Abstract: A bone conduction hearing aid includes a vibrator carried by the insertion end of the hearing aid. When the hearing aid is inserted into the ear canal of a patient, the vibrator is positioned in the ear canal adjacent the mastoid bone. A microphone receives sound waves and outputs a microphone signal to the hearing aid electronics where the microphone signal is amplified and then sent to the vibrator, causing the vibrator to vibrate. Vibrations produced by the vibrator are transferred to the opposite cochlea by way of the mastoid bone, enabling enhanced hearing perception in patients with hearing loss in one ear. Transfer of vibrations to the bones of the middle ear also assists patients with conductive pathology in one ear. The hearing aid may also function to enhance communication in high noise environments. Feedback from the vibrator to the microphone is eliminated electronically. Various alternate forms of feedback elimination are also contemplated by the invention.

Abstract: The present invention is directed to a communication system wherein bone conducted ultrasonic signals are used as carriers to efficiently produce high fidelity, wide audio bandwidth sound. Exemplary embodiments rely on the use of modulation techniques which can achieve high fidelity audible sound, such as carrier plus single sideband (SSB) modulation. Known non-linearities within the ear itself can be exploited to demodulate the modulated ultrasonic carrier without producing audible sounds at the input to the user's ear. The non-linearities of the ear itself, in conjunction with the human brain's perception of audible frequencies generated in response to modulated ultrasonic stimulation, are relied upon to detect audio information.

Abstract: Implantable microphone devices that may be utilized in hearing systems are provided. An implantable microphone device allows the implantable microphone's frequency response and sensitivity to be selected. A microphone device with an increased membrane flexibility and a decreased acoustic compliance of the sealed cavity. Vibrations of a membrane are transmitted through a primary air cavity and through an aperture of a microphone. Keeping a flexible membrane and decreasing the sealed air cavity compliance are the preferred way to simultaneously increase overall sensitivity of the device, and move the resonance peak to higher frequencies.

Abstract: A system and method to compensate for changes in the frequency response of a microphone caused by factors interfering with the receipt of acoustic sound in the microphone. The system includes at least a microphone and a signal processor. The signal processor is operational to process at least one feedback frequency response from the microphone to generate at least one test parameter. The signal processor uses the at least one test parameter to determine at least one operational characteristic of the microphone. The feedback frequency response is generated by the microphone in response to acoustic feedback. The acoustic feedback is generated by actuation of a transducer in response to at least one test signal that is provided to the transducer. The signal processor uses the at least one test parameter to process acoustic frequency responses from the microphone to compensate for changes in the acoustic frequency responses of the microphone.

Abstract: It is intended to provide a hearing aid adapted to primarily listen to a desired sound when a person suffering from some impairment in hearing ability makes conversation to others or in watching television. The hearing aid is constructed of: a main body portion provided with a microphone, an amplifier and a driving battery; and, a speaker portion constructed of a bone conduction speaker connected with the main body portion. In a preferable form of the bone conduction speaker: a yoke is provided with a central magnetic pole surrounded by a voice coil; the yoke extend in four directions to form extensions, a pair of diametrically opposing ones of which have each of magnets mounted on each of the pair. Each of the remaining pair of the extensions is provided an upright support portion for fixedly supporting a diaphragm; and, the diaphragm is fixedly mounted on the support portions.

Abstract: An audio user interface is provided in which items are represented in an audio field by corresponding synthesized sound sources from where sounds related to the items appear to emanate. The location of each sound source is specified relative to an associated one of multiple audio-field references. The offset of each of these audio-field references relative to a presentation reference is independently controllable whereby to adjust the rendering position of the associated sound sources in the audio field. The offset of each audio-field reference is controlled in response to user input and/or to achieve a particular stabilisation of the associated sound source; this stabilisation may be different for different ones of the audio-field references. One audio-field reference can be dedicated to an audio-cursor sound source. Another audio-field reference can be dedicated to world-stabilised sound sources through which compass direction can be announced.

Abstract: An audio user interface is provided in which items are represented in an audio field by corresponding synthesized sound sources from where sounds related to the items appear to emanate. To facilitate user navigation in the audio field, sound sources are arranged to indicate their location in the audio field relative to a preset reference (such as the user's current facing direction or straight-ahead facing direction) by a corresponding audio indication such as an approximate relative bearing—for example “upper left”. The audio indication given by a sound source is arranged to change dynamically as the sound source and/or the present reference changes position.

Abstract: This relates to flextensional microphones which are made up of a piezoelectric substrate having opposing surfaces, typically parallel surfaces when the substrate is crystalline or ceramic, and at least one sound receiving surface physically tied to the piezoelectric substrate. The microphones are at least partially isolated via a biocompatible material, e.g., by a covering or a coating. The inventive microphones may be subcutaneously implanted. The microphones may be used as components of surgically implanted hearing aid systems or as components of hearing devices known as cochlear implants. Preferably the microphones are used in arrays and when used as a component of a hearing assistance or replacement device, are used in conjunction with a source of feedback information, usually another microphone. The feedback information usually relates to sound re-emitted from physical portions of the ear, e.g.

Abstract: A communication device comprising a microphone, a conduction interface and an electromechanical force transducer mounted to the conduction interface to drive the interface to conduct sound to a user by bone conduction, characterised in that the transducer has an intended operative frequency range and comprises a resonant element having a frequency distribution of modes in the operative frequency range and coupling means for mounting the transducer to the interface.

Abstract: A double-functioned hand-free device for cellular telephone comprises a microphone casing having one end connected with a neck hanger, wherein a direct sound-receiver circuit and a circuit for sensing vibration of vocal cords are housed in the microphone casing; and a slew cover on the microphone casing is provided for control and switch the circuits alternatively to meet on-the-spot requirements.

Abstract: A bone conduction speaker, in which a sound is sufficiently improved in tone quality by suppressing an unnecessary vibration of a vibration system and preventing generation of an abnormal sound due to an abnormal resonance, comprises: a bone conduction speaker unit constructed of a yoke, a voice coil, a magnet, a vibrating plate and a vibration block integrated with the vibrating plate; and, a housing which contains the bone conduction speaker unit to function as a vibrating portion; wherein; the vibration block of the bone conduction speaker unit is fixedly mounted on an upper surface of the interior of the housing; and, the yoke is supported by the damping member which is disposed inside the housing.

Abstract: A communication device includes an earpiece housing adapted for fitting to an car of a user such that the earpiece does not block the canal, an inertial sensor operatively connected to the earpiece housing for sensing positional changes of the user's ears, a processor operatively connected to the inertial sensor and disposed within the earpiece determining presence of an alert condition at least partially based on positional changes, and a speaker operatively connected to the processor.

Abstract: A voice communication device such as an earpiece that provides for ultra short range transmission of voice sound information using ultra wide band (UWB) radio communications is disclosed. According to one embodiment of the present invention, a voice communication device includes a speaker, a bone conduction sensor for sensing voice sound vibrations, and an UWB transceiver operatively connected to the speaker and the bone conduction sensor. According to another embodiment of the present invention, a voice communication device is disclosed that includes an earpiece housing, a speaker operatively connected to the earpiece housing for transducing audio, an air conduction sensor operatively connected to the housing for sensing voice sound information, a processor electrically connected to the speaker and the bone conduction sensor and disposed within the earpiece housing, and an UWB transceiver operatively connected to the processor.

Abstract: A support for input and output transducers of a hearing aid is implanted in the middle ear. The support, which is attached to the mastoid bone, can be a single component or comprise two adjustable components. In one embodiment, an arm extends from the proximal end of the support towards an access hole created behind the outer ear, where the arm is attached for further stability. In another embodiment, the arm extends outside the access hole, where it is mounted subcutaneously to the mastoid bone with a mechanical fastener. The support provides positional adjustability, stability, and is invisible externally.

Abstract: A bone conduction microphone and speaker mountable in contact with a user's head or head area, each utilize a strategically mounted audio transducer that is preferably a piezoelectric ceramic bender. In the case of the speaker, the bender is coupled to an audio transformer which may or may not be potted with the bender within the same housing. Additionally, the speaker bender is mounted on a foam layer either with or without a supporting shelf depending on the desired application. The microphone bender is potted within the housing and includes a JFET and resistor mounted directly to the elements of the bender. The present microphone is designed to create the largest possible acoustic mismatch with air while nearly matching the acoustic impedance to the human skill structure. This attenuates the amount of ambient air noise coupled sound receivable into the microphone by greater than 80 dB. The speaker is designed with acoustic impedance matched for bone conduction sound.

Abstract: A bone conduction hearing aid includes a vibrator carried by the insertion end of the hearing aid. When the hearing aid is inserted into the ear canal of a patient, the vibrator is positioned in the ear canal adjacent the mastoid bone. A microphone receives sound waves and outputs a microphone signal to the hearing aid electronics where the microphone signal is amplified and then sent to the vibrator, causing the vibrator to vibrate. Vibrations produced by the vibrator are transferred to the opposite cochlea by way of the mastoid bone, enabling enhanced hearing perception in patients with hearing loss in one ear. Transfer of vibrations to the bones of the middle ear also assists patients with conductive pathology in one ear. The hearing aid may also function to enhance communication in high noise environments. Feedback from the vibrator to the microphone is eliminated electronically. Various alternate forms of feedback elimination are also contemplated by the invention.

Abstract: A voice sound transmitting unit having an earpiece that is adapted for insertion into the external auditory canal of a user, the earpiece having both a bone conduction sensor and an air conduction sensor. The bone conduction sensor is adapted to contact a portion of the external auditory canal to convert bone vibrations of voice sound information into electrical signals. The air conduction sensor resides within the auditory canal and converts air vibrations of the voice sound information into electrical signals. In its preferred form, a speech processor samples output from the bone conduction sensor and the air conduction sensor to filter noise and select the a pure voice sound signal for transmission. The transmission of the voice sound signal may be through a wireless linkage and may also be equipped with a speaker and receiver to enable two-way communication.

Abstract: The scope of the present invention is an earphone unit (11) to be mounted either on external ear (18) or in auditory tube (10), in which unit both a speech registering microphone (13) and a speech reproducing ear capsule (12) have been placed. The earphone unit (11) is suitable for use in connection with various terminal devices, in particular with mobile stations. When a user's speech is registered, the ear capsule signal (12′) containing disturbances is canceled utilizing methods based upon determining the transfer function between the ear capsule (12) and the microphone (13). A separate error microphone (14) is used for eliminating external sources of disturbances (17), such as noise. In order to improve the quality of speech and prevent problems caused by double-talk, signals (15′, 12′, 17′) are processed digitally utilizing e.g. band limitation and prediction of missing bands.

Abstract: A fixation element for an implantable microphone is disclosed. In a preferred embodiment the fixation element comprises an essentially cylindrical portion adapted to be inserted into a bore which crosses a wall of the auditory canal of a user, said cylindrical portion, at least in an implanted state of the fixation element, surrounding an outer circumferential portion of a housing part of the microphone, which housing part is provided with a sound receiving member. The cylindrical portion includes at least one elastic region of increased diameter, said elastic region contacting, in the implanted state of the fixation element, a wall of said bore and providing, by elastic restoring forces, for a friction which is sufficiently high to fix said cylindrical portion in at least one of the two axial directions of said bore.

Abstract: A voice sound transmitting unit having an earpiece that is adapted for insertion into the external auditory canal of a user, the earpiece having both a bone conduction sensor and an air conduction sensor. The bone conduction sensor is adapted to contact a portion of the external auditory canal to convert bone vibrations of voice sound information into electrical signals. The air conduction sensor resides within the auditory canal and converts air vibrations of the voice sound information into electrical signals. In its preferred form, a speech processor samples output from the bone conduction sensor and the air conduction sensor to filter noise and select the a pure voice sound signal for transmission. The transmission of the voice sound signal may be through a wireless linkage and may also be equipped with a speaker and receiver to enable two-way communication.

Abstract: An improved implantable hearing aid microphone comprises a housing having an internal chamber with an aperture thereto and a first diaphragm sealably positioned across the aperture. A microphone having a second diaphragm is positioned within the chamber to define an enclosed volume between the first and second diaphragms for mechanically amplifying acoustic signals received by the first diaphragm. A peripheral rim may define the aperture of the housing, wherein the first diaphragm may be recessed between about 0.5 mm and 1.0 mm relative to the peripheral rim across the lateral extent of the first diaphragm. The internal chamber may be defined to include a first portion having a first cross-sectional area adjacent to the first diaphragm, and a second portion having a second cross-sectional area adjacent to the second diaphragm that is smaller than the first cross-sectional area. The second portion may be disposed to extend away from the first portion about an axis that is transverse to the first diaphragm.

Abstract: A ceramic piezoelectric type microphone includes a lower cover and an upper cover, and a receiving space confined by the lower and upper covers when they are connected. A signal wire is led in the receiving space via an extension portion of the lower cover and passes through a substrate to connect to an electrical circuit board. The other side of the circuit board is connected to a piezoelectric ceramic plate. A high-density foam body is sandwiched between the piezoelectric ceramic plate and a securing portion on an inner side of the upper cover. When a ratio value of a diameter of the surface of the upper cover to a contact thickness formed by the upper cover is greater than 0.15, sound waves generated as a result of contact between cover surfaces and the user's throat skill pass through the foam body to the piezoelectric ceramic plate to be directly converted into a signal output, thereby eliminating most of the background noise except the sound of the user's voice.

Abstract: A implantable sealed microphone (50) includes a diaphragm (52) having a thin central region (54) surrounded by a thicker rim (56). One side of sheet electret material (72) is bonded to the diaphragm (52) while the other side contacts a roughened plate (82). The rim (56) is bonded to a housing (112) thereby hermetically enclosing the electret (72) and the plate (82). The microphone (50) also includes an electrical connector (94) that couples both the plate (82) and the electret (72) to an input of an amplifier (30) included in an implantable hearing aid system (10). Preferably, the microphone (50) is incorporated into a sealed electronics module (100) together with the amplifier (30) and an energy storage device such as a battery that energizes operation of the implantable hearing aid system (10). In such a configuration, the microphone's diaphragm (52) forms a surface of the electronics module's housing (112).

Abstract: A middle ear hearing aid transducer is provided.

Abstract: A yoke 1 having a center magnetic pole 2 around which a voice coil is wound is provided, the yoke 1 is extended in four directions, magnets 4 are disposed on two parts 7 and 7 facing to each other among the extensions, respectively, and diaphragm fixing sections 6 are erected on the other two parts 8 and 8 and a diaphragm is fixed on the diaphragm fixing section 6.

Abstract: Audio apparatus comprises a base unit including circuitry for generating electrical signals representing sounds and at least one earphone adapted to receive the electrical signals and to reproduce sounds represented by the signals, in which the apparatus is provided externally with a terminal arranged so that it can be positioned in use in contact with or in close proximity to the surface of the user's body. The circuitry is arranged to supply to the terminal signals which are transmitted through the user's body, the or each earphone is provided with a terminal arranged so that it can be positioned in use in contact with or in close proximity to the surface of the user's body so as to receive signals transmitted from the terminal through the user's body, and the or each earphone includes receiving circuitry arranged to receive the signals. The earphones may be embodied in a pair of spectacles, and may be adjustable between a first position behind the ear and a second position in or more adjacent the ear.

Abstract: A device for transmitting sound waves between a signal source and a user's ears, wherein the sound waves bypass the air. The invention generally comprises a signal source configured to produce signals representative of sound, and a sound-transmitting element operatively associated with the signal source to which the signal source can transmit such signals for transmission through the sound-transmitting element to a user's mouth, from which the signals are conducted by teeth and bones to the user's ears to be perceived as sound. The signal source generally comprises an source that may produce sound waves directly or indirectly with the assistance of a transducer. The sound-transmitting element generally comprises any element that may transmit signals representative of sound upon contact with a user's mouth and may include edible substances, eating utensils, and writing implements, among others.

Abstract: A voice sound transmitting unit having an earpiece that is adapted for insertion into the external auditory canal of a user, the earpiece having both a bone conduction sensor and an air conduction sensor. The bone conduction sensor is adapted to contact a portion of the external auditory canal to convert bone vibrations of voice sound information into electrical signals. The air conduction sensor resides within the auditory canal and converts air vibrations of the voice sound information into electrical signals. In its preferred form, a speech processor samples output from the bone conduction sensor and the air conduction sensor to filter noise and select the a pure voice sound signal for transmission. The transmission of the voice sound signal may be through a wireless linkage and may also be equipped with a speaker and receiver to enable two-way communication.

Abstract: In a hearing system, a transmitting coil is positioned on the promontory centered medial to the umbo of the tympanic membrane while securing the magnet to a surface of said tympanic membrane or to the manubrium of the malleus. The system does not require the permanent placement of components in the auditory canal which would otherwise interfere with normal hearing when the system is not in use.

Abstract: A disposable audio processor for use with implanted hearing devices is provided. The audio processor may include a microphone, application specific integrated circuit performing both signal processing and signal modulation, a battery, and a coil. The audio processor is designed for specific types of hearing loss. Electronic signals are transmitted to an implanted receiver through the use of electromagnetic fields generated by the coil of the audio processor. The audio processor is a low power and inexpensive device that may be disposed of when it becomes inoperable. The audio processor and may include a finger tab for manipulating the device.

Abstract: Two stage implantable microphone devices suitable for use in hearing systems are provided. An implantable microphone device may include a housing including a diaphragm with the housing and diaphragm enclosing a chamber; a microphone coupled to the housing; and a vent connecting the microphone to the chamber. Vibrations of the diaphragm are transmitted through the chamber as a first stage and through the vent as a second stage to the microphone. The relative dimensions of the chamber and vent may be utilized to tune the frequency response and sensitivity of the device.