EP1885158A2 - Hearing-aid with audio signal generator and method - Google Patents

Abstract

The hearing aid (21) has an audio signal unit formed and effectively connected with a sound generator (64) for generating an audio signal. The audio signal exhibits multiple audio signal sections in series in such a manner that one audio signal section temporally following the previous audio signal section starts before the termination of the previous audio signal section such that the previous and following sections overlap each other with an overlapping time period, where the overlapping time period is smaller than an audio signal section time period of the previous section. An independent claim is also included for a method for generating an audio signal by a hearing aid.

Description

The invention relates to a hearing aid with at least one sound receiver and a sound generator. In hearing aids known from the prior art, a user interface is known, which is designed to generate a signal tone or an acknowledgment tone as a function of user interaction or as a function of a predetermined event. For example, the hearing aid known from the prior art can confirm a successful change to another hearing program with an acknowledgment tone.

This acknowledgment tone can be reproduced via the sound generator of the hearing aid.

The hearing aids known from the prior art have the problem that such beeps or acknowledgment tones can be perceived as unpleasant by a user of the hearing aid known from the prior art. From the WO 01/30127 A2 a hearing aid is known which can provide time-limited audio signals on user-changeable storage elements. In this case, different audio signal patterns are provided for an audio signal. The audio signals are each time-limited and can each be generated as an acknowledgment signal in response to a control signal. The user can program the audio signals in which corresponding audio signal patterns can be loaded into a memory of the hearing aid. Sequences of beep signals are also provided as acknowledgment signals.

The problem underlying the invention is therefore to provide a hearing aid improved with regard to the aforementioned problem.

This object is achieved by a hearing aid according to claim 1 having at least one sound receiver and a sound generator, wherein the at least one sound receiver is configured to receive sound waves and to generate a microphone signal representing the received sound waves.

The hearing aid also has a transmission unit which is connected on the input side to the at least one sound receiver and on the output side to the sound generator. The transmission unit is designed to receive the microphone signal on the input side and to generate a power signal depending on the microphone signal received on the input side, which at least partially represents the microphone signal.

The sound generator is designed to receive the power signal on the input side and to generate a sound as a function of the power signal received on the input side, which corresponds to the power signal. The hearing aid also has an audio signal unit which is operatively connected to the sound generator and designed to generate an audio signal which has at least two audio signal sections immediately following one another in time.

The audio signal sections each have an audio signal section duration and the audio signal has at least one audible frequency for a human ear.

The audio signal portions follow each other so that an audio signal portion subsequent to a previous audio signal portion starts before the previous audio signal portion is terminated, so that the previous and subsequent audio signal portions overlap each other with an overlap period, the overlap period being smaller than the audio signal portion period of the previous audio signal section.

By temporally overlapping temporally consecutive audio signal sections are represented for example by the audio signal sections respectively Sounds perceived by a user of the hearing aid as pleasant. In fact, according to the invention, it has been recognized that each audio signal section has one end, wherein in particular a sudden termination of an audio signal section often represents a jump signal whose switch-off button can be perceived as unpleasant by a user of the hearing aid.
By overlapping the audio signal sections, such a sudden termination of a previous audio signal section advantageously does not occur. Temporal successive tones can be perceived as a melody.

In an advantageous embodiment of the hearing aid, the audio signal unit has an input for an event signal and is designed to generate the audio signal in dependence on the event signal. The event signal can be generated by the hearing aid, for example, when a battery charge of a connected battery falls below a predetermined value. The audio signal may represent, for example, a warning signal in this embodiment.

Preferably, an event signal may be generated by the hearing aid in response to a user interaction signal as confirmation of user interaction.

In a preferred embodiment of the hearing aid, the audio signal section has an end section, wherein an amplitude envelope of the end section has a falling amplitude profile.

A sound decaying with a falling amplitude envelope or another sound represented by an audio signal section is thereby advantageously perceived as pleasant by a user of the hearing aid, as the sound or noise gradually fades away. For example, an audio signal section may be a played sound of a musical instrument, in particular a piano, a harpsichord or represent a sound produced by plucking a guitar page.

In this embodiment, a gradual decay of an amplitude envelope is perceived as pleasant.

In a preferred embodiment, the amplitude envelope of the end section exhibits an exponentially decreasing amplitude profile.

In a preferred embodiment of the hearing aid, the overlap period is shorter than the end section of the previous audio signal section. For example, if a previous audio signal section represents a pitched sound produced by a piano, it is perceived by a user of the hearing aid as pleasant when a subsequent audio signal section, which also represents a different sound generated by a piano, the second sound during a Ausklingphase of the first struck sound begins.
Of course, an audio signal section may also represent other tones:
Thus, for example, notes produced by percussion instruments, in particular a metallophone tone, a xylophone tone, a gong tone, a bell sound, a sound produced by a string instrument, a sound produced by a wind instrument or a sound produced by a synthesizer are conceivable.

Thus, for example, temporally immediately successive audio signal sections can each represent a sound with mutually different pitches, so that the audio signal represents a melody.

In a preferred embodiment, the audio signal section has an initial section, wherein an amplitude envelope of the initial section has a particularly linearly increasing amplitude profile. This way you can Advantageously, a natural sound impression of a sound played by an instrument are generated.

In a further preferred embodiment, the audio signal section has a constant section with a time-constant course of an amplitude envelope.
As a result, an undamped oscillation of a sound can advantageously be generated.

In an advantageous embodiment, the audio signal section represents a sound having a predetermined fundamental frequency. More preferably, the audio signal portion represents a plurality of harmonics of the sound having the predetermined fundamental frequency. In this way, advantageously, a sound character of a sound can be generated.

In a preferred embodiment, the audio signal section represents one of at least one musical instrument or a sound produced by a human voice. For example, an audio signal section may represent a two-part, three-part, or a polyphony-generated sound.

In an advantageous embodiment of the hearing aid, the audio signal unit has at least two tone signal generators, which are each designed to generate at least one audio signal section.

More preferably, the audio signal unit is designed to control the at least two tone signal generators alternately to each other and thus to generate the audio signal.

In this way, an audio signal can advantageously be generated by a space-saving and cost-effective manner.

More preferably, the audio signal unit is designed to generate the audio signal section by means of frequency modulation synthesis.

In this way, a sound-saving sound can advantageously be generated saving space, which represents, for example, a sound of a musical instrument. A memory requirement for a sound thus held may advantageously amount to one-tenth of a memory requirement for a sample formed of samples.

In another embodiment, the hearing aid has a memory for at least one audio signal section, wherein the audio signal section is formed from samples which each represent an audio signal amplitude value of the audio signal section at a sampling instant.

In this way, an audio signal section can represent almost any sounds or noises.

The invention also relates to a method for generating an audio signal by means of a hearing aid, wherein the audio signal comprises at least two audio signal sections and represents at least one frequency perceptible by a human ear.

• Erzeugen eines Audiosignalabschnitts mit einer vorbestimmten Audiosignalabschnittszeitdauer;
• Erzeugen eines zeitlich folgenden Audiosignalabschnitts, wobei der folgende Audiosignalabschnitt beginnt bevor der Audiosignalabschnitt beendet ist;
• Erzeugen des Audiosignals aus den Audiosignalabschnitten.

The method comprises the steps:

• Generating an audio signal section having a predetermined audio signal section period;
• Generating a temporally following audio signal section, wherein the subsequent audio signal section starts before the audio signal section is completed;
• Generating the audio signal from the audio signal sections.

Further advantageous embodiments of the invention will become apparent from the features described in the dependent claims or a combination thereof.

Figur 1

zeigt schematisch ein Ausführungsbeispiel für einen Audiosignalabschnitt;

Figur 2

zeigt schematisch ein Ausführungsbeispiel für Audiosignal;

Figur 3

zeigt schematisch eine Schaltungsanordnung für eine Hörhilfe mit zwei miteinander verbundenen Tonsignalgeneratoren, welche jeweils Bestandteil einer Audiosignaleinheit der Hörhilfe sind.

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

FIG. 1

schematically shows an embodiment for an audio signal section;

FIG. 2

shows schematically an embodiment for audio signal;

FIG. 3

schematically shows a circuit arrangement for a hearing aid with two interconnected Tonsignalgeneratoren, each of which is part of an audio signal unit of the hearing aid.

FIG. 1 shows schematically a diagram 1. The diagram 1 shows a graph 7 which represents an amplitude envelope of an audio signal section. In this embodiment, the audio signal section has four mutually different phases, namely an attack phase, a decay phase, a sustain phase and a release phase.

The diagram 1 has an abscissa 3 and an ordinate 5. On the abscissa 3, a time is plotted and on the ordinate 5, an audio signal amplitude is plotted.

On the abscissa 3 time periods 9, 11, 13 and 15 are marked. The period 9 represents a rising phase of the audio signal portion. The time section 11 represents a decay phase of the audio signal section. The time section 13 represents a holding phase of the audio signal section. The time section 15 represents a decay phase of the audio signal section in which the profile of the amplitude envelope drops.

Figure 2 shows schematically diagram 2, in which three temporal signal amplitude curves are shown. Illustrated are audio signal sections generated by a first audio signal generator 17, audio signal sections 19 generated by a second tone signal generator and an audio signal 20 formed of the audio signal sections 17 and 19.

The diagram 2 has an abscissa 4 and an ordinate 6, wherein the abscissa 4 represents a time course and the ordinate 6 for the audio signal sections 17 and 19 and for the audio signal 20 each represent signal amplitude values.

On the abscissa 4, the time history is plotted in samples, the time course comprising 40,000 samples. The audio signal sections 19 generated by the second tone signal generator are formed of an audio signal section which extends between a sample value 0 and a sample value 15,000. An end section of the audio signal section with a decreasing amplitude curve extends between a sample value 10,000 and the sample value 15,000, this end section corresponding to the time segment 15 shown in FIG. 1 with a decreasing profile of the amplitude envelope.

At the time of the sample 10,000, an audio signal portion of the audio signal portions 17 generated by the first tone generator starts and extends to a sample value of 25,000.

At sample 20,000, an audio signal portion generated by the second tone generator and extending to a sample 35,000 begins. At the time of sample 30,000, an audio signal portion generated by the first tone generator starts.

The audio signal 20 represents a sum signal which is generated by summing the audio signal section 17 generated by the first sound signal generator and the audio signal section 19 generated by the second sound signal generator.

Immediately successive audio signal sections of the audio signal 20 are respectively generated alternately by the first and the second tone signal generator.

The audio signal sections may respectively represent sounds generated by a musical instrument to form a melody. The audio signal 20 can thus represent the melody, comprising four tones in this embodiment.

FIG. 3 schematically shows an exemplary embodiment of a hearing aid with two audio signal generators connected to one another, which can each be part of an audio signal unit and which are provided for generating an audio signal, for example of the audio signal 20 shown in FIG.

A hearing aid circuit arrangement 21 shown in FIG. 3 has a first tone signal generator 22 and a second tone signal generator 24. The tone signal generator 22 has a trigger input 34, a frequency input 36 and a level input 38. The second tone signal generator 24 has a trigger input 40, a frequency input 42 and a level input 44.

The first tone signal generator 22 has a signal output 50, and the second tone signal generator 24 has a signal output 51. The tone signal generators 22 and 24 are each designed to generate an audio signal section in response to a trigger signal received on the input side, which has at least one frequency perceptible by a human ear. The audio signal section has an amplitude envelope, which may have a temporal amplitude curve in accordance with the curve 7 shown in FIG.

The tone signal generators 22 and 24 are each designed to generate the audio signal section at a fundamental frequency, wherein the fundamental frequency in each case depends on a frequency input side received control signal.

The tone signal generators 22 and 24 are thus designed to generate a fundamental frequency of the generated audio signal section as a function of a control signal received on the input side. For example, it is further advantageous to generate additional harmonics from the tone signal generators 22 and 24 as a function of the control signal.

The tone signal generator 22 is configured to generate a volume level of the audio signal portion in response to a level signal received on the input side. The level signal can be received at the level input 38. The tone signal generator 24 is designed in accordance with the tone signal generator 22 and can receive a level signal on the input side via the level input 44.

The tone signal generators 22 and 24 are each connected on the output side to a summation element 47. The summing element 47 is connected on the input side to the signal output 50 and the signal output 51 and connected on the output side to an output 32 of the circuit arrangement 21. The summing element 47 is designed to add signals received on the input side to one another and thus to form a summation signal and output this on the output side.

The circuit arrangement 21 has a flip-flop circuit which is formed by a selection element 46, an AND element 48, an AND element 49 and a NOT element 52. The trigger circuit has a trigger input 26, which forms a trigger input of the circuit arrangement 21.

The AND gate 48 is connected on the output side to the trigger input 40 of the second tone signal generator 24. The AND gate 49 is connected on the output side to the trigger input 34 of the first tone signal generator 22. A first input of the AND gate 48 is connected to the trigger input 26 and a first input of the AND gate 49 is connected to the trigger input 26.

The selector 46 has a signal input u, a reset input R and an input IC for an initial condition. The selector 46 has a transfer function corresponding to a time delay.

The reset input of the selector 46 is connected to the trigger input 26. The selection element 46 is fed back on the output side to the signal input u and on the output side to an input of the NOT element 52 and to a second input of the AND element 48. The NOT element 52 is connected on the output side to the input for an initial condition of the selection element 46 and to a second input of the AND element 49.

By the feedback of the selection member 46, a holding member is formed. For example, if a trigger signal is present at the trigger input 26, the selection element 46 is reset via the reset input and generates a logically positive output signal, which is maintained by the feedback.

The output signal is now on the input side to the NOT element 52 and to the second input of the AND gate 48 at. The NOT element 52 generates on the output side a logically negative signal which is applied to the second input of the AND gate 49. At the first inputs of the AND gates 48 and 49 is in each case the - logically positive - trigger signal of the trigger input 26. In this way, a switching condition of the AND gate 48 is given and an output signal of the AND gate 48 may form a trigger signal for the second tone signal generator 24, which is applied to the trigger input 40.

Upon a repeated application of a logic positive trigger signal to the trigger input 26, the selector 46 reset, wherein the initial condition, controlled by the input IC, is logically negative. In this way, a logically negative output signal is generated, which is maintained by the feedback via the signal input u. The logically negative output signal is now present at the input side of the NOT element 52 and at the second input of the AND gate 48th

The AND gate 48 is now the input side by the NOT element 52 logically positive and controlled by the logic negative output logic negative and therefore goes into a blocking state.

On the AND gate 49 are on the input side two logically positive signals, so that the AND gate 49 generates an output signal which is applied to the trigger input 34 of the tone signal generator 22 and thus can form a trigger signal for the tone signal generator 22.

The tone signal generator 22 can now - triggered by the trigger signal thus generated - generate an audio signal section and output this output side via the output 50.

In this way, by the previously described flip-flop circuit by the tone signal generators 22 and 24 - each alternating - an audio signal formed from audio signal sections are generated.

The circuit arrangement 21 also has a frequency input 28 and a level input 30. The frequency input 28 is connected to the frequency input 36 and the first tone signal generator 22 and to the frequency input 42 of the second tone signal generator 24.

The level input 30 is connected to the level input 38 of the first tone signal generator 22 and to the level input 44 of the second tone signal generator 24. In this way, the tone signal generators 22 and 24 respectively in the case of a drive generate by means of a trigger signal an audio signal section with a fundamental frequency which corresponds to an input side of the frequency input 28 of the circuit 21 adjacent frequency signal.

An output level - and thus a volume of the generated audio signal section - can be controlled via the level inputs 38 and 44, so that an output level and thus a maximum amplitude of the respectively generated audio signal section corresponds to a level signal applied to the level input 30.

The circuit arrangement 21 also has a control unit 54 and a melody generator 56, which has an input 66 for an event signal and is connected on the input side to the control unit 54. The melody generator is connected on the output side to the frequency input 28 and to the trigger input 26. The melody generator 56 may keep at least one melody data set 58 representing a melody and decode it in response to an event signal received on the input side, and generate and output to the output side corresponding frequency signals for generating respective audio signal portions.

The melody generator 56 can generate a trigger signal for each audio signal section to be generated and output this to the trigger input 26. The circuit arrangement also comprises a transmission unit 60, a sound receiver 62 and a sound generator 64, which are each connected to the transmission unit 60. The operation of the transmission unit 60, the sound generator 64 and the sound receiver 62 is as already described above. The transmission unit 60 is connected on the input side to the output 32 and can generate a power signal which corresponds to an audio signal received by the output 32 and outputs this to the sound generator 64.

Claims (12)

Hearing aid (21) having at least one sound receiver (62) and a sound generator (64),
wherein the at least one sound receiver (62) is adapted to receive sound waves and to generate a microphone signal representing the received sound waves,
and with a transmission unit (60), which on the input side to the at least one sound receiver (62) and the output connected to the sound generator (64) and wherein the transmission unit (60) is adapted to receive the microphone signal on the input side and in response to the microphone signal received on the input side generate a power signal which at least partially represents the microphone signal,
and the sound generator (64) is adapted to receive the power signal on the input side and to generate a sound in dependence on the input-side received power signal which corresponds to the power signal,
characterized in that
the hearing aid has an audio signal unit (56, 22, 24) which is operatively connected to the sound generator (64) and designed to generate an audio signal (20) having at least two immediately consecutive audio signal sections (7, 17, 19),
wherein the audio signal sections (7, 17, 19) each have an audio signal section period,
and the audio signal (20) has at least one audible frequency for a human ear,
and the audio signal sections (7, 17, 19) succeed each other such that an audio signal section (7, 19) subsequent to a previous audio signal section (7, 17) starts before the previous audio signal section (7, 17) is finished, so that the previous one and the following audio signal section (7, 17, 19) overlap each other with an overlap period, wherein the overlap period is smaller than the audio signal section period of the previous audio signal section (7, 17). Hearing aid according to claim 1, characterized in that the audio signal unit has an input for an event signal and is adapted to generate the audio signal (7, 17, 19) in response to the event signal. Hearing aid according to claim 1 or 2, characterized in that the audio signal section has an end portion (15), wherein an amplitude envelope (7) of the end portion (15) has a falling amplitude characteristic. Hearing aid according to one of the preceding claims, characterized in that the audio signal section has an initial section (9), wherein an amplitude envelope (7) of the initial section (9) has an increasing amplitude profile. Hearing aid according to one of the preceding claims, characterized in that the audio signal section has a constant section (13) with a time-constant course of an amplitude envelope (7). Hearing aid according to one of the preceding claims, characterized in that the audio signal section (7, 17, 19) represents a sound having a predetermined fundamental frequency. Hearing aid according to claim 6, characterized in that the audio signal section (7, 17, 19) represents a plurality of harmonics of the sound at the predetermined fundamental frequency. Hearing aid according to one of the preceding claims, characterized in that the audio signal section (7, 17, 19) represents a sound generated by at least one musical instrument. Hearing aid according to one of the preceding claims, characterized in that the audio signal unit (21) has at least two tone signal generators (22, 24) which are each designed to generate at least one audio signal section (7, 17, 19). Hearing aid according to one of claims 6 to 9, characterized in that the audio signal section (7, 17, 19) is generated by means of frequency modulation synthesis. Hearing aid according to one of claims 1 to 8, characterized in that the hearing aid has a memory for at least one audio signal portion, wherein the audio signal portion is formed of samples, each representing an audio signal amplitude value of the audio signal portion at a sampling time. A method for generating an audio signal by means of a hearing aid, wherein the audio signal comprises at least two audio signal sections and represents at least one frequency perceptible by a human ear, comprising the steps: Generating an audio signal section having a predetermined audio signal section period; Generating a temporally following audio signal section, wherein the following audio signal section starts before the audio signal section is completed. - generating the audio signal from the audio signal sections.

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