EP1883274A1 - Hearing aid with a radio frequency identification receiver for switching a tranfer characteristic - Google Patents

Abstract

The aid has an output side radio frequency identification(RFID) receiver actively connected with the transmission unit with a spatial detection area (25) for a radiofrequency identification (26,29). The RFID receiver is designed to electromagnetically detect the radiofrequency identification and to produce identification signal depending on the availability of radiofrequency identification in the detection area and to emit output side this identification signal to the transmission unit (9). The hearing aid (3) also has a receiving transducer (5) and a sound generator (7). Independent claims are also included for the following: (1) a program system has hearing aid (2) a method for changing transmission property of a hearing aid.

Description

The invention relates to a hearing aid with a sound receiver and a sound generator.

Hearing aids known from the prior art have mutually different hearing programs which respectively correspond to a predetermined, in particular frequency-dependent transmission behavior of the hearing aid. One application example for switching a predetermined hearing program is operation of the hearing aid when making a telephone call. Hearing aids known from the prior art are designed to switch over into a different program as a function of an approach of a telephone handset to the hearing aid, with hearing aids known from the prior art for this purpose having a sensor for detecting a magnetic field. The telephone receiver has a permanent magnet for generating a magnetic field for switching to another program. Hearing devices known from the prior art can have, for example, a REED contact or a GMR sensor (GMR = Giant Magneto-Resistive) for detecting a magnetic field for switching over a hearing program.

Such small but strong magnets cause inappropriate positioning in the hearing aid an unpleasant whistle, caused by a feedback of an induction coil for detecting a telephone signal, a so-called Telecoil. Another problem may be that other foreign magnetic fields may cause unintentional switching to another listening program. Another disadvantage can be irreversibly damaged by an external magnetic field, a sound generator.

The invention is therefore based on the object to provide a hearing aid which does not have the aforementioned problems.

This object is achieved by a hearing aid with a sound receiver and a sound generator, wherein the sound receiver is designed to receive sound waves and to generate a microphone signal representing the received sound waves. The sound generator of the hearing aid is designed to generate a sound as a function of a power signal received on the input side, wherein in particular the sound corresponds to the power signal.

The hearing aid has a transmission unit, which on the input side is connected at least indirectly to the sound receiver and on the output side at least indirectly to the sound generator.

The transmission unit is designed to generate a power signal in response to a microphone signal received on the input side, which signal corresponds at least partially to the microphone signal. For example, a power signal generated on the output side, in particular by the transmission unit, can be freed from interference signals and thus only partially correspond to the microphone signal.

The transmission unit is further configured to change at least one transmission characteristic of the transmission unit as a function of a marking signal received on the input side.

The hearing aid has a radio frequency detection device operatively connected to the transmission unit with a spatial detection range for at least one radio frequency marker, wherein the radio frequency detection device is adapted to detect a radio frequency marker electromagnetically, in particular inductively, and at least one marker signal at least in response to a presence of a radio frequency marker in the detection range generate and output this to the transmission unit output side.

By a radio frequency detection device for detecting a radio frequency marker advantageously no external magnetic field is necessary to cause a switching of the hearing aid in another hearing program. Further advantageously, foreign magnetic fields can not cause unintentional switching to another hearing program.

In a preferred embodiment, the hearing aid is designed to generate the power signal according to at least one predetermined transfer function as a function of at least one microphone signal frequency and / or one microphone signal amplitude.

For example, such a predetermined transfer function can be represented by a hearing program. In hearing-impaired patients who have a hearing impairment in the form of a permanent threshold shift (PTS = Permanent-Shift-Shift), often a frequency-dependent adjustment of transmission characteristics of the hearing aid, in particular by adjusting a gain of a transmission unit is required.

For example, the amplification factor can be adjusted as a function of frequency to a threshold of hearing aid wearer.

In a preferred embodiment, the hearing aid is configured to hold at least two transfer functions in stock and to select exactly one of at least two stored transfer functions depending on the tag signal and the power signal according to the selected transfer function as a function of a microphone signal frequency and / or a microphone signal amplitude of the microphone signal produce.

Preferably, in this embodiment, the radio frequency detection device is configured to generate a marker signal representing marker information of a detected radio frequency marker.

More preferably, a marking signal can represent marking information, in particular class marking information, which corresponds to a class of radio-frequency markings.

In this way, the hearing aid can advantageously switch over to another hearing program representing another transfer function, if, for example, a radio-frequency marker provided for switching over to another hearing program is located in the detection range of the radio-frequency detection device.

For example, a radio frequency tag can be attached to a telephone handset for switching to a telephone hearing program, in particular glued or built into the telephone handset, and thus switch the hearing aid into the corresponding hearing program for telephoning when the telephone handset is brought to the hearing aid.

A second transfer function, or at least one transfer function held in stock, can each be represented by a second, or at least one further, hearing program.

For example, a hearing aid may have a hearing program which corresponds to a transfer function for making telephone calls with a mobile telephone. For example, a radio frequency tag may include predetermined tag information that may be read out or detected upon detection of the radio frequency tag by a radio frequency sensing device.

The radio frequency detection device is configured to generate a marker signal representing the marker information of the detected radio frequency marker.

In this way, radio frequency markers, each representing different marker information, when detected by a radio frequency detection device, can generate mutually different marker signals.

For example, a radio frequency tag with tag information for switching to a phone listening program may select a predetermined transfer function for telephoning; a radio frequency tag with tag information for telephoning with a mobile phone may, for example, when switched on, switch to a listening program having a transfer function for telephoning with the phone Mobile phone represents.

A radio-frequency marker for switching to a mobile telephone hearing program can be arranged, for example, in the region of a mobile telephone, in particular glued to a mobile telephone or installed or arranged in the mobile telephone.

A radiofrequency marker may advantageously have a continuous sound impedance that does not materially or not affect transmission of speech representing sound through the radiofrequency marker, particularly in the frequency range between 100 Hertz and 4000 Hertz. For example, a radiofrequency tag may be perforated or have a thin membrane, preferably less than 10 grams per square meter in thickness, more preferably less than 5 grams per square meter, most preferably less than 2 grams per square meter. A membrane may comprise polyamide, polyester, polyethylene or polypropylene.

Such a radio-frequency marker can advantageously be glued to a telephone receiver and for this purpose have an adhesive adhesive layer.

In an advantageous embodiment, the hearing aid on the input side with the radio frequency detection device and on the output side operatively connected to the transmission device allocation unit. In this embodiment, the hearing aid also has a look-up memory connected to the allocation unit for at least two assignment data records, each assignment data record representing an assignment of exactly one marking or one class of markers to exactly one transfer function. The allocation unit is configured to evaluate the marker signal and to select a mapping data record corresponding to the marker signal and to generate a transfer signal corresponding to a predetermined transfer function represented by the selected assignment set and to output the transfer signal to the transfer unit for selecting the predetermined transfer function.

In this way, it can be advantageous to assign a marking information to a predetermined transfer function.

Class-representing class mark information may, for example, be associated with a predetermined listening program and thus with exactly one predetermined transmission function such that radio frequency markers, each belonging to a class and each having the same class marking information, are each associated with exactly one predetermined transmission function.

A radio frequency tag may represent, in addition to class tag information, individual tag information for switching an individual transfer function.

The invention also relates to a program system. A program system comprising a hearing aid of the aforementioned kind may have at least one radio-frequency marker, which is in each case assigned to a predetermined hearing program or at least have two radio frequency markers, which are each assigned to mutually different hearing programs or transfer functions.

A program system can advantageously have at least one radio-frequency marker, wherein the radio-frequency marker represents at least two mutually different marker information, and wherein the at least two marker information are each assigned to mutually different, corresponding predetermined transfer functions.

For example, the program system can advantageously comprise at least two radio frequency markers, which each represent a class marking information corresponding to a class and are thus respectively assigned to the same class transfer function.

For example, radio frequency tags, each representing class tag information within a class, may be attached to different telephones and thus each associated with the same audio program.

In another embodiment, the hearing aid can select and / or switch at least two transfer functions. For example, a first transfer function of the hearing aid can be assigned to a predetermined class of marking information, and a second transfer function can be assigned to exactly one individual marking information.

In this way, for example, advantageously a first transfer function can be switched for all phones, and by switching a second transfer function, an individual adaptation to a particular type of phone takes place.

In an advantageous embodiment, a hearing aid of the type described above is part of a pair of eye glasses, and the Radiofrequency detection device comprises an antenna for detecting a radio frequency marker, wherein the antenna is at least partially integrated in a spectacle frame and / or in an eyeglass frame of the eye glasses.

By integrating an antenna into a pair of spectacles or a component of a pair of spectacles, a detection range of a radio frequency detection device can advantageously be increased.

A hearing aid may be an in-the-ear hearing aid (IdO) or a behind-the-ear hearing aid (BTE).

The invention also relates to a programming system comprising a hearing aid of the type described above. The programming system includes a programming device for programming a radio frequency marker next to the hearing aid, wherein the programming device is configured to program at least one radio frequency marker with at least one predetermined marker information which is used to generate a marker signal Selecting a predetermined transfer function of the hearing aid is provided.

In a preferred embodiment, the programming device may be advantageously configured to program a radio frequency tag with a first tag information corresponding to a class of radio frequency tags. A class is assigned to a predetermined transfer function. More preferably, the programming device may be configured to program a radio-frequency marker with a second marker information, which is exactly associated with a predetermined transfer function, and thus exactly one hearing program.

A programming device for a programming system can advantageously be designed for programming the hearing aid. Furthermore, the programming device can be designed to use the hearing aid to detect at least one radio-frequency marker to program with at least one predetermined tag information.

The hearing aid for such a programming system is designed to be programmable in such a way that it can store an assignment data record representing the marking information for assigning a predetermined transfer function to the marking information.

A radio frequency detection device preferably has a transmitter for emitting transmission energy to a radio frequency marker.
The radio frequency marker preferably has a receiver for receiving and storing the transmission energy. The radio frequency marker also includes a transmitter for generating a transmit signal representing marker information.

• FM (FM = Frequenzmodulation)
• AM (AM = Amplitudenmodulation)
• FSK (FSK = Frequency Shift Keying)
• ASK (ASK = Amplitude Shift Keying)
• PSK (PSK = Phase Shift Keying)

The transmitter of the radio frequency marker and the radio frequency detecting device may operate in transmitting the signal representing a marker information by one of the following modulation methods or a combination of the following modulation methods:

• FM (FM = frequency modulation)
• AM (AM = amplitude modulation)
• FSK (Frequency Shift Keying)
• ASK (ASK = Amplitude Shift Keying)
• PSK (PSK = Phase Shift Keying)

Preferably, the radio frequency detection device is configured to perform pulsed detection of a radio frequency marker. More preferably, the radio frequency detection device is designed to perform the pulsed non-detection with a pulse pause of two seconds, advantageously one second.

Preferably, the radio frequency detection device is formed, the pulsed detection with a pulse duration of less than 50 milliseconds, preferably less than 10 milliseconds, more preferably less than a millisecond.

Exemplary embodiments of a radio frequency sensing device operate at a carrier frequency of 125 kilohertz, 13.56 megahertz or in the range between 860-980 megahertz. Also conceivable are carrier frequencies in the range of one to five gigahertz.

Energy can be advantageously saved by pulsed detection.

In a preferred embodiment, the radio frequency marker is programmable and has a transceiver. The radio frequency marker can receive and store a marker information signal via a receiver of the transceiver. The transmitter of the transceiver can generate a transmission signal representing the marking information. The transmitter and receiver of the transceiver can each operate according to one of the aforementioned modulation methods.

The hearing aid can advantageously effect switching as a function of a marking signal, in particular a presence or a predetermined marking signal, in particular switching the hearing aid on and / or off to save energy.

• elektromagnetisches Erfassen einer Markierung, insbesondere einer Radiofrequenzmarkierung, in einem Erfassungsbereich der Hörhilfe;
• Ändern der Übertragungseigenschaft wenigstens in Abhängigkeit von einem Vorhandensein der Markierung in dem Erfassungsbereich.

The invention also relates to a method for changing at least one transmission characteristic of a hearing aid, wherein the transmission characteristic represents a dependence of an output sound from a detected sound wave, comprising the steps:

• electromagnetic detection of a mark, in particular a radio frequency mark, in a detection range of the hearing aid;
• Changing the transmission characteristic at least in response to a presence of the mark in the detection area.

• Vorrätighalten von wenigstens zwei zueinander verschiedener Übertragungsfunktionen, welche jeweils zueinander verschiedene Übertragungseigenschaften repräsentieren;
• Auswählen einer vorrätiggehaltenen Übertragungsfunktion in Abhängigkeit von einer erfassten Markierung, insbesondere einer Radiofrequenzmarkierung;
• Ändern der Übertragungseigenschaft der Hörhilfe entsprechend der ausgewählten Übertragungsfunktion.

Preferably, a method may comprise the steps of:

• Keeping at least two mutually different transfer functions, each representing mutually different transfer characteristics;
• Selecting an on-hold transfer function in response to a detected tag, in particular a radio frequency tag;
• Change the transmission characteristic of the hearing aid according to the selected transfer function.

The invention will now be explained below with reference to figures and other embodiments.

FIG. 1 shows-schematically-an exemplary embodiment of a system 1 comprising a hearing aid 3 and a programming device 32.

The hearing aid 3 has a sound receiver 5, which is designed to receive sound waves and to generate a microphone signal depending on the received sound waves, which represents the received sound waves.

The hearing aid 3 also has a sound generator 7, which is designed to generate a sound as a function of a power signal received on the input side.

The hearing aid 3 also has a transmission unit 9, which on the input side via a connecting line 52 with the Sound receiver 5 is connected and the output side is at least indirectly connected to the sound generator 7.

The transmission unit 9 is designed to generate an output signal which at least partially represents the microphone signal as a function of a microphone signal received on the input side, in accordance with at least one predetermined transfer function.

On the output side, the transmission unit 9 is connected via a connecting line 48 to an amplifier 10, which is designed to generate a corresponding amplified power signal in response to an input signal received on the input side and to output the power signal on the output side.

The amplifier 10 is connected on the output side via a connecting line 50 to the sound generator 7.

The transmission unit 9 can be formed, for example, by a digital signal processor which is designed to change a transmission behavior for a microphone signal received on the input side as a function of the filter quotients received on the input side.

A transmission unit may include the transmission unit 9 and the amplifier 10.

In this exemplary embodiment, the hearing aid 3 also comprises a central processing unit 12, an allocation unit 14, a look-up memory for storing assignment data records 18 and 20, wherein the allocation memory 16 is connected to the central processing unit 12 via a bidirectional data bus 54.

The hearing aid 3 in this embodiment also includes a radio frequency detection device 22 for detecting a radio frequency marker. The radio frequency detecting device 22, also referred to below as the RFID receiver, is connected on the input side via a connecting line 42 to an antenna 24 for detecting a radio-frequency marker 26. The RFID receiver 22 is designed to inductively detect the radio-frequency marker 26 via the antenna 24 and to generate a marker signal which represents a marker information of the radio-frequency marker 26.

The central processing unit 12 is connected on the input side via a connecting line 44 to the RFID receiver 22. The RFID receiver 22 is designed to send the marking signal on the output side via the connecting line 44 to the central processing unit 12.

The central processing unit 12 is connected on the input side via a connecting line 40 to an interface 38.

The interface 38 in this embodiment is an infrared interface, in particular an IrDA interface (IrDA = Infrared Data Association). The interface 38 is designed to receive, in particular to receive an information signal 34 wirelessly. The system 1 also includes a programming device 32, which is designed to transmit the information signal 34. The information signal 34 represents a marker information for a radio frequency marker. The programming device is further configured to program an unprogrammed radio frequency marker 27 - which still has no marker information - which is located in a detection area 36 of the programming device 32 with marker information which is provided for assignment to a transfer function.

The central processing unit is designed to generate an assignment data record which is represented by the information signal as a function of an information signal received via the connection line 40 on the input side Marking information and one of the marking information associated transfer function corresponds.

The central processing unit 12 is designed to store the assignment data record via the bidirectional data bus 54 in the look-up memory 16. In this exemplary embodiment, the assignment data record comprises a marking data record 18 and a transmission data record 20 to be assigned thereto.

The operation of the system 1 will now be explained below:

A radio frequency marking 26 may be located, for example, in a detection area 25 of the antenna 24 of the RFID receiver 22. The radio frequency marker 26 has a transmitting and receiving antenna 28, which is connected to a chip 30. In the chip 30 a marking information is stored - which, for example, as previously described by the programming device 32 has been generated and stored in the chip 30. The RFID receiver 22 can emit via the antenna 24 a transmission energy that can be received by the antenna 28 of the radio frequency marker 26 and stored for returning a marker signal. The radio-frequency marking 26 is designed to generate a marking signal representing the marking information with the previously received, stored transmission energy and to send this back to the RFID receiver 22 via the antenna 28.

The thus-returned marker signal can be received via the antenna 24 and the RFID receiver 22 and sent via the connection line 44 to the central processing unit 12.

The central processing unit 12 can receive the marking signal received on the input side via the connecting line 44 with assignment data records stored in the look-up memory 16 and in the event of a match of the received marker signal with a marker record 18 of a mapping record, generate a transfer signal corresponding to a corresponding transmit record 20 of the mapping record.

The central processing unit 12 can have an allocation unit 14 for comparing an input-side marking signal with an assignment data record. The allocation unit 14 is - indicated by dashed lines - connected to the connecting line 44 and the bidirectional data bus 54, as well as the output side to the connecting line 46.

The transfer signal may, for example, represent filter quotients a (0)... A (n) for setting a digital filter of the transmission unit 9.

Alternatively, predetermined transmission functions may be stored in the transmission unit 9, and the transmission signal may correspond to a predetermined transmission function. The transmission unit 9 can then, depending on a transfer signal received on the input side, select a predetermined transfer function for generating an output signal as a function of a microphone signal received on the input side and switch it into a transmission path.

The radio frequency marking 29 is located in the detection range 25 of the antenna 24, the telephone receiver 31 is located at least partially in the detection range 25 of the antenna 24th Exemplary is also a telephone handset 31 with a mounted on this or applied thereto radio frequency marker 29.

Claims (13)

Hearing aid (3) with a sound receiver (5) and a sound generator (7),
wherein the sound receiver (5) is adapted to receive sound waves and to generate a microphone signal representing the received sound waves,
and the sound generator (7) is designed to generate a sound as a function of a power signal received on the input side, the sound corresponding to the power signal,
and a transmission unit (9) which is connected at least indirectly to the sound receiver (5) on the input side and at least indirectly to the sound generator (7) on the output side, and wherein the transmission unit (9) is designed to generate a power signal in response to a microphone signal received on the input side which at least partially corresponds to the microphone signal,
and the transmission unit (9) is designed to change at least one transmission characteristic of the transmission unit (9) in dependence on a marking signal received on the input side,
characterized,
that the hearing aid (3) having an output side to the transmission unit (9) operatively connected to the RFID receiver (22) with a spatial detection region (25) for at least one radio frequency tag (26, 29),
wherein the RFID receiver (22) is adapted to electromagnetically detect a radio frequency marker (26, 29) and at least one marker signal at least in response to a presence of a radio frequency marker (26, 29). to generate in the detection area and output this to the transmission unit (9) output side. Hearing aid according to claim 1,
characterized,
in that the radio-frequency marking has a transmitting and receiving antenna which is connected to a chip, wherein a marking information is stored in the chip. Hearing aid according to claim 1 or 2,
characterized,
in that the hearing aid is designed to generate the power signal according to at least one predetermined transfer function as a function of a microphone signal frequency and / or microphone signal amplitude of the microphone signal. Hearing aid according to claim 3,
characterized,
in that the hearing aid (3) is designed to keep at least two transmission functions in stock and to select one of at least two transmission functions in dependence on the marking signal and to supply the power signal according to the selected transmission function as a function of a microphone signal frequency and / or a microphone signal amplitude of the microphone signal produce,
and the RFID receiver (22) is adapted to generate a marker signal corresponding to a predetermined marker information of a detected radio frequency marker (26, 29). Hearing aid according to one of the preceding claims,
characterized,
that the hearing aid comprises an input side to the RFID receiver and on the output side to the transmission device operatively connected allocation unit,
and the hearing aid has a look-up memory connected to the allocation unit for at least two assignment data records (18, 20),
wherein each assignment data set (18, 20) represents an assignment of a predetermined marking information to a transfer function or an assignment of a marking information representing a class to a predetermined transfer function,
and the allocating unit is configured to evaluate the marker signal and select an assignment data set (20) corresponding to the marker signal to generate a transfer signal corresponding to a predetermined transfer function represented by the selected allocation record and the transfer signal to the transfer unit for selecting and / or switching the predetermined transfer function issue. Hearing aid according to one of the preceding claims,
characterized,
in that the RFID receiver (22) is designed to perform pulsed detection of a radio-frequency marker (26, 29). Hearing aid according to one of the preceding claims,
characterized,
in that the hearing aid is part of a pair of eye glasses and the RFID receiver (22) has an antenna (28) for detecting a radio frequency marker (26, 29), wherein the antenna (28) at least partially in a spectacle frame and / or in an eyeglass temple the vision glasses is integrated. Program system comprising a hearing aid according to one of the preceding claims,
characterized,
in that the program system has at least one radio-frequency marker (26, 29) with marking information which is assigned to a predetermined transfer function. Program system according to claim 8,
characterized,
in that the program system has at least one radio-frequency marker (26, 29), wherein the radio-frequency marker (26, 29) represents at least two mutually different marker information and wherein the at least two marker information are respectively assigned to different, corresponding predetermined transfer functions. A programming system comprising a hearing aid according to any one of claims 1-7, and a programming device (32) for programming a radio frequency marker (27),
characterized,
in that the programming device (32) is designed to program at least one radio frequency marker (27) with at least one predetermined marker information, which is used to generate a marker signal for selecting a marker signal predetermined transfer function of the hearing aid (3) is provided. A programming system comprising a hearing aid according to any one of claims 1-7 and a programming device for programming the hearing aid,
characterized,
in that the hearing aid (3) is designed to be programmable and the programming device (32) is designed to program the hearing aid (3) for detecting at least one radio-frequency marker (26, 29) with at least one predetermined marker information, wherein the hearing aid (3) is formed, to store an assignment data set representing the tag information for assigning a predetermined transfer function to the tag information. A method for changing at least one transmission characteristic of a hearing aid (3), wherein the transmission characteristic represents a dependence of a generated output sound from a sound wave detected on the input side, comprising the steps: - Electromagnetic detection of a radio frequency marker in a detection range of the hearing aid; Changing the transmission characteristic at least in response to a presence of the radio frequency marker in the detection area. The method of claim 11, comprising the steps of: - maintaining at least two mutually different transfer functions, each of which represents mutually different transfer characteristics; Selecting an on-hold transfer function in response to a detected radio frequency mark; - Change the transmission characteristic of the hearing aid according to the selected transfer function.

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