A portable device including a secondary battery, a plurality of driving components driven by charged power of the secondary battery, a charging unit configured to charge the secondary battery by an input of outside power supplied from outside of the portable device, a plurality of transformation units each configured to output the charged power of the secondary battery at a driving voltage of a corresponding one of the plurality of driving components, a detection unit configured to detect the input of the outside power to the charging unit, and a switching controller configured to switch a state of one of the plurality of transformation units from an operation state to a stopped state responsive to detecting the input of the outside power to the charging unit causing only the corresponding one of the plurality of driving components to stop operation during charging of the secondary battery.
H02J 7/00 - Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries
H02J 7/04 - Regulation of the charging current or voltage
H02J 50/12 - Circuit arrangements or systems for wireless supply or distribution of electric power using inductive coupling of the resonant type
H02J 50/80 - Circuit arrangements or systems for wireless supply or distribution of electric power involving the exchange of data, concerning supply or distribution of electric power, between transmitting devices and receiving devices
H02J 50/90 - Circuit arrangements or systems for wireless supply or distribution of electric power involving detection or optimisation of position, e.g. alignment
2.
Subscription-based wireless service for a hearing device
Examples of subscription-based wireless hearing device systems and methods are described. An exemplary system includes a wireless hearing device and a personal computing device to enable or disable a wireless service of the wireless hearing device in accordance of a subscription. The subscription may be verified using subscription data or validation data received from a remote server.
H04M 1/72415 - User interfaces specially adapted for cordless or mobile telephones with means for local support of applications that increase the functionality by interfacing with external accessories for remote control of appliances
H04W 4/80 - Services using short range communication, e.g. near-field communication [NFC], radio-frequency identification [RFID] or low energy communication
H04M 1/60 - Substation equipment, e.g. for use by subscribers including speech amplifiers
An in-ear receiver can be used in a headset and/or hearing aid and includes a housing in which at least one ear canal section is configured to be inserted into an ear canal of a wearer when the in-ear receiver is used as intended. The housing defines at least one outer contour that is configured with at least in one section adapted to the ear canal of the wearer. The in-ear receiver includes a sound transducer arranged in the housing, and at least one resonant cavity, which is formed in the housing and is divided by the sound transducer into a front volume and a rear volume. The sound transducer is a MEMS sound transducer, and the front volume and/or the rear volume have/has an inner contour adapted to the ear canal.
H04R 1/28 - Transducer mountings or enclosures designed for specific frequency responseTransducer enclosures modified by provision of mechanical or acoustic impedances, e.g. resonator, damping means
H04R 11/14 - Resonant transducers, i.e. adapted to produce maximum output at a predetermined frequency
4.
Wireless hearing device with physiologic sensors for health monitoring
The present disclosure describes examples of systems and methods of wireless remote control of appliances and medical devices using a canal hearing device upon manual activation of a switch placed in the concha cavity behind the tragus. The manual activation of the switch may be by applying a force to the tragus by a finger of a user of the canal hearing device. In one embodiment the lateral end comprises one or more manually activated switches, a wireless antenna, and a battery cell. In some examples, the wireless electronics include low energy Bluetooth. The appliance may be any device with wireless capabilities, for example an electronic lock, a thermostat, an electronic lighting, a telephone, a kitchen appliance, a medical alert system, a television, a medical device, and a smart glass. The inconspicuous and secure wear of the hearing device allows for active lifestyle, including exercise, and more discrete communications.
The present disclosure describes examples of systems and methods of wireless remote control of appliances and medical devices using a canal hearing device upon manual activation of a switch placed in the concha cavity behind the tragus. The manual activation of the switch may be by applying a force to the tragus by a finger of a user of the canal hearing device. In one embodiment the lateral end comprises one or more manually activated switches, a wireless antenna, and a battery cell. In some examples, the wireless electronics include low energy Bluetooth. The appliance may be any device with wireless capabilities, for example an electronic lock, a thermostat, an electronic lighting, a telephone, a kitchen appliance, a medical alert system, a television, a medical device, and a smart glass. The inconspicuous and secure wear of the hearing device allows for active lifestyle, including exercise, and more discrete communications.
The present disclosure describes examples of systems and methods of wireless remote control of appliances and medical devices using a canal hearing device upon manual activation of a switch placed in the concha cavity behind the tragus. The manual activation of the switch may be by applying a force to the tragus by a finger of a user of the canal hearing device. In one embodiment the lateral end comprises one or more manually activated switches, a wireless antenna, and a battery cell. In some examples, the wireless electronics include low energy Bluetooth. The appliance may be any device with wireless capabilities, for example an electronic lock, a thermostat, an electronic lighting, a telephone, a kitchen appliance, a medical alert system, a television, a medical device, and a smart glass. The inconspicuous and secure wear of the hearing device allows for active lifestyle, including exercise, and more discrete communications.
Disclosed herein are examples of methods and systems for performing a calibration check of a personal hearing test system using a built-in calibration cavity, particularly for use by a non-expert user outside the clinical environment. The hearing test system includes a one or more earpieces. The hearing test system further includes a portable test unit having an acoustic calibration cavity for accommodating the earpiece at least partially therein. The acoustic calibration cavity may include an opening along an exterior surface of the portable test unit. The acoustic calibration cavity receives an acoustic calibration stimuli and the microphone provided within the acoustic calibration cavity produces a calibration signal input for measuring and performing a calibration check, or an automatic self-calibration.
A portable device including a secondary battery, a plurality of driving components driven by charged power of the secondary battery, a charging unit configured to charge the secondary battery by an input of outside power supplied from outside of the portable device, a plurality of transformation units each configured to output the charged power of the secondary battery at a driving voltage of a corresponding one of the plurality of driving components, a detection unit configured to detect the input of the outside power to the charging unit, and a switching controller configured to switch a state of one of the plurality of transformation units from an operation state to a stopped state responsive to detecting the input of the outside power to the charging unit causing only the corresponding one of the plurality of driving components to stop operation during charging of the secondary battery.
H02J 50/12 - Circuit arrangements or systems for wireless supply or distribution of electric power using inductive coupling of the resonant type
H02J 50/80 - Circuit arrangements or systems for wireless supply or distribution of electric power involving the exchange of data, concerning supply or distribution of electric power, between transmitting devices and receiving devices
H02J 50/90 - Circuit arrangements or systems for wireless supply or distribution of electric power involving detection or optimisation of position, e.g. alignment
H02J 7/00 - Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries
H02J 7/04 - Regulation of the charging current or voltage
H02J 7/02 - Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries for charging batteries from AC mains by converters
9.
Hearing device and methods for interactive wireless control of an external appliance
The present disclosure describes examples of systems and methods of wireless remote control of appliances using a hearing device, for example upon manual activation of a switch placed in the concha cavity behind the tragus. In some examples, the hearing device includes one or more manually activated switches, a wireless antenna, and a battery cell. In some examples, the wireless electronics include low energy Bluetooth capability. The appliance may be any device with wireless control capability, for example an electronic lock, a thermostat, an electronic lighting, a telephone, a kitchen appliance, a medical alert system, a television, a medical device, and a smart glass.
Various systems and methods are disclosed herein to increase the quality of the sound and intelligibility of speech delivered to a user by combining electric audio signals from more than one hearing assistance device that incorporates an active signal enhancement system. The method includes receiving electric audio signals at a first hearing assistance device, and sending electric audio signals to a second hearing assistance device. The electric audio signal is encoded as a replacement for input to an microphone channel located at the second hearing assistance device. The electric audio signals from the microphone located at the first hearing assistance device and the microphone located at the second hearing assistance device are combined.
G10K 11/175 - Methods or devices for protecting against, or for damping, noise or other acoustic waves in general using interference effectsMasking sound
The present disclosure describes examples of systems and methods of wireless remote control of appliances and medical devices using a canal hearing device upon manual activation of a switch placed in the concha cavity behind the tragus. The manual activation of the switch may be by applying a force to the tragus by a finger of a user of the canal hearing device. In one embodiment the lateral end comprises one or more manually activated switches, a wireless antenna, and a battery cell. In some examples, the wireless electronics include low energy Bluetooth. The appliance may be any device with wireless capabilities, for example an electronic lock, a thermostat, an electronic lighting, a telephone, a kitchen appliance, a medical alert system, a television, a medical device, and a smart glass. The inconspicuous and secure wear of the hearing device allows for active lifestyle, including exercise, and more discrete communications.
Various systems and methods are disclosed herein to increase the quality of the sound delivered to a user and allow personalization to optimize listening performance and comfort under atypical listening conditions, environment specific adjustment, and data capture to assist in the personalization of the system to the user's needs and preferences. Features disclosed include sound level rating systems that aggregate noise data detected by user's mobile phones or hearing devices to provide a database of real-time noise levels. Additionally, a user's sound settings may be saved in the system by location so that they may be recalled when re-entering a specific location. A remote clinician may tune a hearing device, or a user can tune the device using a pre-recorded audio sample. Also, a user may replay the last X seconds of audio recorded by their hearing device.
Various systems and methods are disclosed herein to increase the quality of the sound delivered to a user and allow personalization to optimize listening performance and comfort under atypical listening conditions, environment specific adjustment, and data capture to assist in the personalization of the system to the user's needs and preferences. Features disclosed include sound level rating systems that aggregate noise data detected by user's mobile phones or hearing devices to provide a database of real-time noise levels. Additionally, a user's sound settings may be saved in the system by location so that they may be recalled when re-entering a specific location. A remote clinician may tune a hearing device, or a user can tune the device using a pre-recorded audio sample. Also, a user may replay the last X seconds of audio recorded by their hearing device.
Various systems and methods are disclosed herein to increase the quality of the sound delivered to a user and allow personalization to optimize listening performance and comfort under atypical listening conditions, environment specific adjustment, and data capture to assist in the personalization of the system to the user's needs and preferences. Features disclosed include sound level rating systems that aggregate noise data detected by user's mobile phones or hearing devices to provide a database of real-time noise levels. Additionally, a user's sound settings may be saved in the system by location so that they may be recalled when re-entering a specific location. A remote clinician may tune a hearing device, or a user can tune the device using a pre-recorded audio sample. Also, a user may replay the last X seconds of audio recorded by their hearing device.
Various systems and methods are disclosed herein to increase the quality of the sound delivered to a user and allow personalization to optimize listening performance and comfort under atypical listening conditions, environment specific adjustment, and data capture to assist in the personalization of the system to the user's needs and preferences. Features disclosed include sound level rating systems that aggregate noise data detected by user's mobile phones or hearing devices to provide a database of real-time noise levels. Additionally, a user's sound settings may be saved in the system by location so that they may be recalled when re-entering a specific location. A remote clinician may tune a hearing device, or a user can tune the device using a pre-recorded audio sample. Also, a user may replay the last X seconds of audio recorded by their hearing device.
Various systems and methods are disclosed herein to increase the quality of the sound delivered to a user and allow personalization to optimize listening performance and comfort under atypical listening conditions, environment specific adjustment, and data capture to assist in the personalization of the system to the user's needs and preferences. Features disclosed include sound level rating systems that aggregate noise data detected by user's mobile phones or hearing devices to provide a database of real-time noise levels. Additionally, a user's sound settings may be saved in the system by location so that they may be recalled when re-entering a specific location. A remote clinician may tune a hearing device, or a user can tune the device using a pre-recorded audio sample. Also, a user may replay the last X seconds of audio recorded by their hearing device.
Disclosed herein are systems and methods enabling self-fitting by a non-expert consumer. The method in some examples involves transmitting a wireless command by a computing device to a hearing device in-situ to produce a sequence of test audio signals corresponding to natural sound segments, while allowing the consumer to adjust fitting parameters based on perceptual assessment of hearing device output. The sound segments may represent a practical range of sounds within the normal human auditory range, with each sound segment selected to correspond to one or more fitting parameters of the programmable hearing device. The consumer is instructed to listen to the output of the in-situ hearing device and adjust controls on the personal computer's graphical user interface related to corresponding fitting parameters. The systems and methods disclosed herein allow dispensing or adjusting of hearing devices without requiring specialized instruments or clinical settings.
Disclosed herein are systems and methods enabling hearing aid fitting by a non-expert consumer at home. The method in one embodiment involves delivering a sequence of test audio signals corresponding to natural sound segments to a non-acoustic input of a programmable hearing device in-situ, while allowing the consumer to adjust fitting parameters based perceptual assessment of hearing device output. The sound segments define a fitting soundscape representing a practical range of sounds within the normal human auditory range, with each sound segment corresponding to one or more fitting parameters of the programmable hearing device. The consumer is instructed to listen to the output of the in-situ hearing device and adjust controls related to corresponding fitting parameters. In one embodiment, the fitting system comprises a personal computer and a handheld device providing calibrated test audio signals and a programming interface. The systems and methods disclosed herein allow home dispensing of hearing devices without requiring specialized instruments or clinical settings.
Disclosed herein are examples of methods and systems for performing remote verification of a hearing device, particularly for use by a non-expert user outside the clinical environment. A status and/or functionality of the hearing device may be verified using verification criteria. Upon verifying the status and/or the functionality of the hearing device, a user may be permitted to conduct an e-commerce transaction. The status of the hearing device may include identification information associated with the hearing device and/or the user. The functionality of the hearing device may include a calibration and/or a system performance.
G06Q 20/10 - Payment architectures specially adapted for electronic funds transfer [EFT] systemsPayment architectures specially adapted for home banking systems
G06Q 20/40 - Authorisation, e.g. identification of payer or payee, verification of customer or shop credentialsReview and approval of payers, e.g. check of credit lines or negative lists
H04L 29/06 - Communication control; Communication processing characterised by a protocol
In one embodiment, a system includes a programmable hearing device configured to deliver a sequence of outputs in-situ, each output corresponding to a sound segment, wherein the outputs are delivered according to fitting parameters programmed into the programmable hearing device, and a computing device communicatively coupled online to a remote server. The computing device may be configured to receive a consumer input indicative of a subjective assessment of the consumer of each of the sound segments, wherein the consumer input is configured to adjust one or more fitting parameters associated with the output corresponding to the sound segment being assessed, wherein the fitting application is configured to make adjustments to the fitting parameters in accordance with the consumer input.
Frequent replacement of a battery is avoided even if power consumption is large, and the structure is simplified and waterproofness is improved. Furthermore, cost reduction is achieved because driving components are selectable from components with variously different operating voltages. A hearing aid includes a secondary battery having a nominal voltage higher than a nominal voltage of an air battery, driving components driven by power at different voltages supplied from the secondary battery, and a transformation unit configured to output the charging power of the secondary battery at a voltage suitable for driving each driving component.
H02J 7/02 - Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries for charging batteries from AC mains by converters
H02J 50/10 - Circuit arrangements or systems for wireless supply or distribution of electric power using inductive coupling
H02J 7/00 - Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries
22.
Hearing device test system for non-expert user at home and non-clinical settings
A hearing device test system for use by a non-expert user may include a hearing device comprising a sound processor and a speaker and a portable test unit including a test microphone acoustically coupled to an exterior of the portable test unit via an acoustic calibration cavity. The portable test unit may include a coupler at an opening to the acoustic calibration cavity configured to receive the hearing device at least partially therein and the test microphone may be configured to produce a calibration signal input responsive to acoustic calibration stimuli provided by the speaker of the hearing device. The hearing device test system may also include a processor associated therewith and configured to measure a level of the calibration signal input.
Examples of systems and methods for rapidly grading the hearing of a user in accordance with WHO guidelines are disclosed. One example includes a personal computer and a test device configured to produce calibrated acoustic output at suprathreshold levels presented at an audiometric frequency range from 500 to 4000 Hz. The consumer's minimal response levels are registered, and a hearing ability score is presented to indicate a hearing grade and hearing aid candidacy. The hearing ability score may be representative of a classification of the WHO grading of hearing impairment. Systems and methods disclosed herein, with considerations for room noise present in the consumer's environment, allow for rapid hearing profiling, using a standard personal computer and minimal low-cost hardware, thus particularly suited for self-testing outside clinical environments such as at home, office, or retail store settings.
Examples of a subscription-based rechargeable hearing device system and methods are described. An exemplary system includes a hearing device and a charging device to charge the hearing device according to a subscription status. In some examples, a charging station automatically disengages the rechargeable battery cell upon insertion of the hearing device partially into a receptacle cavity of the charging station. The subscription may be verified using a remote server in communication with a subscription database.
Examples of canal hearing devices including a lateral section having a frequency shaping sound port system are disclosed. A lateral section includes an elongate sound channel for receiving an incoming sound and producing a frequency-shaped sound output. The hearing device includes a microphone, a speaker for transmitting sound to the eardrum, and a sound port to receive the frequency-shaped sound output from the elongate sound channel and provide a pathway for the frequency-shaped sound output to reach the microphone.
Examples of retaining seal assemblies for acoustically sealing and retaining a canal hearing device or an earpiece within the ear canal are disclosed. The retaining seal assembly may include one or more flanges and a clip element. The flanges may include elongate trenches along an exterior surface of one or more of the flanges. The elongate trenches may allow the flange to conform to the shape of the ear canal and distribute concentric compressive forces when the seal assembly is inserted in the ear canal. The clip element may be formed of a relatively rigid material and may include one or more locking tabs. The conforming flanges may be concentrically positioned over the clip element. The seal assembly may include a debris barrier to provide protection for a sound outlet of the canal hearing device or the earpiece.
The present disclosure describes examples of systems and methods of wireless remote control of appliances and medical devices using a canal hearing device upon manual activation of a switch placed in the concha cavity behind the tragus. The manual activation of the switch may be by applying a force to the tragus by a finger of a user of the canal hearing device. In one embodiment the lateral end comprises one or more manually activated switches, a wireless antenna, and a battery cell. In some examples, the wireless electronics include low energy Bluetooth. The appliance may be any device with wireless capabilities, for example an electronic lock, a thermostat, an electronic lighting, a telephone, a kitchen appliance, a medical alert system, a television, a medical device, and a smart glass. The inconspicuous and secure wear of the hearing device allows for active lifestyle, including exercise, and more discrete communications.
The present disclosure describes examples of systems and methods of wireless remote control of appliances using a canal hearing device upon manual activation of a switch placed in the concha cavity behind the tragus. In some examples, the lateral end comprises one or more manually activated switches, a wireless antenna, and a battery cell. In some examples, the wireless electronics include low energy Bluetooth capability. The appliance may be any device with wireless control capability, for example an electronic lock, a thermostat, an electronic lighting, a telephone, a kitchen appliance, a medical alert system, a television, a medical device, and a smart glass. The inconspicuous and secure wear of the canal hearing device may allow a hearing device user to enjoy a normal lifestyle, including exercise, and to discretely interact with wirelessly controlled devices.
A portable device is arranged to include a secondary battery, a driving component driven by charged power of the secondary battery, a charging unit configured to charge the secondary battery by outside power, a transformation unit (processing unit) configured to output the charged power of the secondary battery at a driving voltage of the driving component, a detection unit configured to detect the input of the outside power to the charging unit, and a switching controller configured to switch the state of the transformation unit from an operation state to a stopped state only when the input of the outside power to the charging unit is detected by the detection unit.
H02J 50/12 - Circuit arrangements or systems for wireless supply or distribution of electric power using inductive coupling of the resonant type
H02J 50/80 - Circuit arrangements or systems for wireless supply or distribution of electric power involving the exchange of data, concerning supply or distribution of electric power, between transmitting devices and receiving devices
H02J 50/90 - Circuit arrangements or systems for wireless supply or distribution of electric power involving detection or optimisation of position, e.g. alignment
H02J 17/00 - Systems for supplying or distributing electric power by electromagnetic waves
H02J 7/00 - Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries
H02J 7/04 - Regulation of the charging current or voltage
H02J 7/02 - Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries for charging batteries from AC mains by converters
Disclosed herein are systems and methods enabling hearing aid fitting by a non-expert consumer at home. The method in one embodiment involves delivering a sequence of test audio signals corresponding to natural sound segments to a non-acoustic input of a programmable hearing device in-situ, while allowing the consumer to adjust fitting parameters based perceptual assessment of hearing device output. The sound segments define a fitting soundscape representing a practical range of sounds within the normal human auditory range, with each sound segment corresponding to one or more fitting parameters of the programmable hearing device. The consumer is instructed to listen to the output of the in-situ hearing device and adjust controls related to corresponding fitting parameters. In one embodiment, the fitting system comprises a personal computer and a handheld device providing calibrated test audio signals and a programming interface. The systems and methods disclosed herein allow home dispensing of hearing devices without requiring specialized instruments or clinical settings.
Methods and systems of interactive online fitting of a hearing aid by a non-expert consumer without requiring a clinical setup are disclosed. In one embodiment, the system includes an audio generator for delivering test audio signals at predetermined levels to a non-acoustic input of a programmable hearing aid in-situ, and a programming interface for delivering programming signals to the hearing aid. The consumer is instructed to listen to the output of the hearing device in-situ and to interactively adjust fitting parameters according to a subjective assessment of audible output representative of the test audio signal. In one embodiment, the online-based fitting system comprises a personal computer, a handheld device connected to the personal computer, and a fitting application hosted by a server. In one embodiment, remote customer support personnel may communicate with a hearing aid worn by the consumer and interactively control fitting parameters.
Methods and systems of interactive fitting of a hearing aid by a non-expert person without resorting to a clinical setup are disclosed. The system includes an audio generator for delivering test audio signals at predetermined levels to a non-acoustic input of a programmable hearing aid in-situ. The consumer is instructed to listen to the output of the hearing device in-situ and interactively adjust fitting parameters of the programmable hearing aid according to the perceptual assessment of the hearing aid output in-situ. The output is representative of the test audio signal presented to the non-acoustic input. In one embodiment, the fitting system includes a personal computer, a handheld device communicatively coupled to the personal computer, and a fitting software application. In one embodiment, the fitting system includes an earphone for conducting a hearing evaluation.
Disclosed herein are systems and methods enabling hearing aid fitting by a non-expert consumer. The method in one embodiment involves delivering a sequence of test audio signals corresponding to natural sound segments to a non-acoustic input of a programmable hearing device in-situ, while allowing the consumer to adjust fitting parameters based perceptual assessment of hearing device output. The sound segments define a fitting soundscape within the normal human auditory range, with each sound segment corresponding to one or more fitting parameters of the programmable hearing device. The consumer is instructed to listen to the output of the in-situ hearing device and adjust controls related to corresponding fitting parameters. In one embodiment, the fitting system comprises a personal computer and a handheld device providing calibrated test audio signals and programming interface. The systems and methods allow home dispensing of hearing devices without requiring specialized instruments.
Examples of systems and methods for profiling the hearing ability of a consumer are disclosed. One example includes a personal computer and a handheld device configured to produce calibrated acoustic output at suprathreshold levels above 20 db HL, and at step levels of 10-20 decibels, and presented test frequency bands across an audiometric frequency range from 400 to 8000Hz. The consumer's minimal audibility levels are registered, and a hearing profile score is presented to indicate hearing ability and hearing aid candidacy. In some embodiments, band-limited natural sounds are presented. Systems and methods disclosed herein, with considerations for noise present in the consumer's environment, allow for rapid calibrated hearing profiling, using a standard personal computer and minimal hardware, thus particularly suited for self-testing outside clinical environments such as at home or the office.
Examples of modular hearing devices and tools for disengaging a battery module from a main module of the canal hearing device are described. The disengagement tool may be used to switch the modular hearing device to the power OFF condition, or to completely remove the battery module therefrom. According to examples described, the disengagement tool comprises a receptacle cavity shaped to accommodate the lateral end of the modular hearing device, the cavity including features arranged to actuate a handle of the battery module for automatically disengaging the battery module upon insertion of the canal hearing device into the receptacle cavity. Other examples describe features for holding the battery module with the main module in either the ON or OFF positions.
Examples of a rechargeable canal hearing device and charging systems are described. An exemplary rechargeable hearing device includes a battery module and a main module adapted to be removably couple together to form a modular canal hearing device assembly configured to be inserted inconspicuously in the ear canal. The modular canal hearing device assembly may include electrical contacts or an inductive charging system to couple charging energy from a charging station. According to examples described, the charging station includes a receptacle cavity shaped to partially accommodate the modular canal hearing device assembly including its handle. The receptacle cavity includes features operable to manipulate the handle as an actuator for automatically disengaging the battery module from the main module upon insertion of the lateral end into the receptacle cavity.
A listening support device, such as in particular a hearing aid, includes a part (6) worn in the ear, wherein the part worn in the ear includes an electro-acoustic converter (61) and optionally also includes a microphone (62). The part worn in the ear includes a device housing (6) which is inserted releasably in a compressible case (30) which at least partially encircles the device housing laterally. The compressible case (30) is provided with at least one continuous channel (31,32,33) which provides for an open communication between a proximal side directed toward an outlet of the auditory canal and an opposite, distal side thereof.
A hearing aid comprises a microphone on a proximal side of a device housing and a loudspeaker which via a transmission channel is in open communication with a sound-emitting opening of the device. A sound processing device serves to generate sound received by the microphone to the loudspeaker in amplified form. The device housing is provided on a distal side with an optionally sealed battery chamber for receiving a battery therein. The transmission channel is at least almost wholly separated from the microphone acoustically in order to prevent acoustic feedback. The battery chamber comprises ventilation means for the purpose of increasing the lifespan of the battery.
Examples of a removable earpiece assembly configured for coupling to a canal hearing device using a foil-thin clip are described. The earpiece assembly may be readily removed for replacement when soiled or degraded after use. The earpiece assembly may include a compliant element for contact with the ear canal in a comfortable and safe manner. The earpiece assembly may function as an acoustic seal and/or a retainer for the canal hearing device. The removable earpiece assembly may provide a highly space efficient solution which may be used with miniature canal hearing devices, including a CIC device. In some embodiments, disengagement of the earpiece assembly from the canal hearing device may be accomplished by a side peel motion.
A hand held tool for safely inserting a canal hearing device into the ear canal having a medial end configured to simultaneously cradle the lateral end of the canal hearing device and constrain a knob element laterally positioned on the canal hearing device. In a preferred embodiment, the insertion tool comprises a C-shaped cavity for self-centering engagement with a D-shaped lateral end of a CIC device, providing ease of use for hearing impaired individuals. In a preferred embodiment, the insertion tool is substantially formed of a single monolithic structure for improved durability and lower cost of fabrication.
B25B 27/00 - Hand tools or bench devices, specially adapted for fitting together or separating parts or objects whether or not involving some deformation, not otherwise provided for
A seal assembly for canal hearing devices including a dynamic pressure vent formed and defined by diaphragmatic flaps configured to open in response to a pressure gradient across the diaphragm. The seal assembly comprises a compliant seal element configured to be positioned generally concentrically around the canal hearing device for providing comfortable contact with the ear canal and for acoustically sealing the residual volume of the ear canal. The seal assembly is preferably made of an elastomeric material. The dynamic pressure vent is substantially closed in the normal position to minimize feedback, while momentarily opening inside the ear canal during insertion or removal of the canal hearing device into or from the ear canal.
An electro-acoustic micro-converter can be applied in an audio device, and in particular in a hearing aid. The micro-converter is at least substantially block-shaped and includes an at least substantially rectangular acoustic membrane tensioned therein transversely of a longitudinal direction. A coil element is carried by the membrane and extends in a magnetic field maintained by magnet elements, including a permanently magnetic magnet body, in a coil gap around the magnet body.
Examples of systems and methods of wireless control of a canal hearing device by applying a magnetic field on the skin at the temporomandibular region of the head are described. An exemplary hearing device may include one or more magnetic sensors for wireless activation by the magnetic end of a remote control device applied inconspicuously to the anterior of the external ear. The activation of a reed switch magnetic sensor within the canal hearing device may be decoded by the electronics of the hearing device to implement a control command, such as volume change, program setting change, ON, or OFF. According to examples described, wireless control of the canal hearing device may be implemented with a natural, comfortable, and inconspicuous hand-arm motion. In some embodiments, multiple reed switches may be arranged to selectively respond to a magnetic field applied within distinct “hot spot” regions, for separate remote control commands.
A removal tool for removing canal hearing devices from the ear canal, examples of which may include a hand piece and a removal loop having a wide section for placing over a knob handle structure incorporated within the canal hearing device, and a narrow section for interlocking with the knob handle to remove the hearing device from the ear. The removal loop is generally configured in the shape of keyhole to guide and transition of the knob and shaft of the knob handle into the narrow section for capture and interlocking therewithin. The removal tool may provide ease of use, particularly for individuals with poor dexterity and/or poor vision. In a preferred embodiment, the removal loop is made of a single formed wire for improved durability, lower cost of fabrication, and safe operation that minimizes contact with the walls of the ear canal.
A modular canal hearing aid assembly having a main module and a disposable battery module that docks perpendicularly into the main module which surrounds the battery module circumferentially and laterally for secure connection that eliminates inadvertent separation of the modules during removal of the hearing aid assembly from the ear canal. The disposable battery module incorporates battery cell, sound port, and handle, in a unitary structure that is easy to handle and replace as an integrated unit when any of the degradables within are consumed. The disposable battery module also comprises a membrane filter for filtering out earwax and liquids. The perpendicular docking mechanism provides highly space efficient design for comfortable and inconspicuous fit deep in the ear canal.
A personalized hearing profile is generated for an ear-level device comprising a memory, microphone, speaker and processor. Communication is established between the ear-level device and a companion device, having a user interface. A frame of reference in the user interface is provided, where positions in the frame of reference are associated with sound profile data. A position on the frame of reference is determined in response to user interaction with the user interface, and certain sound profile data associated with the position. Certain data is transmitted to the ear level device. Sound can be generated through the speaker based upon the audio stream data to provide real-time feedback to the user. The determining and transmitting steps are repeated until detection of an end event.
A modular canal hearing device having a speaker module placed in the bony region for extended wear while a main module is removably inserted in the cartilaginous region. The main module wirelessly activates the speaker module when placed in proximity thereto. The main module is removed daily or as needed for maintenance of the hearing device such as for battery replacement. The speaker module remains undisturbed in the bony region to avoid skin friction. The main module contains the microphone, electronics, battery and in the preferred embodiment an inductive coupling coil for inductively sending audio signals to the receiver module. The modular design allows for a highly miniaturized design that is easier to navigate in the ear canal for improved fit and sound fidelity at the eardrum while allowing easy maintenance of a removable module.
A hearing aid includes a device housing (2) in which a programmable sound processing device is received on a carrier. The carrier is provided on a main surface with a conductor track which lies exposed in an opening (8) in an outer casing of the device housing (2). A coupling connector (20) of an external programming device can be received in the opening in order to place the conductor track on the main surface of the carrier into direct and operative contact with a corresponding conductor track on the coupling connector. A separate connector for the purpose of programming and tuning the sound processing device to the individual hearing characteristics and/or wishes of a user can thus be omitted from the hearing aid.
A hearing aid includes a microphone on a proximal side of a device housing and a loudspeaker which via a transmission channel is in open communication with a sound-emitting opening of the device. A sound processing device serves to generate sound received by the microphone to the loudspeaker in amplified form. The device housing is provided on a distal side with an optionally sealed battery chamber for receiving a battery therein. The transmission channel is at least almost wholly separated from the microphone acoustically in order to prevent acoustic feedback. The battery chamber includes ventilation elements for the purpose of increasing the lifespan of the battery.
An ear-level hearing device and a handheld computer with a graphical user interface determines a subject's own hearing threshold. Hardware includes the smartphone, viewing screen of the smartphone, smartphone software, ear level hearing device, transmitter on the smartphone and receiver on the ear level device (ELD) communicating with the graphical user interface on the smartphone to the ear level hearing device. The interface on the smartphone may include an automatic routine or buttons to vary frequency and amplitude of a frequency dependent sound presentation to the earpiece. Software installed on the hand-held smartphone system sends wireless signals to the ELD changing acoustic parameters in the listening device. The ELD stores frequency/amplitude parameters of the thresholds and wirelessly delivers them to the smartphone. The smartphone uses the threshold data to derive the appropriate amplified acoustical signal (relative to the thresholds) to the subject.
An audible location alarm is generated from an ear-level device of a type comprising a memory, a microphone and a speaker, each coupled to a processor. Communication is established between the ear-level device and a companion device, the companion device having an interface, a display associated with the user interface, and an audible location alarm program stored therein. The audible location alarm program is initiated. An audible location alarm signal is transmitted to the ear-level device, thereby providing instruction to the ear-level device to broadcast an audible location alarm through the speaker of the ear level device until detection of an end event.
A personalized hearing profile is generated for an ear-level device comprising a memory, microphone, speaker and processor. Communication is established between the ear-level device and a companion device, having a user interface. A frame of reference in the user interface is provided, where positions in the frame of reference are associated with sound profile data. A position on the frame of reference is determined in response to user interaction with the user interface, and certain sound profile data associated with the position. Certain data is transmitted to the ear level device. Sound can be generated through the speaker based upon the audio stream data to provide real-time feedback to the user. The determining and transmitting steps are repeated until detection of an end event.
An ear-level device which can be operable in multiple modes supports a voice menu by which more complex functions executable by the ear-level device or by a companion module can be selected using input at the ear-level device. By pushing a button on an earpiece for example, a voice menu is activated announcing a set of functions such as voice dial, last number redial and so on. When the function that the user wants is announced, the user presses the same button which activates the execution of the function.
A method controls a functional element of an ear-level device of a type including a functional element, a memory, a microphone and a speaker, each coupled to a processor. Communication between the ear-level device and a companion device, such as a mobile phone, is established. A functional element for control is selected through the user interface of the companion device. A control instruction for controlling the selected functional element is chosen using the user interface and is transmitted from the companion device to the ear-level device to provide instruction to the ear-level device to control the selected functional element in the chosen way.
A modular canal hearing aid assembly having a main module positioned in the ear canal and a disposable battery module laterally positioned in the ear canal. The main module incorporates the durable components of a hearing device including the receiver, microphone and electronics. The disposable battery module comprises consumable elements including battery and incoming sound port. The disposable battery module provides a unitary structure that is easier to handle, remove from the main module, and replace when any of the consumable elements is depleted or degraded. The canal hearing device assembly is generic in shape and provided with assorted seal tips for “instant fitting” without resorting to custom manufacturing.
The invention relates to a hearing aid to be arranged at and/or in an ear, comprising a microphone for converting acoustic signals into electrical signals, a hearing module for providing the electrical signals, a loudspeaker for converting the electrical signals outputted from the hearing module into acoustic signals. The hearing module comprises a means for noise suppression effecting a noise estimation to determine a signal-dependent filter and to provide a noise-reduced output signal.
A hearing aid includes a hearing aid shell, a microphone enclosed within the hearing aid shell, and a sealing member that surrounds the periphery of the microphone enclosed within the hearing aid shell, and a sealing member that surrounds the periphery of the microphone. The sealing member completely fills the area between the periphery of the microphone and the interior surface of the hearing aid shell.
A hearing aid includes a circuit board having a battery affixed thereon and a switch that utilizes a portion of the circuit board as a portion of the switch. The battery is permanently affixed to the circuit board in at least one location and at least a portion of the battery is spaced away from the circuit board. The circuit board further includes at least one pair of printed switch traces. The switch is integrated into the circuit board in a way that utilizes the circuit board to form a rotary switch.
An ear module, which can be selectively worn on either left or right ear, comprises an interior lobe, adapted to fit within the concha, comprising a speaker and a compressive member/cover assembly. The compressive member/cover assembly is positionable, typically rotatable, relative to the remainder of the inner lobe between left and right ear orientations to permit the ear module to be worn on either the left or the right ear. A method for improving the quality of sound emanating from an ear module includes selecting the sound bore within the ear module to help improve the frequency response of the ear module so that the ear module has a resonant peak near 2.7 kHz and a maximum 20 dB decrease in high frequency response as measured at 5 kHz from the average frequency response as measured at 500 Hz, 800 Hz, and 1600 Hz.
A hearing aid comprises a microphone on a proximal side of a device housing and a loudspeaker which via a transmission channel is in open communication with a sound-emitting opening of the device. A sound processing device serves to generate sound received by the microphone to the loudspeaker in amplified form. The device housing is provided on a distal side with an optionally sealed battery chamber for receiving a battery therein. The transmission channel is at least almost wholly separated from the microphone acoustically in order to prevent acoustic feedback. The battery chamber comprises ventilation means for the purpose of increasing the lifespan of the battery.
A hearing aid includes a device housing to be worn outside an ear of a user and which co-acts with an in-the-ear part provided with a sound-emitting opening and which is intended and adapted to be received at least substantially in the ear of the user. The in-the-ear part is physically separated from the device housing, wherein at least a microphone and a loudspeaker are accommodated together with the sound-emitting opening in the in-the-ear part. An electronic connection is present between the device housing and the in-the-ear part. A power supply of a hearing aid particularly includes a capacitor (40), more particularly an ultra-capacitor. The functionality of a hearing aid can be expanded with an expansion unit (50). For an accurate fit of the in-the-ear part use is made of a digital representation which has been modified on the basis of fitting data of a fitting body.
An ear module with an interior lobe (200) housing a speaker (58) and adapted to fit within the Concha (103) of the outer ear, and an exterior lobe (300) housing data processing resources, includes a compressive member (202) coupled to the interior lobe (200) and providing a holding force between the anti-helix (101) and the forward wall (108) of the ear canal (102) near the tragus (104). The interior lobe (200) extends into the exterior opening (110) of the ear canal (102), and includes a forward surface (210) adapted to fit against the forward wall (108) of the ear canal (102), and a rear surface (211) facing the anti-helix (101). The width of the extension (201) (in a dimension orthogonal to the forward surface (210) of the extension (201)) between the forward surface (210) and the rear surface (211) from at least the opening of the ear canal (102) to the tip (203) of the extension (201) is substantially less than the width of the ear canal (102), leaving an open air passage (250).
A method of generating a personalized sound system hearing profile for a user. The method begins by selecting an initial profile, based on selected factors of user input. In an embodiment, the initial profile is selected based on demographic factors. Then the system identifies one or more alternate profiles, each having a selected relationship with the initial profile. The relationship between alternate profiles and the initial profile can be based on gain as a function of frequency, one alternate profile having a higher sensitivity at given frequencies and the other a lower sensitivity. The next step links at least one audio sample with the initial and alternate profiles and then plays the selected samples for the user. The system then receives identification of the preferred sample from the user; and selects a final profile based on the user's preference. An embodiment offers multiple sound samples in different modes, resulting in the selection of multiple final profiles for the different modes. Finally, the system may apply the final profile to the sound system.
A method and system for managing physiological systems is provided. The physiological system management (PSM) system includes one or more signal acquisition blocks to collect physiological information. The PSM system includes oversampled filterbanks for transferring one or more input signal related to the physiological information into subband signals, and a subband processing scheme for processing the outputs from the oversampled filterbanks for event detection in one or more physiological systems. The PSM system includes an adaptive controller which decides on the proper control measure and delivers the measure to the one or more physiological systems.
A personal sound system is described that includes a wireless network supporting an ear-level module, a companion module and a phone. Other audio sources are supported as well. A configuration processor configures the ear-level module and the companion module for private communications, and configures the ear-level module for a plurality of signal processing modes, including a hearing aid mode, for a corresponding plurality of sources of audio data. The ear module is configured to handle variant audio sources, and control switching among them.
A method and system for processing of physiological signals is provided. The system processes information signals in subband-domain associated with the physiological signals in time-domain. The information signals are obtained by one or more over-sampled filterbanks. The method and system possibly synthesizes the subband signals obtained by subband processing. The method and system may implement the analysis, subband processing, and synthesis algorithms on over-sampled filterbanks, which are implemented on ultra low-power, small size, and low-cost platform in real-time. The method and system may use over-sampled, Weighted-Overlap Add (WOLA) filterbanks.
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