The invention is directed to programmable hearing aid systems wherein a number of different programs are provided and among which the user of the hearing aid can choose in order to use the program best suited to the actual acoustic environment. The invention is useable in connection with both in the ear and behind the ear hearing aids as well as implantable devices with electrical or mechanical stimulation of inner ear part.
The act of choosing a program can be done discretely by the use of a remote control, or less discretely by touching buttons placed on the hearing aid. In either case however the user is made aware of his hearing disability and in some degree also people around may notice this action. Further this action may take some time, and during this time the attention of the hearing aid user is directed to the hearing aid and not directly at the surroundings, and these moments of less attention is disturbing to both the hearing aid user and to the people who are maintaining a conversation or other kind of communication with him or her.
From U.S. Pat. No. 6,035,050 a hearing aid system is known, wherein a solution to the above problem is attempted. The hearing aid system has a matching arrangement with a first memory for several parameter sets available for selection for each of several hearing situations, an input unit for selecting a current hearing situation and for selecting one of the several parameter sets available for this hearing situation, and a second memory for allocation data that identify the parameter sets selected for each hearing situation. For the determination of an optimal parameter set for each of several hearing situations, an optimal user-specific parameter set is allocated to each hearing situation as it arises during an optimization phase. After the optimization phase, the allocation data are evaluated in order to determine an optimal parameter set for each hearing situation. This parameter set is then programmed as the parameter set which will be called to set the transmission characteristics of the hearing aid whenever the hearing situation allocated thereto occurs.
According to the teachings of U.S. Pat. No. 6,035,050 the user needs to select both a hearing situation, which he believes to be in and make a choice as to the processing parameter set, which provides the best performance in the given situation. This leaves the user with many complex choices during the optimization phase, and the risk of confusion is high. Further this prior art hearing aid system prescribes the use of both an auxiliary module and a control module.
The object of the invention is to provide a hearing aid system with a learning capacity, which is easy and straightforward to use and where the training can be carried out without the use of any special devices apart from the hearing aid and possibly a remote control.
This is achieved according to the invention with a hearing device comprising:
In the following a distinction is made between an acoustic value, and a Characterizing Acoustic Value (CAV), where an acoustic value as the value at one specific point in time of an acoustic parameter, whereas the CAV is determined on the basis of several acoustic values which are logged during a period of time.
Each of the PPS's or processing parameter sets are similar to a program, and in the learning period the user only has to find out which of a number of PPS possibilities gives the best or preferred sound. The possible choices of PPS's are preferably programmed into the hearing aid by the hearing aid acoustician based on the users expected needs and lifestyle. Once a PPS is chosen in a given sound environment the hearing aid system starts to record and store the CAV's or characterizing acoustic values of that environment. During the learning period all possible PPS's should be activated in order for the hearing aid system to store sufficient data or CAV's for the acoustic environment in which the user chooses to activate the respective PPS. Once the learning period is over the automatic mode is activated, and now the current CAV's are continually calculated and compared with the stored CAV's. The best match between current and stored CAV's form the basis of an automatic choice of PPS. When using the hearing aid the user only has to choose program or PPS's during the learning period, and he does not have to worry about the sound environment. In the automatic mode the hearing aid is capable of choosing the program or PPS which matches the choices made during the training period.
In an embodiment of the invention the CAV's are derived from one or more of the following acoustic values (which could also be internal hearing instrument parameters):
The above acoustic values are often already calculated because they are used in the signal processor for providing the best output and it does therefore not cause any higher power consumption or the use of more processing power to generate these acoustic values. Further the combination of these values gives a very accurate description of the sound environment. Many other CAV values could be used, but not too many different acoustic values should be used due to storage limitations. Not only acoustic values belonging to the environment are usable hear. Also parameters belonging to the hearing aid could be used, such as the current setting, battery power or other values regarding the hearing aid.
In an embodiment means are provided for storing of CAV's derived from the signal during use of each of the user chosen PPS's during a learning period in the manual mode whereby the means comprises a number of storing places preferably arranged as a second cyclic buffer in a second memory for each of the CAV's for storing consecutively derived values, and storing places in the second memory for storing the most frequently occurring value in the cyclic buffer.
The CAV readings are bound to vary somewhat, even if the sound environment is quite stable and the value, which gets stored for further use, must reflect several readings extending over some time. By using the most frequently occurring value it is assured, that the CAV values which gets stored as a permanent signature for the environment carry the most information about the environment.
However in some cases this is not entirely true, because if the difference between most frequently occurring value and second most frequently occurring value is small, it could indicate that the characterizing value does not carry significant information about the sound environment. Therefore the CAV's are stored along with a weight indicator. The weight indicator shows how much the corresponding stored CAV fluctuates in the cyclic buffer. If the CAV stays unchanged, the weight indicator is high to signify that this CAV is an important factor in the current environment, and if the CAV changes a lot, a low weight indicator gets assigned, to signify that this CAV value is not significant for the current environment.
In an embodiment of the hearing aid system the CAV values to be used in automatic mode and manual mode comprises mean values derived by first storing consecutive acoustic values calculated directly from the input signal of the hearing aid in a first cyclic buffer and storing the most frequently occurring values, such that the most frequently occurring value is the CAV used.
In this way transients, which may occur in the sound environment will not get a dominating influence on the CAV values which are calculated and further used by the hearing aid.
In a further embodiment of the hearing aid system according to the invention, the first cyclic buffer has a first length and update frequency in the manual mode and a second length and update frequency in the automatic mode. In this way this part of the system is shaped dynamically according to the specific task which is performed.
The cyclic buffer makes it possible to see if any of the characterizing values change more permanently to a new constant level, which could form the basis of a new CAV set being written into the memory.
In a further embodiment of the hearing aid system a comparison and a grading means are provided for comparing the current CAV's stored in the first memory in automatic mode with the CAV's belonging to each PPS and stored in the second memory in manual mode and whereby a grade is assigned to each PPS for the correspondence between the current CAV and the CAV belonging to the respective PPS whereby a further cyclic buffer is provided with places for each available PPS and arranged to receive consecutive grades and where the PPS having the highest average grading over the cyclic buffer is used in the signal processing means.
Preferably the comparison between current and stored CAV's is carried out with respect to the weight indicator stored along with the CAV's during the learning phase. If the stored CAV and the current CAV have equal values the weight gets added to a sum, and sums for each PPS are compared and a grading is assigned to each PPS according to the sum. The grades have two values, namely the value 1 for best correspondence between current and stored CAV and 0 for the remaining pairs of stored and current CAV's. This makes the averaging simple, as it is the PPS, which has the highest number of ones, which is being used. The length of the further cyclic buffer is preferably set to 61, but other values are possible. The length-range should be from about 30 up to 200. Larger length will give more precise decision; shorter length will give faster switching. With some intermediate values, e.g., 40, 61, 92, 150, a trade-off between switching-speed and decision-accuracy can be reached. 61 is a good compromise and trials have shown well functioning hearing aids with this value.
According to yet another embodiment of the hearing aid system a further user input means is provided for user determined selection of at least one parameter value belonging to a PPS during use by the signal processing means in the manual or the automatic mode. Hereby it is possible to give the user access to one or more specific parameters of the processing parameter set currently in use. In this way the user may get the possibility to adjust the gain or any other parameter. This is an advantage, as it may occur that the automatically set gain in certain circumstances could lead to uncomfortable sound levels or to too low sound levels.
In an embodiment of the hearing aid system means are provided for comparing the user determined parameter value with the value of the corresponding parameter belonging to the stored PPS. Means are also provided for changing the value of the parameter belonging to the stored PPS in order to reduce the difference between the value of the stored parameter and the value of the user determined parameter. In this way it is ensured that the user preference of e.g. gain setting is stored. When this PPS is later chosen in either automatic or manual mode the user gain is set more accurately according to the user preference.
It is preferred that at least one user determinable parameter value comprises the gain setting. Other parameters could however also be used for this purpose.
The hearing device in
In
In the manual/learning mode the user has to choose the program, also called processing parameter set (PPS), which provides the best signal, whereas in the automatic mode the hearing aid chooses the PPS to be used in the signal processor 2. This automatic choice is based on the current sound environment and the choices made by the user in the learning mode. This is further explained in the following.
In
In the described embodiment the acoustic values used can be described using 18 binary places, or 18 different acoustic values are used to describe the environment. The 18 corresponding characterizing acoustic values are taken from the storing places of the first memory 4 (
As seen in
In the beginning the user may have to listen to the hearing aid with each of the PPS possibilities turned on, in order to decide which one is preferable in the current situation. Therefor the capture and storing of environment data or characterizing acoustic values (CAV) is not commenced before some time has lapsed without changes in the choice of PPS. When the hearing aid is handed out to the user default CAVs are stored in the memory. The CAV are consecutively captured and stored according to the user chosen PPS in a second cyclic buffer of a second memory.
In the presented embodiment of the invention the second cyclic buffer in the second memory for storing characterizing acoustic values derived from the input signal has a length of 16. New CAV values get stored in this buffer every 10 seconds. This is shown in
The task of comparing current and stored CAV's and choosing the best-suited PPS for the current environment is handled as described in the following with reference to
As seen from the above, the determination of CAV belonging to a particular PPS chosen by the user takes place in two steps: First the acoustic environment values are stored as they are captured, and the most frequently occurring value is used to give CAV values. The CAV values are logged over some time, and the most frequently occurring values are assigned to the particular PPS chosen by the user.
In each PPS a gain is specified, but the user may also be given control of the gain through a further user input possibility. Through this possibility the user may adjust the gain according to his or her preference. Basically this has to be done at every shift of the PPS if the specified gain is not according to the users liking. In order to avoid this the hearing aid according to the invention monitors the users changes of gain, and if the user chooses a gain setting which is higher than the specified gain a new gain setting gets stored in the PPS memory. The new gain is set one dB higher than the originally specified gain. This will happen each time this particular PPS is used and after some time the specified gain will be according to the users liking. If the user at a later time changes his mind and whishes a lower gain, he just chooses to set the gain lower each time the particular PPS is used, and after some time the initial gain setting of this PPS will reach a lower value. This feature of the hearing aid according to the invention is active both in the learning mode and in the automatic mode. In the present example the gain is the parameter, which the user may change, but other parameters may be changeable in this way like the cut-off frequencies or time-constants (attack-, release-times).
Number | Date | Country | Kind |
---|---|---|---|
2002 01930 | Dec 2002 | DK | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/IB03/06356 | 12/9/2003 | WO | 00 | 9/7/2005 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2004/056154 | 7/1/2004 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
4425481 | Mansgold et al. | Jan 1984 | A |
4989251 | Mangold | Jan 1991 | A |
5581747 | Anderson | Dec 1996 | A |
5604812 | Meyer | Feb 1997 | A |
5706351 | Weinfurtner | Jan 1998 | A |
6035050 | Weinfurtner | Mar 2000 | A |
20020037087 | Allegro et al. | Mar 2002 | A1 |
Number | Date | Country |
---|---|---|
10142347 | Oct 2002 | DE |
0176321 | Oct 2001 | WO |
Number | Date | Country | |
---|---|---|---|
20060215860 A1 | Sep 2006 | US |