Abstract: A customized hearing assistance device system, or CHADS, including hearing profiles generated by a digital signal processor (DSP) device is also set forth. A microprocessor, configured to store the hearing profiles, each of the profiles including a plurality of audio parameters, is provided. The microprocessor can be operatively connected to an audio input and an audio output of the system. A modification interface is provided. The modification interface is operatively connected to the microprocessor. The modification interface is configured to selectively adjust any parameter of one of the hearing profiles, whereby a user of the CHADS can actuate the microprocessor to select one of the hearing profiles stored in the microprocessor. The user can employ the modification interface to adjust one or more parameters of the selected hearing profile in response to a change in the ambient sound environment.

Abstract: A hearing aid with a housing holding a microphone, a battery, a programmable signal processing device capable of delivering an output signal is provided whereby the output signal drives an output transducer of the hearing aid to serve a stimulus on the hearing aid user perceivable as sound. The hearing aid housing further holds a socket adapted for receiving a programming connection in order to connect the programmable signal processing device to an external programming device, and a switch adapted to be operated by the hearing aid user, and a cover arranged above the socket and switch and pivotally linked to the hearing aid. Preferably an intermediate link is provided and adapted to interlink the hearing aid with the cover.

Abstract: A cochlear implant system includes: an electrode array implanted within a cochlea; an internal processor in communication with the electrode array; an implanted antenna which is electrically coupled to the internal processor; and a modular external headpiece which is removably positioned over the implanted antenna, the modular external headpiece including a core containing a sound processor for processing sound and providing a corresponding signal to the implanted antenna; and a modular component configured to releasably engage the core and supply electrical power to the core.

Abstract: A hearing aid includes a casing configured to fit behind an ear of a user's head and against a side of the user's head. The hearing aid further includes a first proximity sensor associated with the casing and configured to generate a first signal that is proportional to a proximity of the casing to the ear and includes a processor coupled to the first proximity sensor and configured to select an operating mode from a plurality of operating modes in response to the first signal.

Abstract: A hearing aid system (100) comprises a hearing aid (102) and an external device (101). The hearing aid (102) has link means for providing a wireless link with the external device (101), memory means for storing a hearing aid variable and signal processing means for initiating the logging in response to a trigger signal received from the external device (101) The external device (102) has link means (107) for providing the wireless link with the hearing aid (102), an input transducer (103) for providing an electrical audio signal, memory means (105) for storing a sample of the electrical audio signal, user input means (106) and signal processing means (104) configured for initiating the recording of the electrical audio signal sample and for initiating the transmission of the trigger signal to the hearing aid (102) in response to an activation of the user input means (106). The invention further provides a method of fitting a hearing aid system (100).

Abstract: A user interface incorporated onto a hearing aid includes flexible hybrid component integrating a touch sensor into a bendable display. The touch sensor, such as a capacitive sensor, includes one or more sensor elements allowing a user to control operation of the hearing aid by touching. The bendable display presents information related to the operation of the hearing aid to the user.

Abstract: A hearing assistance device, comprising a microphone to receive sound, signal processing electronics electrically connected to the microphone, a receiver electrically connected to the signal processing electronics and a switch electrically connected to the signal processing electronics, wherein the switch includes conductive silicone adapted to change the switch from a first state to a second state when activated.

Abstract: The invention relates to a system and a method for configuring a hearing device by means of an external configuration unit, the hearing device comprising a microphone, an A/D-converter, a processing unit with a memory, a D/A-converter and a receiver, the external configuration unit comprising a programming host, an external processing unit, an interface and a playing device, the method including the steps of processing a sound recording from the playing device with a parameter setting externally, feeding the processed sound recording to the receiver of the hearing device via the interface and the D/A-converter, emitting the processed sound recording through the receiver, repeating steps a) to c) with varying parameter settings until a match between the quality of the signal and the requirements of the user is reached, and transmitting and storing the chosen parameter setting in the memory of the hearing device.

Abstract: The invention relates to an assistive listening system comprising an audio transmitting device adapted for transmitting an audio signal and/or a control signal to a multitude of receiving listening devices and at least one receiving listening device adapted for receiving said audio signal and said control signal from said audio transmitting device. The invention further relates to a method of operating an assistive listening system and to its use. The object of the present invention is to provide an assistive listening system suitable for servicing a multitude of body worn listening devices in a wireless environment. The problem is solved in that the system is adapted to establish a digital link according to the DECT-standard from the audio transmitting device to the at least one receiving listening device, wherein the system is adapted to provide that said link is uni-directional.

Abstract: A configuration and an associated method for the wireless transmission of data between hearing devices include an external unit which generates and emits a carrier signal, a first hearing device with a first transponder which modulates and back-scatters the carrier signal and a second hearing device with a second transponder which receives the carrier signal that is scattered backwards and forwards and modulated by the first transponder. The external unit is, for instance, a hearing device remote control. Advantageously, little or no additional energy is needed in the hearing device for the wireless data transmission. The energy for the supply of the first transponder is delivered by the carrier signal of the external unit.

Abstract: The hearing device comprises a connector (2) having at least one electrical contact (6); and a user control (8); wherein said user control (8) comprises said at least one electrical contact (6). Typically, said connector is a connector for providing a communication connection to said hearing device. The user control can be a pushbutton switch. In one embodiment, said connector comprises at least two electrical contacts (6), and said user control comprises a shorting member (12) for shorting said at least two electrical contacts when operated. In one embodiment, said user control comprises an elastic member (14), which is deformed when said user control is operated, for resetting said user control into its original position. Through this, a small-size hearing device can be realized. The method of operating a hearing device comprises the step of using at least one electrical contact (6) of a connector (2) of said hearing device as a part of a user control (8) of said hearing device.

Abstract: Systems and methods for diagnosis or treating tinnitus are disclosed. In some embodiments, a method for treating tinnitus includes receiving, by a programmed computer system, input data representative of one or more of the following characteristics of an user tinnitus: central frequency, bandwidth, volume, hearing threshold, and tone to noise ratio of a user tinnitus; processing, in real-time, by the programmed computer system, user tinnitus data to generate a user tinnitus profile based on the received one or more categories of user tinnitus data; and generating, in real-time, by the programmed computer system, a notched audio output according to the user tinnitus profile.

Abstract: A hearing aid system may include a behind-the-ear (BTE) part configured to be located at an ear of a user, an in-the-ear (ITE) part configured to be located in an ear canal of a user, and a measurement circuit. The ITE part may include a receiver for converting an electric output signal having frequencies in the human audible frequency range to an output sound, and a resistive identification element. The measurement circuit is configured to measure an identification parameter indicative of the resistance of the resistive identification element, thus identifying the ITE part. The measurement circuit uses the same electric output signal that is driving the receiver to determine the identification parameter. Advantageously, this approach does not require an additional signal, such as DC voltage, to determine the identification parameter.

Abstract: 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.

Abstract: This invention relates to a system (100, 200) for enabling a hearing device (106, 202) wireless access to a communication network (114). The system (100, 200) comprises a first transceiver unit (108) in said hearing device (106, 202) communicating according to a first communication protocol. The system (100, 200) further comprises a server device (112, 204) comprising an input/output unit (122), which is connected to the communication network (114) and communicates according to a second communication protocol, a second transceiver unit (118), which is connected wirelessly to the first transceiver unit (108) and communicates according to the first communication protocol, and comprising a translator unit (120), which interconnects the second transceiver unit (118) and the input/output unit (122) and translates between the first and second communication protocol.

Abstract: An active medical device, including an input receiver configured to receive a frequency-varying input signal, and a functional component that reacts to the input signal and consumes power at a rate dependant on the frequency of portions of the input signal to which the functional component reacts, wherein the active medical device is configured to adjust one or more portions of the input signal corresponding to portions of the input signal where the functional component consumes power at a rate that is greater than that of other portions of the input signal.

Abstract: The invention relates to a hearing aid system comprising an input transducer for converting an input sound signal comprising an information signal part of a known waveform and a background noise part to an electrical analogue input signal, optionally an A/D converter for converting the electrical input signal to a digital input signal. The invention further relates to a method of making a critical gain measurement. The object of the present invention is to improve the signal-to-noise ratio of a signal to be measured or detected in a hearing instrument compared to prior art solutions. The problem is solved in that a matched filter receiving said analogue or digital input signal and optimized to improve the identification of the information signal part from the noisy input signal. An advantage of the invention is that it provides an alternative scheme for improving signal to noise ratio of a hearing aid. The invention may e.g.

Abstract: Acclimatization of a hearing device user to a hearing device is made more acceptable by automatic acclimatization management. The intensity of the hearing device is increased in the long term, e.g. during several months. The speed of the intensity increase depends on user inputs. A user controls an audio processing parameter (APP), such as volume, with a user control. Each time the user switches the hearing device off and on again, the power-on value (POV) of the audio processing parameter (APP) is changed. The amount of the change depends on which settings for the audio processing parameter (APP) have been selected by the hearing device user and how long the settings have been active. An initial power-on value (iPOV) and a target power-on value (tPOV), which is to be reached at the end (H) of the acclimatization phase, may be programmed by an audiologist.

Abstract: An calibrated hearing-aid tuning appliance includes a hearing-aid interface for programming settings of a hearing aid worn by a user. The appliance also includes a calibrated audio output subsystem including an audio interface, an audio amplifier, and a calibrated speaker. The audio output subsystem can consistently propagate sound waves having frequency response, sound pressure level, and distortion characteristics within predetermined tolerances. A memory stores pre-recorded sound files and programming instructions for heuristically tuning the hearing-aid. When the programming instructions are communicated to a CPU for execution via a CPU interface, the appliance automatically selects at least one of the pre-recorded sound files; automatically reproduces the selected sound files via the calibrated audio output subsystem; collects feedback from the user based on the sound files thereby reproduced; and automatically adjusts one or more of the settings based on the user's feedback.

Abstract: A digital headset system for use in audiometric testing. The headset system includes a stored calibration reference relating the exact frequency and volume response of each speaker to analog input signals. A microprocessor accesses the calibration reference to determine the required analog signal needed to produce the desired sound. An on-board digital to analog converter generates the required analog signal and transmits it to the speaker. The headset is used with software based audiometric test methods that allow the generation of an electronic user hearing profile. The user hearing profile may be used to re-program an audio emitting device to function in a customized manner. The user hearing profile may be overlaid on a partner hearing profile in order to emulate for the partner how sounds are perceived by the user. The test methods may be self-administered or administered by a healthcare professional.

Abstract: A method for operating a hearing system (1) is described, the hearing system comprising a signal processor (12) controlled by settings of sound processing parameters referred to as current settings, wherein the current settings are stored in a first memory unit (18), and a second memory unit (19) comprises former settings.

Abstract: A programmable hearing aid including means for receiving and transmitting data wirelessly from and to a portable module being in proximity to said hearing aid. Said portable module has means for transmitting audio signals, fitting data or special instructions to the hearing aid processor and including means for receiving data transmitted from said hearing aid, including data representing a monitoring of real-time signal processing parameters in the hearing aid. A preferred embodiment of the hearing aid/portable module combination utilizes Miller-coded direct sequence spread-spectrum radio signal transmitters and receivers for transmitting and receiving data between the heading aid and the portable module. This enables remote controlling or monitoring of, transmitting audio to, or programming of a hearing aid without the need for external connectors.

Abstract: An audio device and an audio input/output method are described, which is coupled to an audio port, and includes a capacitor, a load, an output amplifying module, and an input amplifying module. The capacitor and the load are coupled to the audio port. The output amplifying module is operated at a first working voltage, for outputting a first audio signal to the audio port. A direct current (DC) level of the first audio signal is substantially zero volts. The input amplifying module is operated at a second working voltage, in order to receive a second audio signal from the audio port. When the audio port is in an output state, the output amplifying module is enabled and the input amplifying module is disabled, and when the audio port is in an input state, the input amplifying module is enabled and the output amplifying module is disabled.

Abstract: A system and method for identification of a peripheral device is provided. A system and method for automatic parameter adjustment of a destination device based on the identification of a peripheral device is provided.

Abstract: The invention relates to a hearing aid with at least one sound receiver and a sound generator. The hearing aid has an audio signal unit operatively connected to the sound generator, the audio signal unit being designed to generate an audio signal perceptible to a human ear. The audio signal has a plurality of mutually different frequencies of a frequency range. The audio signal unit has at least one tone generator. The at least one tone generator is designed to generate the audio signal with at least one fundamental frequency representing a tone and with harmonics of the fundamental frequency.

Abstract: A hearing aid (1) and a method of managing data stored in a logging device in a hearing aid is devised. The method involves obtaining sets of data representing parameters such as the sound environment at a predetermined data acquisition rate and storing the data according to one of a plurality of a set of possible parameter sets in a histogram (15) is having room for a limited number of instances of each particular set of parameters. If the limit for a particular histogram bin is reached when an instance is stored in the histogram, the data acquisition rate is adjusted according to a specified scheme and the number of instances of every parameter set is reduced by a fixed factor. Acquired data in the histogram thus reflects the most recent sound environments experienced by the hearing aid user.

Abstract: A hearing aid is provided which has at least one input transducer for providing an input signal, at least one signal processing channel receiving at least a portion of said input signal, a hearing aid processor for processing said portion of said input signal to produce at least one output signal, an output transducer responsive to said output signal, and a data logger receiving said portion of said input signal for logging of input signal data. The data logger comprises a characterization unit for characterising and logging parameters of the input signal data, and a memory unit for storing said parameters.

Abstract: Systems and methods may be used to modify a controllable stimulus generated by a digital audio device in communication with a human user. An input signal is provided to the digital audio device. In turn, the digital audio device sends a stimulus based on that input signal to the human user, who takes an action, usually in the form of an output signal, to characterize the stimulus that the user receives, based on the user's perception. An algorithm then determines a difference between the input signal and the output signal, and a perceptual model is constructed based at least in part on the difference. Thereafter, a new value for the parameter of the digital audio device is suggested based at least in part on the perceptual model. This process continues iteratively until the algorithm finds the user's optimal device parameters. While this process is highly complex and time consuming, the algorithm successfully reaches at least a near optimal settings, if not the optimal, in a short time.

Abstract: A hearing assistance device has one multipurpose control device that operates in a algorithm selection mode and a daily use mode. In the algorithm selection mode, the multipurpose control device is used to switch between amplification algorithms and select one of the algorithms to be implemented in an audio processing program. In the daily use mode, the multipurpose control device is used to adjust the volume of sound generated by an audio output section. A battery compartment door of the device has an open position in which the device is powered off, and a closed position in which the device is powered on. The multipurpose control device and the battery compartment door are the only user-operable controls on the hearing assistance device for controlling the device and powering the device on or off. No other controls are needed for adjusting volume, selecting algorithms, and switching between and selecting programs.

Abstract: A method for providing hearing assistance to a user, comprising capturing audio signals by an internal microphone arrangement and supplying the captured audio signals a central signal processing unit; estimating whether a certain type of external audio signal supply device is connected to the audio signal processing unit in order to supply external audio signals to the central signal processing unit, and selecting an audio signal processing scheme according to the estimated type of external audio signal supply device; processing, the captured audio signals and the external audio signals according to the selected audio signal processing scheme; transmitting the processed audio signals to stimulating means worn at or in at least one of the user's ears via a wireless audio link; and stimulating the user's hearing by said stimulating means according to the processed audio signals.

Abstract: A method for providing hearing assistance to a user, comprising capturing audio signals by a microphone arrangement; measuring at least one mechanical parameter; selecting an audio signal processing scheme according to the measured at least one mechanical parameter; processing, by a signal processing unit, the captured audio signals according to the selected audio signal processing scheme; transmitting the processed audio signals to stimulating means worn at or in at least one of the user's ears via a wireless audio link; and stimulating the user's hearing by said stimulating means according to the processed audio signals.

Abstract: A circuit for operating a hearing device with a variable operating parameter is disclosed. A storage device for storing operating parameter settings in a starting situation as well as in a target situation and a control unit, which implements a matching of the operating parameter according to a setting of the starting situation to the operating parameter settings of the target situation, is provided. Further, a connection device for connection to a control element and a data processing device for influencing the operating parameter by a user of the hearing device, is provided. The control unit performs the matching of the operating parameter with a minimal matching rate in time segments in which the operating parameter is often influenced by the control element or data processing device, and with a higher matching rate in time segments, in which the operating parameter is rarely influenced or not influenced at all by the control element or data processing device.

Abstract: 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.

Abstract: A hearing aid (62, 72, 82, 92, 102, 112) adapted for alleviating tinnitus of a user (75), comprises an audio input means (83), a signal processing unit (88, 98, 108, 118) and an output transducer (80). The hearing aid further comprises a band stop filter (87) arranged to match a tinnitus of the user and switching means (86, 116) and switch control means (84, 114) for controlling the switching of said band stop filter (87) into and out of the signal path between the audio input means (83) and the output transducer (80), in response to a predefined trigger event. The invention further provides a method of adjusting a hearing aid.

Abstract: A hearing aid is described. The hearing aid includes a control surface and a control element. The hearing aid further includes a plurality of components in addition to the control surface and the control element. A portion of the control surface is configured to engage a portion of the control element. The control surface at least partially circumscribes at least one of the plurality of components.

Abstract: The present subject matter relates to a hearing assistance device for an ear of a wearer comprising a microphone for receiving sound, hearing assistance electronics in communications with the microphone, the hearing assistance electronics including a hybrid circuit, and a wearable housing adapted to house at least the hearing assistance electronics. The hybrid circuit comprises a first integrated circuit die having one or more through-silicon-vias (TSVs), a first redistribution layer disposed on a surface of the first integrated circuit, and a second integrated circuit die having one or more contacts, the second integrated circuit die disposed on the first redistribution layer, wherein the first redistribution layer is adapted to connect one or more of the one or more TSVs of the first integrated circuit die to one or more of the one or more contacts of the second integrated circuit die.

Abstract: This hearing aid adjustment device is connected to a hearing aid and is used to adjust the hearing aid by using reference sounds, and comprises a memory section, an output section, an input section, a controller, and a display section. The memory section stores reference sounds to which segment information has been assigned, as well as the desired volume range for the hearing aid user. The output section outputs a reference sound from the memory section to the hearing aid. The input section inputs hearing aid processed sounds with respect to reference sounds that have undergone hearing aid processing in the hearing aid. The controller calculates the volume of segment units included in a hearing aid processed sound on the basis of segment information stored in the memory section. The display section displays in segment units whether or not the volume calculated by the controller falls within the desired volume range for the hearing aid user as stored in the memory section.

Abstract: A hearing aid (100) fits in an ear of a user and amplifies a sound and outputs the amplified sound.

Abstract: The data records to be stored in the two hearing devices of a binaural hearing system during the adjustment are generally different. With “side definition”, the correct assignment of the two hearing devices to the ears or of the wearer is ensured. To this end, an acoustic signal is transmitted to the wearer by way of the receiver of at least one of these hearing devices. The wearer informs the adjusting facility by way of an input device connected hereto, as to the ear with which the wearer heard this acoustic signal or which spatial characteristic or asymmetry is attributed to this acoustic signal.

Abstract: A hearing apparatus and particularly a hearing aid intended to be able to recognize acoustic situations more reliably includes a microphone device for picking-up a sound signal, a reception device for picking-up an electrical or electromagnetic signal and a classification device for determining an acoustic situation from the signals of the microphone device and the reception device. A signal processing device processes the signals of the microphone device and the reception device as a function of an output signal of the classification device. In particular, the signals of the microphone device and the reception device are made available separately to the classification device for recognizing the situation. Thus, the individual input signals, or the correlation thereof, can be used for recognizing the situation. A method for operating a hearing apparatus is also provided.

Abstract: The present disclosure includes methods, devices, and systems for cochlear implants. One method embodiment for cochlear implant signal processing includes processing a differential analog audio signal using amplitude modulation and pulse-width modulation. The method includes driving a transmission coil on an external unit of the cochlear implant with the pulse-width and amplitude modulated signal. The method also includes driving a reception coil on an internal unit of the cochlear implant with an output of the transmission coil.

Abstract: The present application discloses systems and methods for determining one or more configuration settings for a first hearing prosthesis based on configuration data associated with a second hearing prosthesis. In some embodiments, determining the one or more configuration settings for the first hearing prosthesis may include determining an acoustic operating range associated with the first hearing prosthesis based on whether a configured gain at one or more frequencies for the second hearing prosthesis meets or exceeds a target gain at the one or more frequencies. Some embodiments may also include storing the determined configuration settings in a tangible computer readable memory associated with the first hearing prosthesis.

Abstract: A hearing aid (1) comprises a housing, two microphones (3, 4), signal processing means provided with user selectable settings, and a receiver. The housing is provided with mechanical sound generating means (5, 11). The sound generating means is capable of providing a specific sound when manipulated by a hearing aid user. The sound generating means is arranged such that the two signals (25), obtained from the specific sound being recorded by the two different microphones (3, 4) will have a negative correlation, making said specific sound identifiable by said signal processing means. The signal processing means are arranged for selecting a specific setting dependent on one or more sounds generated by the sound generating means (5, 11). The invention further provides a method for selecting a setting of a hearing aid.

Abstract: A system for assisting a hearing impaired user is presented. The system includes a transmitter to transmit data representing audio intended to be heard by a hearing impaired person, the transmitter paired with at least one intended receiver. The transmitter includes: an analogue-to-digital converter to convert an analogue audio signal into digitally represented audio data, and a transmitter to transmit the digitally represented audio data in a radio signal on an active channel selected from a plurality of channels. The system also includes a receiver to receive data representing audio to be heard by the hearing impaired person, the receiver paired with the transmitter device. The receiver includes a receiver to receive the radio signal containing the digitally represented audio data, the radio signal being received from the transmitter on the active channel, and a digital-to-analogue converter to convert the digitally represented audio data into an analogue audio signal.

Abstract: A hearing aid configuration and an associated method provide wireless transmission of data between a hearing aid and an external unit. The external unit, for example a programming device, is worn with a lanyard around the neck of a hearing aid user. The configuration additionally contains at least one second antenna disposed in the lanyard and at least one third antenna arranged in the lanyard which is connected by an electric series circuit to the second antenna. The advantage of this is that the lanyard can be made long enough to be comfortable to wear and a sufficiently high receive signal of the wireless data transmission is still guaranteed in the external unit.

Abstract: A method for operating a hearing aid in a hearing aid system where the hearing aid is continuously learnable for the particular user. A sound environment classification system is provided for tracking and defining sound environment classes relevant to the user. In an ongoing learning process, the classes are redefined based on new environments to which the hearing aid is subjected by the user.

Abstract: The invention regards a method for programming a hearing aid wherein the hearing aid user is initially tested by subjecting the user to air borne sound and/or to bone transmitted vibrations, and based on the test results a bone conducting hearing threshold of a bone integrated bone conducting hearing aid is calculated, and further a bone conducting hearing aid is chosen and applied to a skin penetrating abutment which is firmly attached to a bone integrated fixture in the skull bone of the hearing aid user. According to the invention the vibrator in the chosen hearing aid is caused to vibrate at different frequencies and vibration levels and feed-back from the hearing aid user is obtained in order to obtain knowledge of the hearing aid users experienced hearing threshold with the attached hearing aid and finally the experienced hearing threshold is used to fine tune this same hearing aid for future wearing by the user.

Abstract: A method for improving compatibility of a hearing aid with an antenna, in which at least a metal frame is provided near by a grounding surface of the antenna to change the direction of radiation of the antenna, thereby to enhance the directivity of the antenna on the side away from a hearing aid, and to reduce the quantity of radiation proceeding toward the hearing aid and to improve the near-field quantity (for about 3 dB) of an electric field of an HAC tested plane. This method can further increase the heights of the metal frames to reduce the near-field quantity of the electric field of HAC (hearing aid compatibility) tested plane.

Abstract: A hearing apparatus for adjusting a hearing aid and an associated method. The apparatus includes at least one hearing aid and at least one external unit which can exchange data with the hearing aid. It further includes a first memory unit in the external unit which stores a point in time and a hearing situation at which at least one predeterminable algorithm for signal processing is activated, an output unit in the external unit which outputs the stored points in time and hearing situations, an input unit in the external unit for entering a measure of evaluation which expresses the satisfaction of a hearing aid wearer with the activated algorithm, and a modification unit in the hearing aid for changing at least one parameter of the algorithm as a function of the measure of evaluation. The hearing aid user is able to evaluate and change the setting of their hearing aid retrospectively for specific hearing situations.

Abstract: The present disclosure relates to methods and apparatus of communicating instructions to a hearing assistance device, such as a hearing aid. In various embodiments instructions are formed using tones sent to the hearing assistance device. The instructions can be used to control the operation of the hearing assistance device. The signals may include dual tone multifunction signals or other nonstandard signals. Various detection processes are provided which include but are not limited to using a modified complex Goertzel algorithm to detect tones. The remote device can be a standard device or can be modified to provide the proper signals. The following techniques can be applied to hearing assistance devices including, but not limited to completely-in-the-canal devices, in-the-canal devices, behind-the-ear devices, receiver-in-canal devices, and implanted devices, such as cochlear implants.