues from the pinna of the ear when placed outside the ear canal to reduce feedback from the transducer.
  • 10. The device of claim 9 wherein the low frequency sound comprises frequencies below about 3 kHz.
  • 11. The device of claim 1 wherein the high frequencies of sound comprise frequencies above about 4 kHz.
  • 12. The device of claim 11, wherein the circuitry is coupled to the external input transducer and the at least one output transducer to transmit low frequency sound comprising frequencies below about 4 kHz from the external input transducer to the user.
  • 13. The device of claim 11, wherein the circuitry comprising the processor and amplifiers is coupled to the ear canal input transducer, the external input transducer and the at least one output transducer to transmit high frequencies from the ear canal input transducer and low frequencies from the external input transducer to the user so as to provide the localization cues and reduce feedback.
  • 14. The device of claim 1 wherein the at least one output transducer comprises a first output transducer and a second output transducer, wherein the circuitry is coupled to the first output transducer and the ear canal input transducer and configured to transmit the high frequencies of sound, and wherein the circuitry is coupled to the second output transducer and the external input transducer and configured to transmit low frequencies of sound.
  • 15. The device of claim 1 wherein the at least one output transducer comprises at least one of an acoustic speaker configured for placement inside the ear canal, a magnet supported with a support configured for placement on an eardrum of the user, an optical transducer supported with a support configured for placement on the eardrum of the user, a magnet configured for placement in a middle ear of the user, or an optical transducer configured for placement in the middle ear of the user.
  • 16. The device of claim 15 wherein the at least one output transducer comprises the magnet supported with the support configured for placement on an eardrum of the user, and wherein the at least one output transducer further comprises at least one coil configured for placement in the ear canal to couple to the magnet to transmit sound to the user.
  • 17. The device of claim 16 wherein the at least one coil comprises a first coil and a second coil, the first coil coupled to the ear canal input transducer and configured to transmit first frequencies from the ear canal input transducer to the magnet, the second coil coupled to the external input transducer and configured to transmit second frequencies from the external input transducer to the magnet.
  • 18. The device of claim 15 wherein the at least one output transducer comprises the optical transducer supported with the support configured for placement on the eardrum of the user and wherein the optical transducer further comprises a photodetector coupled to at least one of a coil or a piezo electric transducer supported with the support and configured to vibrate the eardrum.
  • 19. The device of claim 1 wherein the ear canal input transducer is configured to generate a first audio signal and the external input transducer is configured to generate a second audio signal and wherein the at least one output transducer is configured to vibrate with the first high frequency gain in response to the first audio signal and the second high frequency gain in response to the second audio signal to reduce feedback.
  • 20. The device of claim 1 further comprising wireless communication circuitry configured to transmit near-end sound from the user to a far-end person when the user speaks.
  • 21. The device of claim 20 wherein the wireless communication circuitry is configured to transmit the near-end sound from at least one of the ear canal input transducer or the external input transducer.
  • 22. The device of claim 21 wherein the wireless communication circuitry is configured to transmit the near-end sound from the external input transducer.
  • 23. The device of claim 20 further comprising a third input transducer coupled to the wireless communication circuitry, the third input transducer configured to couple to tissue of the user and transmit near-end speech from the user to the far-end person in response to bone conduction vibration when the user speaks.
  • 24. The device of claim 1 further comprising: a second device for use with a second contralateral ear of the user, the second device comprising, a third input transducer configured for placement inside a second ear canal or near an opening of the second ear canal to detect second high frequency localization cues, a fourth input transducer configured for placement outside the second ear canal, and a second at least one output transducer configured for placement inside the second ear canal, and wherein the second at least one output transducer is acoustically coupled to the third input transducer when the second at least one output transducer is positioned in the second ear canal and wherein fourth input transducer is positioned away from the second ear canal opening to reduce feedback when the third input transducer detects the second high frequency localization cues.
  • 25. The communication device of claim 1, wherein the circuitry comprises a high pass filter, a low pass filter, the amplifiers, and the processor.
CROSS REFERENCE TO RELATED APPLICATIONS DATA

The present application claims the benefit under 35 USC 119(e) of U.S. Provisional Application No. 60/979,645 filed Oct. 12, 2007; the full disclosure of which is incorporated herein by reference in its entirety. The subject matter of the present application is related to copending U.S. patent application Ser. Nos. 10/902,660 filed Jul. 28, 2004, entitled “Transducer for Electromagnetic Hearing Devices”; 11/248,459 filed on Oct. 11, 2005, entitled “Systems and Methods for Photo-Mechanical Hearing Transduction”; 11/121,517 filed May 3, 2005, entitled “Hearing System Having Improved High Frequency Response”; 11/264,594 filed on Oct. 31, 2005, entitled “Output Transducers for Hearing Systems”; 60/702,532 filed on Jul. 25, 2006, entitled “Light-Actuated Silicon Sound Transducer”; 61/073,271 filed on Jun. 17, 2008, entitled “Optical Electro-Mechanical Hearing Devices With Combined Power and Signal Architectures”; 61/073,281 filed on Jun. 17, 2008, entitled “Optical Electro-Mechanical Hearing Devices with Separate Power and Signal Components”; U.S. Patent Application Ser. No. 61/099,087, filed on Sep. 22, 2008, entitled “Transducer Devices and Methods for Hearing”; and U.S. patent application Ser. No. 12/244,266, filed on Oct. 2, 2008, entitled “Energy Delivery and Microphone Placement Methods for Improved Comfort in an Open Canal Hearing Aid”.

US Referenced Citations (251)
Number Name Date Kind
3440314 Frisch Apr 1969 A
3549818 Turner et al. Dec 1970 A
3585416 Mellen Jun 1971 A
3594514 Wingrove Jul 1971 A
3710399 Hurst Jan 1973 A
3712962 Epley Jan 1973 A
3764748 Branch et al. Oct 1973 A
3808179 Gaylord Apr 1974 A
3882285 Nunley et al. May 1975 A
3985977 Beaty et al. Oct 1976 A
4002897 Kleinman et al. Jan 1977 A
4061972 Burgess Dec 1977 A
4075042 Das Feb 1978 A
4098277 Mendell Jul 1978 A
4109116 Victoreen Aug 1978 A
4120570 Gaylord Oct 1978 A
4248899 Lyon et al. Feb 1981 A
4252440 Frosch et al. Feb 1981 A
4303772 Novicky Dec 1981 A
4319359 Wolf Mar 1982 A
4334315 Ono et al. Jun 1982 A
4334321 Edelman Jun 1982 A
4339954 Anson et al. Jul 1982 A
4357497 Hochmair et al. Nov 1982 A
4380689 Giannetti Apr 1983 A
4428377 Zollner et al. Jan 1984 A
4524294 Brody Jun 1985 A
4540761 Kawamura et al. Sep 1985 A
4556122 Goode Dec 1985 A
4592087 Killion May 1986 A
4606329 Hough Aug 1986 A
4611598 Hortmann et al. Sep 1986 A
4628907 Epley Dec 1986 A
4641377 Rush et al. Feb 1987 A
4689819 Killion Aug 1987 A
4696287 Hortmann et al. Sep 1987 A
4729366 Schaefer Mar 1988 A
4741339 Harrison et al. May 1988 A
4742499 Butler May 1988 A
4756312 Epley Jul 1988 A
4766607 Feldman Aug 1988 A
4774933 Hough et al. Oct 1988 A
4776322 Hough et al. Oct 1988 A
4800884 Heide et al. Jan 1989 A
4817607 Tatge Apr 1989 A
4840178 Heide et al. Jun 1989 A
4845755 Busch et al. Jul 1989 A
4932405 Peeters et al. Jun 1990 A
4936305 Ashtiani et al. Jun 1990 A
4944301 Widin et al. Jul 1990 A
4948855 Novicky Aug 1990 A
4957478 Maniglia Sep 1990 A
4999819 Newnham et al. Mar 1991 A
5003608 Carlson Mar 1991 A
5012520 Steeger Apr 1991 A
5015224 Mariglia May 1991 A
5015225 Hough et al. May 1991 A
5031219 Ward et al. Jul 1991 A
5061282 Jacobs Oct 1991 A
5066091 Stoy et al. Nov 1991 A
5094108 Kim et al. Mar 1992 A
5117461 Moseley May 1992 A
5142186 Cross et al. Aug 1992 A
5163957 Sade et al. Nov 1992 A
5167235 Seacord et al. Dec 1992 A
5201007 Ward et al. Apr 1993 A
5259032 Perkins et al. Nov 1993 A
5272757 Scofield et al. Dec 1993 A
5276910 Buchele Jan 1994 A
5277694 Leysieffer et al. Jan 1994 A
5360388 Spindel et al. Nov 1994 A
5378933 Pfannenmueller et al. Jan 1995 A
5402496 Soli et al. Mar 1995 A
5411467 Hortmann et al. May 1995 A
5425104 Shennib Jun 1995 A
5440082 Claes Aug 1995 A
5440237 Brown et al. Aug 1995 A
5455994 Termeer et al. Oct 1995 A
5456654 Ball Oct 1995 A
5531787 Lesinski et al. Jul 1996 A
5531954 Heide et al. Jul 1996 A
5535282 Luca Jul 1996 A
5554096 Ball Sep 1996 A
5558618 Maniglia Sep 1996 A
5606621 Reiter et al. Feb 1997 A
5624376 Ball et al. Apr 1997 A
5707338 Adams et al. Jan 1998 A
5715321 Andrea et al. Feb 1998 A
5721783 Anderson Feb 1998 A
5729077 Newnham et al. Mar 1998 A
5740258 Goodwin-Johansson Apr 1998 A
5762583 Adams et al. Jun 1998 A
5772575 Lesinski et al. Jun 1998 A
5774259 Saitoh et al. Jun 1998 A
5782744 Money Jul 1998 A
5788711 Lehner et al. Aug 1998 A
5795287 Ball et al. Aug 1998 A
5797834 Goode Aug 1998 A
5800336 Ball et al. Sep 1998 A
5804109 Perkins Sep 1998 A
5804907 Park et al. Sep 1998 A
5814095 Muller et al. Sep 1998 A
5825122 Givargizov et al. Oct 1998 A
5836863 Bushek et al. Nov 1998 A
5842967 Kroll Dec 1998 A
5857958 Ball et al. Jan 1999 A
5859916 Ball et al. Jan 1999 A
5879283 Adams et al. Mar 1999 A
5888187 Jaeger et al. Mar 1999 A
5897486 Ball et al. Apr 1999 A
5899847 Adams et al. May 1999 A
5900274 Chatterjee et al. May 1999 A
5906635 Maniglia May 1999 A
5913815 Ball et al. Jun 1999 A
5940519 Kuo Aug 1999 A
5949895 Ball et al. Sep 1999 A
5987146 Pluvinage et al. Nov 1999 A
6005955 Kroll et al. Dec 1999 A
6024717 Ball et al. Feb 2000 A
6045528 Arenberg et al. Apr 2000 A
6050933 Bushek et al. Apr 2000 A
6068589 Neukermans May 2000 A
6068590 Brisken May 2000 A
6084975 Perkins Jul 2000 A
6093144 Jaeger et al. Jul 2000 A
6135612 Clore Oct 2000 A
6137889 Shennib et al. Oct 2000 A
6139488 Ball Oct 2000 A
6153966 Neukermans Nov 2000 A
6174278 Jaeger et al. Jan 2001 B1
6181801 Puthuff et al. Jan 2001 B1
6190305 Ball et al. Feb 2001 B1
6190306 Kennedy Feb 2001 B1
6208445 Reime Mar 2001 B1
6217508 Ball et al. Apr 2001 B1
6222302 Imada et al. Apr 2001 B1
6222927 Feng et al. Apr 2001 B1
6240192 Brennan et al. May 2001 B1
6241767 Stennert et al. Jun 2001 B1
6261224 Adams et al. Jul 2001 B1
6277148 Dormer Aug 2001 B1
6312959 Datskos Nov 2001 B1
6339648 McIntosh et al. Jan 2002 B1
6354990 Juneau et al. Mar 2002 B1
6366863 Bye et al. Apr 2002 B1
6385363 Rajic et al. May 2002 B1
6387039 Moses May 2002 B1
6393130 Stonikas et al. May 2002 B1
6422991 Jaeger Jul 2002 B1
6432248 Popp et al. Aug 2002 B1
6436028 Dormer Aug 2002 B1
6438244 Juneau et al. Aug 2002 B1
6445799 Taenzer et al. Sep 2002 B1
6473512 Juneau et al. Oct 2002 B1
6475134 Ball et al. Nov 2002 B1
6493454 Loi et al. Dec 2002 B1
6519376 Biagi et al. Feb 2003 B2
6536530 Schultz et al. Mar 2003 B2
6537200 Leysieffer et al. Mar 2003 B2
6549633 Westermann Apr 2003 B1
6554761 Puria et al. Apr 2003 B1
6575894 Leysieffer et al. Jun 2003 B2
6592513 Kroll et al. Jul 2003 B1
6603860 Taezner et al. Aug 2003 B1
6620110 Schmid Sep 2003 B2
6626822 Jaeger et al. Sep 2003 B1
6629922 Puria et al. Oct 2003 B1
6668062 Luo et al. Dec 2003 B1
6676592 Ball et al. Jan 2004 B2
6695943 Juneau et al. Feb 2004 B2
6724902 Shennib et al. Apr 2004 B1
6728024 Ribak Apr 2004 B2
6735318 Cho May 2004 B2
6754358 Boeson et al. Jun 2004 B1
6801629 Brimhall et al. Oct 2004 B2
6829363 Sacha Dec 2004 B2
6842647 Griffith et al. Jan 2005 B1
6888949 Vanden Berghe et al. May 2005 B1
6900926 Ribak May 2005 B2
6912289 Vonlanthen et al. Jun 2005 B2
6920340 Laderman Jul 2005 B2
6940989 Shennib et al. Sep 2005 B1
D512979 Corcoran et al. Dec 2005 S
6975402 Bisson et al. Dec 2005 B2
6978159 Feng et al. Dec 2005 B2
7043037 Lichtblau May 2006 B2
7050675 Zhou May 2006 B2
7072475 DeNap et al. Jul 2006 B1
7076076 Bauman Jul 2006 B2
7095981 Voroba et al. Aug 2006 B1
7167572 Harrison et al. Jan 2007 B1
7174026 Niederdrank Feb 2007 B2
7203331 Boesen Apr 2007 B2
7239069 Cho Jul 2007 B2
7245732 Jorgensen et al. Jul 2007 B2
7255457 Ducharme et al. Aug 2007 B2
7266208 Charvin et al. Sep 2007 B2
7289639 Abel et al. Oct 2007 B2
7322930 Jaeger et al. Jan 2008 B2
7376563 Leysieffer et al. May 2008 B2
7421087 Perkins et al. Sep 2008 B2
7444877 Li et al. Nov 2008 B2
7668325 Puria et al. Feb 2010 B2
7867160 Pluvinage et al. Jan 2011 B2
8233651 Haller Jul 2012 B1
20010024507 Boesen Sep 2001 A1
20010027342 Dormer Oct 2001 A1
20020012438 Leysieffer et al. Jan 2002 A1
20020030871 Anderson et al. Mar 2002 A1
20020086715 Sahagen Jul 2002 A1
20020172350 Edwards et al. Nov 2002 A1
20020183587 Dormer Dec 2002 A1
20030064746 Rader et al. Apr 2003 A1
20030125602 Sokolich et al. Jul 2003 A1
20030142841 Wiegand Jul 2003 A1
20030208099 Ball Nov 2003 A1
20040165742 Shennib et al. Aug 2004 A1
20040202340 Armstrong et al. Oct 2004 A1
20040208333 Cheung et al. Oct 2004 A1
20040234089 Rembrand et al. Nov 2004 A1
20040234092 Wada et al. Nov 2004 A1
20040240691 Grafenberg Dec 2004 A1
20050020873 Berrang et al. Jan 2005 A1
20050036639 Bachler et al. Feb 2005 A1
20050163333 Abel et al. Jul 2005 A1
20050226446 Luo et al. Oct 2005 A1
20060023908 Perkins et al. Feb 2006 A1
20060062420 Araki Mar 2006 A1
20060107744 Li et al. May 2006 A1
20060177079 Baekgaard Jensen et al. Aug 2006 A1
20060189841 Pluvinage Aug 2006 A1
20060233398 Husung Oct 2006 A1
20060251278 Puria et al. Nov 2006 A1
20070083078 Easter et al. Apr 2007 A1
20070100197 Perkins et al. May 2007 A1
20070127748 Carlile et al. Jun 2007 A1
20070127766 Combest Jun 2007 A1
20070135870 Shanks et al. Jun 2007 A1
20070191673 Ball et al. Aug 2007 A1
20070236704 Carr Oct 2007 A1
20070250119 Tyler et al. Oct 2007 A1
20070286429 Grafenberg et al. Dec 2007 A1
20080021518 Hochmair et al. Jan 2008 A1
20080051623 Schneider et al. Feb 2008 A1
20080107292 Kornagel May 2008 A1
20090092271 Fay et al. Apr 2009 A1
20090310805 Petroff Dec 2009 A1
20100034409 Fay et al. Feb 2010 A1
20100048982 Puria et al. Feb 2010 A1
20100202645 Puria et al. Aug 2010 A1
20110077453 Pluvinage et al. Mar 2011 A1
Foreign Referenced Citations (20)
Number Date Country
2004-301961 Feb 2005 AU
2044870 Mar 1972 DE
3243850 May 1984 DE
3508830 Sep 1986 DE
0 296 092 Dec 1988 EP
1 845 919 Oct 2007 EP
2455820 Nov 1980 FR
60-154800 Aug 1985 JP
2004-187953 Jul 2004 JP
WO 9745074 Dec 1997 WO
WO 9903146 Jan 1999 WO
WO 9915111 Apr 1999 WO
WO 0150815 Jul 2001 WO
WO 0158206 Aug 2001 WO
WO 0158206 Feb 2002 WO
WO 03063542 Jul 2003 WO
WO 2004010733 Jan 2004 WO
WO 2005015952 Feb 2005 WO
WO 2006042298 Apr 2006 WO
WO 2006075175 Jul 2006 WO
Non-Patent Literature Citations (69)
Entry
International Search Report and Written Opinion of PCT Application No. PCT/US08/79868, dated Dec. 24, 2008; 16 pages total.
Atasoy [Paper] “Opto-acoustic Imaging” for BYM504E Biomedical Imaging Systems class at ITU, downloaded from the Internet <<http://www2.itu.edu.tr/˜cilesiz/courses/BYM504-2005-OA—504041413.pdf>>, 14 pages.
Athanassiou et al., “Laser controlled photomechanical actuation of photochromic polymers Microsystems” Rev. Adv. Mater. Sci., 2003; 5:245-251.
Ayatollahi et al., “Design and Modeling of Micromachined Condenser MEMS Loudspeaker using Permanent Magnet Neodymium-Iron-Boron (Nd-Fe-B),” IEEE International Conference on Semiconductor Electronics, 2006. ICSE '06, Oct. 29, 2006-Dec. 1, 2006; pp. 160-166.
Baer et al., “Effects of Low Pass Filtering on the Intelligibility of Speech in Noise for People With and Without Dead Regions at High Frequencies,” J Acoust Soc Am. Sep. 2002;112(3 Pt 1):1133-1144.
Best et al., “Influence of High Frequencies on Speech Locatisation,” Abstract 981, Feb. 24, 2003, retrieved from: <http://www.aro.org/abstracts.html>.
Birch et al., “Microengineered systems for the hearing impaired,” IEE Colloquium on Medical Applications of Microengineering, Jan. 31, 1996; pp. 2/1-2/5.
Burkhard et al., “Anthropometric Manikin for Acoustic Research,” J Acoust Soc Am. Jul. 1975;58(1):214-22.
Camacho-Lopez et al., “Fast Liquid Crystal Elastomer Swims Into the Dark,” Electronic Liquid Crystal Communications, (Nov. 26, 2003), 9 pages total.
Carlile et al., Abstract 1264—“Spatialisation of Talkers and the Segregation of Concurrent Speech ,” Feb. 24, 2004, retrieved from: http://www.aro.org/archives/2004/2004—1264.html.
“EAR”, Retrieved from the Internet: <<http://wwwmgs.bionet.nsc.ru/mgs/gnw/trrd/thesaurus/Se/ear.html>>, 4 pages total.
Cheng et al., “A Silicon Microspeaker for Hearing Instruments,” Journal of Micromechanics and Microengineering 2004; 14(7):859-866.
Datskos et al., “Photoinduced and thermal stress in silicon microcantilevers”, Applied Physics Letters, Oct. 19, 1998; 73(16):2319-2321.
Decraemer et al., “A Method for Determining Three-Dimensional Vibration in the Ear,” Hearing Research, 77 (1-2): 19-37 (1994).
Fay et al., “Cat Eardrum Response Mechanics,” Mechanics and Computation Division, Department of Mechanical Engineering, Stanford University, (2002), 10 pages total.
Fletcher, “Effects of Distortion on the Individual Speech Sounds”, Chapter 18, ASA Edition of Speech and Hearing in Communication, Acoust Soc.of Am. (republished in 1995) pp. 415-423.
Freyman et al., “Spatial Release from Informational Masking in Speech Recognition,” J Acoust Soc Am. May 2001;109(5 Pt 1):2112-2122.
Freyman et al., “The Role of Perceived Spatial Separation in the Unmasking of Speech,” J Acoust Soc Am. Dec. 1999;106(6):3578-3588.
Gennum, GA3280 Preliminary Data Sheet: Voyageur TD Open Platform DSP System for Ultra Low Audio Processing, downloaded from the Internet: <<http://www.sounddesigntechnologies.com/products/pdf/37601DOC.pdf>>, Oct. 2006; 17 pages.
Gobin et al; “Comments on the physical basis of the active materials concept” Proc. SPIE 4512:84-92.
Hato et al., “Three-Dimensional Stapes Footplate Motion in Human Temporal Bones.” Audiol Neurootol, 2003; 8: 140-152.
“Headphones” Wikipedia Entry, downloaded from the Internet : <<http://en.wikipedia.org/wiki/Headphones>>, 9 pages total.
Hofman et al., “Relearning Sound Localization With New Ears,” Nat Neurosci. Sep. 1998;1(5):417-421.
Jin et al., “Speech Localization”, J. Audio Eng. Soc. convention paper, presented at the AES 112th Convention, Munich, Germany, May 10-13, 2002, 13 paegs total.
Killion, “Myths About Hearing Noise and Directional Microphones,” The Hearing Review, vol. 11, No. 2, (Feb. 2004), pp. 14, 16, 18, 19, 72 & 73.
Killion, “SNR loss: I can hear what people say but I can't understand them,” The Hearing Review, 1997; 4(12):8-14.
Lee et al., “A Novel Opto-Electromagnetic Actuator Coupled to the tympanic Membrane” Journal of Biomechanics , 41(16): 3515-3518.
Lezal, “Chalcogenide glasses—survey and progress”, J. Optoelectron Adv Mater., Mar. 2003; 5 (1):23-34.
Martin et al. “Utility of Monaural Spectral Cues is Enhanced in the Presence of Cues to Sound-Source Lateral Angle,” JARO, vol. 5, (2004), pp. 80-89.
Moore, “Loudness Perception and Intensity Resolution”, Cochlear Hearing Loss, Whurr Publishers Ltd., (1998), Chapter 4, pp. 90-115.
Musicant et al., “Direction-Dependent Spectral Properties of Cat External Ear: New Data and Cross-Species Comparisons,” J. Acostic. Soc. Am, May 10-13, 2002, Feb. 1990; 8(2):757-781.
National Semiconductor, LM4673 Boomer: Filterless, 2.65W, Mono, Class D Audio Power Amplifier, [Data Sheet] downloaded from the Internet: <<http://www.national.com/ds/LM/LM4673.pdf>>; Nov. 1, 2007; 24 pages.
Poosanaas et al., “Influence of sample thickness on the performance of photostrictive ceramics,” J. App. Phys., Aug. 1, 1998, 84(3):1508-1512.
Puria et al., “A gear in the middle ear,” ARO Denver CO, 2007b.
Puria and Allen, “Measurements and Model of the Cat Middle Ear: Evidence of Tympanic Membrane Acoustic Delay,” Journal of the Acoustical Society of America, 104 (6): 3463-3481 (1998).
Puria et al., “Middle Ear Morphometry From Cadaveric Temporal Bone MicroCT Imaging,” Proceedings of the 4th International Symposium, Zurich, Switzerland, Jul. 27-30, 2006, Middle Ear Mechanics in Research and Otology, pp. 259-268.
Puria et al., “Sound-Pressure Measurements in the Cochlear Vestibule of Human-Cadaver Ears,” Journal of the Acoustical Society of America, 101 (5-1): 2754-2770, (1997).
Shaw, “Transformation of Sound Pressure Level From the Free Field to the Eardrum in the Horizontal Plane,” J. Acoust. Soc. Am., Dec. 1974; 56(6):1848-1861.
Shih, “Shape and displacement control of beams with various boundary conditions via photostrictive optical actuators,” Proc. IMECE Nov. 2003, pp. 1-10.
Stuchlik et al, “Micro-Nano actuators driven by polarized light”, IEE Proc. Sci. Meas. Techn. Mar. 2004, 151(2::131-136.
Suski et al., Optically activated ZnO/SiO2/Si cantilever beams, Sensors & Actuators, 1990; 24:221-225.
Takagi et al.; “Mechanochemical Synthesis of Piezoelectric PLZT Powder”, KONA, 2003, 151(21):234-241.
Thakoor et al., “Optical microactuation in piezoceramics”, Proc. SPIE, Jul. 1998; 3328:376-391.
Tzou et al; “Smart Materials, Precision Sensors/Actuators, Smart Structures, and Structronic Systems”, Mechanics of Advanced Materials and Structures, 2004;11:367-393.
Uchino et al.; “Photostricitve actuators,” Ferroelectrics 2001; 258:147-58.
Vickers et al., “Effects of Low-Pass Filtering on the Intelligibility of Speech in Quiet for People With and Without Dead Regions at High Frequencies,” J Acoust Soc Am. Aug. 2001;110(2):1164-1175.
Wang et al., “Preliminary Assessment of Remote Photoelectric Excitation of an Actuator for a Hearing Implant,” Proceeding of the 2005 IEEE, Engineering in Medicine and Biology 27th Annual Conference, Shanghai, China, Sep. 1-4, 2005, pp. 6233-6234.
Wiener et al., “On the Sound Pressure Transformation by the Head and Auditory Meatus of the Cat”, Acta Otolaryngol. Mar. 1966;61(3):255-269.
Wightman et al., “Monaural Sound Localization Revisited,” J Acoust Soc Am. Feb. 1997;101(2):1050-63.
Yi et al., “Piezoelectric Microspeaker with Compressive Nitride Diaphragm,” The Fifteenth IEEE International Conference on Micro Electro Mechanical Systems, 2002; pp. 260-263.
Yu et al. “Photomechanics: Directed bending of a polymer film by light”, Nature, Sep. 2003; 425(6954):145.
U.S. Appl. No. 61/073,271, filed Jun. 17, 2008, inventor: Lee Felsenstein.
U.S. Appl. No. 61/073,281, filed Jun. 17, 2008, inventor: Lee Felsenstein.
U.S. Appl. No. 60/702,532, filed Jul. 25, 2005, inventor: Nikolai Aljuri.
U.S. Appl. No. 61/099,087, filed Sep. 22, 2008, inventor: Paul Rucker.
U.S. Appl. No. 12/244,266, filed Oct. 2, 2008, inventor: Jonathan P. Fay.
Thompson. Tutorial on microphone technologies for directional hearing aids. Hearing Journal. Nov. 2003; 56(11):14-16,18, 20-21.
European search report and opinion dated Jun. 12, 2009 for EP 06758467.2.
International search report and written opinion dated Aug. 7, 2009 for PCT/US2009/047682.
International search report and written opinion dated Sep. 20, 2006 for PCT/US2005/036756.
International search report and written opinion dated Oct. 17, 2007 for PCT/US2006/015087.
International search report and written opinion dated Nov. 23, 2009 for PCT/US2009/047685.
International search report and written opinion dated Dec. 8, 2008 for PCT/US2008/078793.
Lee, et al. The optimal magnetic force for a novel actuator coupled to the tympanic membrane: a finite element analysis. Biomedical engineering: applications, basis and communications. 2007; 19(3):171-177.
Murugasu, et al. Malleus-to-footplate versus malleus-to-stapes-head ossicular reconstruction prostheses: temporal bone pressure gain measurements and clinical audiological data. Otol Neurotol. Jul. 2005; 2694):572-582.
Puria, et al. Malleus-to-footplate ossicular reconstruction prosthesis positioning: cochleovestibular pressure optimization. Otol Nerotol. May 2005; 2693):368-379.
Sekaric, et al. Nanomechanical resonant structures as tunable passive modulators. App. Phys. Left. Nov. 2003; 80(19):3617-3619.
Sound Design Technologies, —Voyager TDTM Open Platform DSP System for Ultra Low Power Audio Processing—GA3280 Data Sheet. Oct. 2007; retrieved from the Internet: <<http://www.sounddes.com/pdf/37601DOC.pdf>>, 15 pages total.
Wang, et al. Preliminary Assessment of Remote Photoelectric Excitation of an Actuator for a Hearing Implant. Proceeding of the 2005 IEEE, Engineering in Medicine and Biology 27th nnual Conference, Shanghai, China. Sep. 1-4, 2005; 6233-6234.
Related Publications (1)
Number Date Country
20090097681 A1 Apr 2009 US
Provisional Applications (1)
Number Date Country
60979645 Oct 2007 US