Receiver system and method for transmitting information for an otological device

The invention relates to a receiver system for an otological device. The receiver system has an oscillation receiver to receive a carrier signal with a carrier frequency. The receiver system is designed to change a receive frequency for the carrier signal. The receiver system has a frequency regulator which is designed to at least indirectly register the receive frequency and to change the receive frequency for the carrier signal to a predetermined receive frequency and to set it to the predetermined receive frequency. The frequency regulator is connected to the oscillation receiver at least at least indirectly and is designed to generate an excitation signal and to excite the oscillation receiver to oscillate by means of the excitation signal and thus to generate a response oscillation with a response frequency. The frequency regulator is also designed to ascertain the receive frequency depending on the response oscillation.

FIELD OF THE INVENTION

The invention relates to a receiver system for an otological device for transmitting information.

BACKGROUND OF THE INVENTION

With regard to receiver systems for transmitting information to an otological device, particularly a hearing aid, for example by means of an accessory part, particularly a remote control, a programming unit or a comparable device, or from the otological device to another otological device or an accessory part, for example a remote control or a programming unit, correct tuning of a resonant frequency for an oscillation receiver of the receiver system is required since incorrect tuning of the resonant frequency has a major influence on a transmission quality or on an achievable transmission range. Normally, a frequency response of a receiver system has a bandpass characteristic with a center frequency, whereby the center frequency should be set as precisely as possible at a receive frequency provided for transmission purposes. A receive frequency for such a receiver is essentially determined by frequency determining components such as coils, capacitors or components connected thereto. Such components can exhibit tolerances of a predefined component value, which means that an initial tuning is necessary in order to specify a receive frequency. Furthermore, temperature- and ageing-related changes in the frequency determining components can render necessary a retuning.

With regard to radio receivers known from the prior art, a receive frequency can be tuned manually by a user. In addition, quartz-stabilized PLL receivers for example are known which require no retuning of a receive frequency (PLL=phase locked loop).

A quadrature modulation receiver is known from JP10013191A2 which is designed to change, and thus to retune, a receive frequency of the receiver circuit depending on a signal strength of a receiver circuit.

A PLL receiver, described above, can for example only be used with difficulty, or not at all, in otological devices, particularly hearing aids or in an accessory for hearing aids on account of a space requirement or a power consumption.

SUMMARY OF THE INVENTION

The invention is thus based on the problem of tuning or retuning a receive frequency of a receiver by using the simplest possible means.

This problem is solved by a receiver system for an otological device, which is provided for transmitting information.

The receiver system can for example form part of a sender/receiver system, particularly a transceiver.

The receiver system has an oscillation receiver, whereby the oscillation receiver is designed to receive a carrier signal with a carrier frequency. The receiver system is designed to change a receive frequency for the carrier signal. The receiver system has a frequency regulator which is designed to at least indirectly register the receive frequency and to change the receive frequency for the carrier signal to a predefined receive frequency and to set it to the predefined receive frequency.

The frequency regulator is connected to the oscillation receiver at least indirectly and is designed to generate an excitation signal and to excite the oscillation receiver to oscillate by means of the excitation signal and thus to generate a response oscillation with a response frequency. The frequency regulator is also designed to ascertain the receive frequency depending on the response oscillation.

In this manner, it is advantageously possible to register a natural frequency of a receiver system, for example of an oscillating circuit of a receiver system.

In a preferred embodiment, the excitation signal is a feedback signal generated in the oscillation receiver. In this embodiment, the frequency regulator is designed to feed back the oscillation receiver at least indirectly.

By means of such a feedback process, a receiving circuit of a receiver is excited to generate a natural oscillation with a natural frequency. The frequency regulator can advantageously ascertain the receive frequency depending on this natural frequency generated by a feedback process. The natural oscillation thus constitutes the response oscillation.

In a preferred embodiment, the frequency regulator is designed to ascertain the receive frequency depending on the response frequency in accordance with a predefined assignment rule. For example, a predefined assignment rule can be implemented by means of a stored look-up table, whereby one receive frequency is assigned in each case to a plurality of response frequencies.

By this means it is advantageously possible to take into consideration a frequency offset between a natural frequency generated by a feedback process and a receive frequency.

The embodiment described above is based on the knowledge that there is a relationship between natural frequency generated by a feedback process and a receive frequency of a resonant circuit, which for example can be represented by a predefined assignment rule. The frequency regulator can thus for example ascertain the receive frequency in accordance with a predefined assignment rule depending on the response frequency generated by a feedback process.

In another preferred embodiment of the receiver system, the excitation signal is a pulse signal limited in time or a step signal. This is based on the knowledge that a pulse signal as an approximation to a Dirac delta impulse can contain all the frequencies in the frequency slice from minus infinity to plus infinity and can thus excite a receiver, particularly an oscillating circuit of a receiver with all frequencies. In a preferred embodiment, the pulse signal exhibits a plurality of frequencies within a frequency slice. The pulse signal can for example be constituted by a signal with a predefined bandwidth.

In another embodiment, the excitation signal is constituted by a step signal, whereby the step signal exhibits an amplitude timing curve with a time-dependent amplitude rise. The frequency content of such a step signal is dependent on the rise of the amplitude curve.

An excitation signal can advantageously represent noise, particularly white noise. White noise contains all the frequencies of a frequency slice at the same energy level in each case.

A frequency content of such an excitation signal can be registered for example by means of a Fourier transform.

In a preferred embodiment, the receiver system, particularly the oscillation receiver of the receiver system, is operatively connected to an oscillation sender for the transmission of information, whereby the oscillation sender is designed to generate the excitation signal.

In this embodiment, a sender of a transceiver can advantageously be used in order to generate the excitation signal.

In an advantageous embodiment, the oscillation receiver and the oscillation sender are each constituted at least partially by common parts. For example, a resonant circuit, particularly an inductance, particularly a coil, can be used both as a sending coil and also as a receiving coil.

In a preferred embodiment, the frequency regulator is designed to sample at least one period of the response oscillation and to register zero transitions within the period of the response oscillation and to ascertain the response frequency of the response oscillation depending on the registered zero transitions.

For example, the frequency regulator is designed to sample the at least one period of the response oscillation with at least twice the response frequency. By further preference, the frequency regulator is designed to sample the at least one period of the response oscillation with five times or ten times the response frequency.

A frequency regulator can thus register a response frequency in a simple manner. The frequency regulator can for example have a frequency divider which is designed to divide the number of registered zero transitions in accordance with a predefined division ratio.

In an advantageous embodiment, the frequency regulator is designed to add at least two periods of a response oscillation to one another or to duplicate a registered period of the response oscillation and add a duplication result formed in this way and the registered period of the response oscillation to one another.

The zero transitions contained in the addition result can then be registered.

In this manner, the frequency regulator can advantageously reduce statistical noise in a response signal.

This is particularly advantageous in a situation when the quality of a receiver system, particularly the quality of an oscillating circuit of a receiver system is low and on account of the low quality a decay over time of the response oscillation is brief.

The invention also relates to a method, particularly for an otological device, for receiving a carrier signal with a carrier signal frequency and regulating a receive frequency for receiving the carrier signal.

With regard to the method, the receive frequency is registered at least indirectly and the receive frequency, which is provided for receiving a carrier signal, is changed to a predetermined receive frequency. In addition, an excitation signal is generated and the excitation signal is used to excite an oscillation receiver to oscillate. In this manner, a response oscillation with a response frequency is generated. The receive frequency is ascertained depending on the response oscillation and is set to the predetermined receive frequency in a further step.

The excitation signal in the method described above can advantageously be generated by a feedback process of the oscillation receiver.

The excitation signal in the method described above can in another embodiment be a pulse signal limited in time or a step signal.

Further advantageous embodiments for a receiver system or for a method result from the features described in the dependent claims or from a combination of the features described in the dependent claims.

DETAILED DESCRIPTION OF THE INVENTION

FIG. 1schematically illustrates an embodiment of a receiver system1. The receiver system1has an oscillating circuit3. The oscillating circuit3has an inductance5and a frequency setting element7.

The frequency setting element7can for example be constituted by a voltage-dependent capacitance, particularly a variable capacitance diode.

The inductance5and the frequency setting element7are incorporated serially in each case into the oscillating circuit3.

The receiver system1also has a regulator9.

The regulator9is designed to receive a response frequency on the input side and to compare this with a predetermined frequency. The regulator9is designed, depending on a difference formed from the response frequency and the predetermined receive frequency, to generate a control signal for controlling the frequency setting element7and to output this on the output side.

The receiver system1also has an A/D converter16operatively connected to the oscillating circuit3, said A/D converter being designed to sample a response signal received on the input side, representing for example a response oscillation, and to generate a sampled signal and to output this on the output side.

The receiver system1also has a zero transition counter12which is designed to ascertain zero transitions in a sampled signal received on the input side and to generate an output signal which represents the number of zero transitions ascertained, particularly the number of zero transitions ascertained within a time interval. The output signal from the zero transition counter12can thus represent a zero transition frequency.

The A/D converter16can for example be a 1-bit A/D converter.

The receiver system1also has a timer14which can for example have an oscillating crystal. The timer14is connected on the output side by way of a connecting line38to the zero transition counter12and can thus make available a time base for the zero transition counter12. The timer14is also connected to the A/D converter16by way of a connecting line40and can thus constitute a time base for the A/D converter16.

The receiver system1also has a memory10for a predetermined receive frequency. The regulator9is connected on the input side by way of a connecting line36to the memory10and is designed to read the predetermined receive frequency out of the memory10. The regulator9is connected on the output side by way of a connecting line46to the frequency setting element7. The regulator9can output the control signal provided for setting the frequency setting element7on the output side by way of the connecting line46and send it to the frequency setting element7.

The oscillating circuit3is connected by way of a connection node25to an antenna27. The antenna27can be a receiving antenna for a magnetic field or an electromagnetic field. In this embodiment, the antenna can receive a transmitted signal60and feed this by way of the connection node25into the oscillating circuit3.

The transmitted signal60can represent information for an otological device, particularly a hearing aid or an accessory part, for example a remote control. Otherwise, the transmitted signal can for example represent data or a data record, whereby the data or the data record represents the information.

The receiver system1also has a pulse generator18which is designed to generate an excitation signal for generating a response oscillation, depending on a control signal received on the input side, and to output this on the output side. In this embodiment, the excitation signal is formed by a square pulse.

The pulse generator18is connected on the output side by way of a connecting line48to an excitation coil22.

For this purpose, the excitation coil22can be located adjacent to the inductance5such that a magnetic field generated by the excitation coil22by means of an excitation signal sent to the excitation coil22can be received by the inductance5and can there induce a corresponding current. The excitation coil22and the inductance5can be coupled magnetically to one another.

The oscillating circuit3is connected by way of a connection node23and a connecting line52to a connection node32. The A/D converter16is connected by way of a connecting line53to the connection node32. The A/D converter16is thus operatively connected to the oscillating circuit3. The connection node32is connected by way of a connecting line50to an output30for a demodulator. A demodulator of an otological device, particularly of a hearing aid, can for example be connected to the output30. Other than the output30represented in this figure, an output for a demodulator, particularly a digital demodulator, can be connected to the output of the A/D converter.

The A/D converter16is connected on the output side by way of a connecting line42to the zero transition counter12. The zero transition counter12is connected on the output side by way of a connecting line44to the regulator9.

The mode of operation of the receiver system1will now be described in the following:

In order to ascertain a receive frequency of the oscillating circuit3, the regulator9can generate a control signal intended for generating an excitation signal and send this control signal by way of connecting line58on the output side to the pulse generator18.

The pulse generator18can generate an excitation signal depending on the control signal received on the input side and send this on the output side by way of the connecting line48to the excitation coil22. The excitation coil22can generate a magnetic field corresponding to the excitation signal and couple this into the inductance5of the oscillating circuit3and generate a response oscillation there.

The energy thus fed in for the response oscillation can—by alternately generating inductive energy in the inductance5and capacitive energy in the frequency setting element7constituted by a voltage-dependent capacitance—be maintained in the oscillating circuit3, depending on the quality of the oscillating circuit3.

The response oscillation generated in this way will decay exponentially over the following course of time depending on the quality of the oscillating circuit3.

A response signal corresponding to the response oscillation can be received by the A/D converter16on the input side by way of the connection node23, the connecting line52, the connection node32and the connecting line53.

The A/D converter16can sample the response signal received on the input side and send a sampled response signal by way of the connecting line42to the zero transition counter12. A time signal generated by the timer14, which can serve as a time base, is available to the A/D converter16for sampling the response signal.

The zero transition counter12can, depending on the sampled response signal received on the input side, generate an output signal which represents a response frequency of the response oscillation.

In this embodiment, the response frequency registered by the zero transition counter12corresponds to twice the response frequency and thus to a receive frequency of the oscillating circuit3, assuming a sinusoidal response signal.

The regulator9can now receive the signal representing the response frequency by way of the connecting line44on the input side and form a difference from a response frequency corresponding to this signal and a predetermined receive frequency read out from the memory10.

In a further step, depending on the difference thus formed, the regulator9can generate a control signal in order to change a receive frequency and send this signal on the output side by way of the connecting line46to the frequency setting element7. Depending on the control signal received on the input side, the frequency setting element7can change a receive frequency of the oscillating circuit3and set it to such a changed value.

The regulator9can repeat the method described above for example until such time as a difference formed from the response frequency and the predetermined frequency is sufficiently small or the response frequency and the predetermined frequency stored in the memory10are identical to one another.

In another embodiment, the receiver system1has no excitation coil22. In this embodiment, the pulse generator18on the output side is connected by way of a connecting line49shown dashed to the connection node23and thus to the oscillating circuit3. The pulse generator18can in this manner feed an excitation signal directly into the oscillating circuit3.

In the case of an embodiment with the excitation coil22, the oscillating circuit3is advantageously electrically isolated from the pulse generator18.

Another embodiment is also conceivable in which the connecting line52can be connected to the excitation coil22by way of the connection node23instead of an electrical connection to the oscillating circuit3. In this manner, a response oscillation originating from the inductance5can be coupled by way of a magnetic field into the excitation coil22and indirectly generate a response signal there. The response signal thus indirectly generated can be available to the A/D converter16on the input side by way of the connection node32and the connecting line53.

FIG. 2schematically illustrates another embodiment of a receiver system2.

The receiver system2has an oscillating circuit3. The oscillating circuit3has an inductance5and a frequency setting element7.

The frequency setting element7can for example be constituted by a voltage-dependent capacitance, particularly a variable capacitance diode.

The inductance5and the frequency setting element7are incorporated serially in each case into the oscillating circuit3.

The receiver system2also has a regulator9.

The regulator9is designed to receive a response frequency on the input side and to compare this with a predetermined frequency. The regulator9is designed, depending on a difference formed from the response frequency and the predetermined receive frequency, to generate a control signal for controlling the frequency setting element7and to output this on the output side.

The receiver system2also has an A/D converter16operatively connected to the oscillating circuit3, said A/D converter being designed to sample a response signal received on the input side, representing for example a response oscillation, and to generate a sampled signal and to output this on the output side.

The receiver system2also has a zero transition counter12which is designed to ascertain zero transitions in a sampled signal received on the input side and to generate an output signal which represents the number of zero transitions ascertained, particularly the number of zero transitions ascertained within a time interval. The output signal from the zero transition counter12can thus represent a zero transition frequency.

The A/D converter16can for example be a 1-bit A/D converter.

The receiver system2also has a timer14which can for example have an oscillating crystal. The timer14is connected on the output side by way of a connecting line38to the zero transition counter12and can thus make available a time base for the zero transition counter12. The timer14is also connected to the A/D converter16by way of a connecting line40and can thus constitute a time base for the A/D converter16.

The receiver system2also has a memory10for a predetermined receive frequency. The regulator9is connected on the input side by way of a connecting line36to the memory10and is designed to read the predetermined receive frequency out of the memory10. The regulator9is connected on the output side by way of a connecting line46to the frequency setting element7. The regulator9can output the control signal provided for setting the frequency setting element7on the output side by way of the connecting line46and send it to the frequency setting element7.

The oscillating circuit3is connected by way of a connection node25to an antenna27. The antenna27can receive a transmitted signal60and feed this by way of the connection node25into the oscillating circuit3.

The oscillating circuit3of the receiver system2is connected by way of a connection node21and a connecting line51to a connection node24. The connection node24is connected by way of a connecting line56to the connection node32. The connection node24is also connected by way of a connecting line55to a feedback element20.

The feedback element20can for example be constituted by an amplifier. The feedback element20is connected on the output side by way of a connecting line54to a switch19, particularly an electronic switch for activating a response oscillation. The switch19is connected on the input side to the connecting line54and on the output side by way of a connecting line52and by way of a connection node35to the oscillating circuit3. The switch19, in order to actuate it, is connected by way of a connecting line59to the regulator9.

The mode of operation of the receiver system2will now be described in the following:

The regulator9can for example, in order to register a receive frequency of the oscillating circuit3, generate a control signal for generating a response oscillation and send this on the output side by way of the connecting line19to the switch19in order to actuate the latter. Depending on the control signal, the switch19can electrically connect the connecting line54and the connecting line52to one another. In this manner, the oscillating circuit3is fed back on itself by way of the connection node21, by way of the connecting line51, onward by way of the connection node24and the connecting line55, onward by way of the feedback element20, the connecting line54, the closed switch19, the connecting line52and finally by way of the connection node35. As a result of this feedback loop formed in said manner, a response oscillation can be generated in the form of a feedback oscillation.

The response oscillation thus formed exhibits a natural frequency which is different from a receive frequency of the oscillating circuit3. The response frequency of the response oscillation can be registered by way of the A/D converter16, the connecting line42, the zero transition counter12, the connecting line44—by analogy with the receiver system1described in FIG.1—by the regulator9on the input side.

In a following step, the regulator can, depending on a difference formed from the response frequency and a predetermined receive frequency stored in the memory10, generate a control signal for setting the frequency setting element7and sending this on the output side by way of the connecting line46to the frequency setting element7.

A frequency offset, formed by a difference between the response frequency and twice a receive frequency of the oscillating circuit3, can for example be taken into account by the regulator9, or have already been taken into account by the fact that the predetermined frequency value stored in the memory10already represents such a frequency offset.

Alternatively, a response frequency can be halved and thus—for example in accordance with a predefined assignment rule, particularly in accordance with a look-up table—a frequency doubling caused by registration of the zero transitions can be taken into account.