This application is the US National Stage of International Application No. PCT/EP2007/057670, filed Jul. 25, 2007 and claims the benefit thereof. The International Application claims the benefits of German application No. 10 2006 035 126.6 DE filed Jul. 28, 2006, both of the applications are incorporated by reference herein in their entirety.
The invention relates to a method for the transfer of data via a wireless connection between a hearing aid and an external programming device. In addition to a receiving mode, the hearing aid also has a standby mode in which the energy consumption of the hearing aid is significantly reduced.
In addition to an interface for a wired connection to an external control device, modern hearing aids also have a transmitting/receiving device for the wireless connection of the hearing aid to the external control device. Within the scope of wireless programming, the hearing aid can also receive programming data from an external programming device via a radio link of this kind. This also permits wireless binaural coupling of hearing aids with which the two hearing aids can be coupled together in such a way that they work as an integrated unit and functions such as volume or program selection are synchronized between the two hearing aids. However, a hearing aid with an integrated receiving device for the wireless reception must be expected to have a higher power consumption. Since, as rule, the hearing aid only has access to its internal power supply, the wireless data transfer inevitably results in a reduced operating time and hence in more frequent battery changes. For this reason, it is desirable to keep the additional power consumption caused by the receiving device as low as possible. In addition, with the wireless programming of hearing aids, it is necessary to prevent illegal programming accesses and possibly to work at a higher data rate than that used in normal operation.
Since with known systems designed for wireless binaural coupling, the receiving device is permanently activated, resulting however in a relatively high power consumption by the hearing aid, at present, conventional hearing aids are still programmed via a cable connection.
It is the object of the invention, on the basis of this prior art, to provide a method for wireless data transfer between a hearing aid and another device by means of which the energy consumption of the hearing aid in operation can be reduced. This object is achieved by a method with the features of the independent claims. Further advantageous embodiments of the invention are disclosed in the dependent claims.
According to the invention, a method for wireless data transfer between a hearing aid and an external device is provided with which the hearing aid receives, by means of an internal receiving device, data sent from the external device via a wireless connection. It is provided that the hearing aid switches to a receiving mode as soon as data is sent from the external device via the wireless connection, wherein the receiving device in the receiving mode is permanently switched on for the reception of data. In addition, the hearing aid switches to a standby mode when no data are sent from the external device via the wireless connection. In this standby mode, the receiving device is alternately switched on and off in order to detect the start of a data transfer from the external device. Since the receiving device in the standby mode only is only operated temporarily, the power consumption of the hearing aid can be significantly reduced by the use of the standby mode.
In an advantageous embodiment of the invention, the hearing aid changes to the receiving mode as soon as, during a switched-on phase of the standby mode, the receiving device detects the start of a data transfer from the external device via the wireless connection. Since the hearing aid in the standby mode so-to-speak repeatedly “sniffles” into the transfer channel, it is able to recognize the start of a data transfer relatively quickly and change to the receiving mode without any great delay.
A further advantageous embodiment of the invention provides that the hearing aid changes to the standby mode as soon as the receiving device in the receiving mode registers no data transfer from the external device via the wireless connection for a prespecified time. This measure enables it to be ensured that the hearing aid does not remain in the receiving mode for an unnecessarily long time. The enables further energy saving by the hearing aid.
A further advantageous embodiment of the invention provides that the receiving device in the standby mode is periodically switched on and off again, wherein the duration of the switched-on and switched-off phases is selected so that the start of a data transfer from the external device can be detected. The duration of the switched-on and switched-off phases determines the pulse duty ratio with which the hearing aid samples the transfer channel for monitoring purposes. The determination of the duration of this time enables the pulse duty ratio and hence the energy saving to be adapted to the respective requirements.
In a particularly advantageous embodiment of the invention, the external device sends an activation signal to the hearing aid via the wireless connection in order to indicate to the hearing aid the start of a new data transfer. An activation signal preceding the actual data transfer makes it possible to ensure that the hearing aid is already activated when the actual data transfer starts. Since, in this case, the hearing aid is able to receive all the data and no data have to be repeated, this measure results in a higher data transfer rate.
A further advantageous embodiment of the invention provides that the duration of the activation signal is selected so that it exceeds the duration of a switched-off phase of the receiving device 11 in the standby mode of the hearing aid.
This ensures that the activation signal at least partially coincides with a switched-on phase. This has the advantage that it increases the probability of the activation signal being detected by the hearing aid.
A further advantageous embodiment of the invention provides that the activation signal comprises an activation message and a redundant preamble. The duration of the redundant preamble is hereby selected so that the total duration of the activation signal exceeds the duration of a switched-off phase of the receiving device in the standby mode of the hearing aid. This ensures that the hearing aid can receive at least a part of the activation signal in a switched-on phase. Since the preamble is sent before the actual activation message, the hearing aid is able to suppress the subsequent switched-off phases until it has received the actual activation message.
In addition, according to a further advantageous embodiment of the invention, the activation message in the activation signal can be repeated until the total duration of the activation signal exceeds the duration of the switched-off phase of the receiving device in the standby mode of the hearing aid. This alternative also increases the probability of the hearing aid receiving the actual activation message correctly.
A particularly advantageous embodiment of the invention provides that the external device uses a specific modulation method in order to indicate the start of a new data transfer. The hearing aid switches to the receiving mode as soon as it detects that the external device is transferring its data signals by means of the specific modulation method.
Hereby, it is advantageous that a specific modulation method can be identified much more quickly than a corresponding activation message, which possibly can only be received complete. It is also possible to reduce the risk of an inadvertent change to the receiving mode when the special modulation method is only used for data transfer. It is advantageous for the hearing aid to change to the receiving mode as soon as the hearing aid detects that the external device is transferring data signals by means of a specific phase or frequency modulation method.
In a further advantageous embodiment of the invention, the data transfer takes place within the scope of wireless programming of the hearing device, wherein the hearing aid in a special programming mode receives programming data in a wireless manner from an external device serving as a control device. Hereby, it is provided that the hearing aid changes to the programming mode as soon as it receives a special command from the control device via the wireless connection. Programming data sent by the control device outside of the programming mode via the wireless connection to the hearing aid are ignored by the hearing aid. Hereby, it is provided that the hearing aid in the programming mode prevents the change to the standby mode. This has the advantage that the connection does not have to be repeatedly reactivated which would result in delays and hence in lower data rates. In addition, it is also ensured that the hearing aid receives all of the programming data correctly. However, hereby it is also advantageous for the hearing aid in the programming mode automatically to change to the receiving mode or the standby mode programming mode after the expiry of a prespecified time. The choice of a suitably long time can ensure that the risk of an interruption to the programming is minimized. Simultaneously, it is possible to ensure that the hearing aid is not incorrectly programmed by data which it inadvertently receives outside of the programming mode.
In addition, in a further embodiment of the invention, the hearing aid can prevent the automatic change from the programming mode to the receiving mode or the standby mode if a new programming access via the wireless connection takes place within the prespecified time. This is advantageous, since it enables unnecessary interruptions of the programming to be prevented.
Finally, in a further advantageous embodiment of the invention, it is provided that the hearing aid in the programming mode resets the time for the automatic change of operating mode if a new programming access takes place or when the hearing aid receives an audio data flow. This measure also means the unnecessary interruption of the programming of the hearing aid can be prevented.
The following describes the invention in more detail with reference to drawings which show:
In addition to the receiving device 11, the hearing aid 10 also has further circuits 12, such as, for example, control circuits and signal processing circuits. Since these circuits are of no relevance for understanding the invention, they are shown as schematically summarized in
As a rule, during operation, the only power supply for the hearing aid 10 is its internal battery. Due to its small dimensions, the housing of the hearing aid 10 can only accommodate a relatively small battery. Due to the relatively small battery, the service life of the hearing aid is already greatly restricted in normal operation. In addition, the wireless data reception places a great load on the power supply of the hearing aid 10. The concept according to the invention should achieve a significant power saving in the hearing aid 10.
The following explains the procedure on the change of the different operating modes with reference to
In addition, the time interval Δt, after which the hearing aid 10 switches to the standby mode as long as it is no longer receiving any further data, should be selected so that short transmission pauses, which can typically occur during the communication between the hearing aid 10 and the external device 20, do not result in a change of the operating modes. This is because over-frequent changes of operating mode and the associated reactivation procedures of the receiving device could result in delays in the data transfer and consequently in an unwanted reduction of the data rate.
According to the invention, the hearing aid 10 should switch back to the receiving mode as soon as it has registered the start of a data transfer in the standby mode. A change of operating mode of this kind is shown in the pair of diagrams c) and d) in
As shown in the two diagrams c) and d), in the present example, the activation signal is more than twice as long as the switched-off time of the receiving device 11 in the standby mode. In a switched-on phase, the hearing aid 10 can therefore unambiguously detect the start of a data transfer by the external device 20. At time t3, the hearing aid 10 therefore changes to the receiving mode in order to receive the actual data then sent from the external device 20.
Whether, after the reception of an activation signal following the prespecified switched-on and switched-off sequence in the standby mode, the hearing aid 10 switches its receiving device 11 off again before it changes to the receiving mode, depends in the first instance on the processing speed in the hearing aid 10. In principle, it is advantageous for the hearing aid 10 to suppress the switched-off cycle in the standby mode as long as it is receiving the activation message but no change of operating mode has taken place. Diagram c) in
In order to indicate the start of a new data transfer to its communication partner, the external device 20 can in principle start the data transfer without waiting for the reactivation of the hearing aid 10. As soon as the hearing aid 10 has changed to the receiving mode, the external device 20 sends the data already sent to the hearing aid 10 again in order to ensure that now all the data has been correctly received by the hearing aid 10. Multiple transmissions of this kind are used inter alia also to avoid errors with disrupted data transmission, in particular if there is no reverse channel. However, this approach involves a risk that the hearing aid 10 is unable to detect unambiguously whether the data currently being received is actually the data which it is to utilize or whether these data are still serving to activate the receiving mode and will then be sent once again during the actual data transfer. A faulty interpretation of the data by the hearing aid 10 could in principle result in reception errors. It is therefore advantageous for the external device 20 to use a special activation signal to activate the receiving mode of the hearing aid 10. This activation signal can contain a special activation message and in addition redundant parts such as, for example, a preamble preceding the activation message. It is advantageous to use a preamble preceding the activation message since the hearing aid 10 can already recognize on the reception of a preamble of this kind that a data transfer will take place shortly. In this way, it can suppress the switched-off phases in the standby mode until it has received the activation message and hence optionally also the information into which operating mode it should change. This enables the change of operating mode to be accelerated under some circumstances. To achieve a reliable recognition of the start of the data transfer, the length of the activation signal should exceed the duration of the switched-off phases in the standby mode. This can be achieved by the fact that the activation message in the activation signal is repeated several times until this condition is satisfied. In addition, it is also possible to extend the length of the activation signal by means of the redundant parts until they exceed the duration of a switched-off phase.
Alternatively, the hearing aid 10 can detect the start of a new data transfer from the modulation method used by the external device 20 to transfer its data. Hereby, suitable for this are in particular specific phase or frequency modulation methods, for example, frequency shift keying (FSK) or phase shift keying (PSK). The external device 20 can only use the special modulation method at the start of a new data transfer in order then to transfer the actual data by means of another modulation method. Alternatively, the external device 20 can use a different modulation method for each new data transfer.
In order to ensure reliable programming of the hearing aid 10, it is advantageous to provide a programming mode in the hearing aid 10, wherein received programming commands only result in programming of the hearing aid 10 in this operating mode, while, in another operating mode, they are ignored by the hearing aid 10. Although, in an analogous way to its receiving mode, the hearing aid 10 is hereby permanently switched to receive, the programming mode is preferably an independent operating mode and not a special receiving mode. To ensure reliable programming, the programming mode should have several important features which are not required in the regular receiving mode. Contrary to the case with the regular receiving mode, the change to the programming mode should not take place automatically in order to avoid unintentional programming. Preferably, the hearing aid 10 is only changed to the programming mode via special commands of the external device 20. Typically, the programming of the hearing aid 10 requires higher data rates than, for example, those required during the coupling of the hearing aid 10 to the external device 20, which can be embodied as another hearing aid or as a remote control. Therefore, it is advisable to increase the data rate in the programming mode. To achieve this, power-saving operating modes such as, for example, the standby mode (sniff mode) are deactivated during the programming. This occurs in order not to slow down the communication between the devices 10, 20 during the programming due to unnecessary waiting times which occur due to a repeated reactivation procedure. In addition, the ready-to-receive state of the hearing aid 10 must be permanently guaranteed during the entire programming, which is not the case with a constant change into other operating modes. Preferably, the programming mode is initiated by a command which is transmitted in the lower data rate of the normal operation. Following this, the standby mode is deactivated and the programming mode started in which the higher data rate is now used. Although the automatic change to the standby mode typical for the regular receiving mode is undesirable in the programming mode for the reasons described above, it can be advantageous for the hearing aid 10 only to remain in the programming mode for a preset programming time Δtp and after the expiry of this time automatically to return to the normal operating mode. The change to a reliable operating mode can enable it to be ensured that no unintentional change to the programming occurs. In addition, a change to the standby mode reduces the load on the internal power supply of the hearing aid 10. The time interval Δtp after which the hearing aid 10 switches from programming mode to a normal operating mode, is typically much longer than the time interval Δt after which the hearing aid 10 changes from the receiving mode to the standby mode. This is evident in
In addition, in the programming mode, the prespecified programming time Δtp can be reset and restarted by a programming access. It is also possible for a received audio data flow to reset this time Δtp as long as the system supports the transfer of audio data flows during the programming.
Number | Date | Country | Kind |
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10 2006 035 126 | Jul 2006 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2007/057670 | 7/25/2007 | WO | 00 | 1/27/2009 |
Publishing Document | Publishing Date | Country | Kind |
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WO2008/012327 | 1/31/2008 | WO | A |
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