EP1701585B1

EP1701585B1 - Method and system for adjusting a hearing device

Info

Publication number: EP1701585B1
Application number: EP20060112108
Authority: EP
Inventors: Christian Brunner; Patrick Baechler; Ivo Hasler; Hubert Lechner; Stefan Menzl; Bernd Waldmann
Original assignee: Phonak AG
Current assignee: Sonova Holding AG
Priority date: 2006-03-31
Filing date: 2006-03-31
Publication date: 2012-06-13
Anticipated expiration: 2026-03-31
Also published as: EP1701585A2; EP1701585A3

Description

The present invention is directed to a method for wirelessly adjusting one or more hearing devices with a central unit.
It is generally known that a person's hearing loss is not normally uniform over the entire frequency spectrum of hearing. For example, in typical noise-induced hearing loss, the hearing loss is typically greater at higher frequencies than at lower frequencies. The degree of hearing loss at various frequencies varies with individuals. The measurement of an individual's hearing ability can be illustrated by an audiogram. An audiologist, or other hearing health professionals, will measure an individual's perceptive ability for differing sound frequencies and differing sound amplitudes. A plot of the resulting information in an amplitude/frequency diagram will graphically represent the individual's hearing ability, and will thereby represent the individual's hearing loss as compared to an established range of normal hearing for individuals. In this regard, the audiogram represents graphically the particular auditory characteristics of the individual. Other types of measurements relating to hearing deficiencies may be made.
Since individuals have differing hearing abilities with respect to each other, and oftentimes have differing hearing abilities between the right and left ears, it is normal to have some form of adjustment of the hearing devices to compensate for the characteristics of the hearing of the individual.
Numerous types of adjustable hearing devices are known. As such, details of the specifics of adjusting functions will not be described in detail.
The adjustment of hearing devices can be made in several ways. First, it has been known to have the manufacturer establish a computer-based programming function at its factory or outlet centers. In this form of operation, the details of the individual's hearing readings, such as the audiogram that has been obtained by the audiologist, are forwarded to the manufacturer for use in making the adjustments. Once adjusted, the hearing device or hearing devices are then sent back to the audiologist or directly to the intended user. Such an operation clearly suffers from the disadvantage of the loss of time in the transmission of the information and the return of the adjusted hearing device. In addition, an interactive adjustment involving the audiologist and the hearing device user is usually not possible. Furthermore, such arrangements characteristically deal only with the adjustment of the particular manufacturer's hearing devices, and are not readily adaptable for adjusting various types of hearing devices.
Yet another type of prior art programming system is utilized wherein the programming system is located near the audiologist who directly adjusts the hearing device for the hearing device user. In such an arrangement, it is common for each location to have a general purpose computer especially programmed to perform the adjustment function and provide it with an interface unit hard-wired to the computer for providing the programming function to the hearing device. In this arrangement, the hearing professional enters the audiogram or other patient-related hearing information into the computer, and thereby allows the computer to calculate the auditory parameters that will be optimal for the predetermined listening situations for the individual. The computer then directly programs the hearing device. Such specific programming systems and hard-wired interrelationship to the host computer are costly and do not lend themselves to ease of altering the programming functions.
Other types of programming or adjusting systems wherein centralized host computers are used to provide programming access via telephone lines and the like are also known, and suffer from many of the problems of cost, lack of ease of usage, lack of flexibility in reprogramming, and the like.
Known methods for adjusting hearing devices are disclosed, for example, by WO 99/09 799 and by US-5 210 803 . Other types of devices having a self-identification feature for device detection are disclosed, for example, by EP-1 309 222 A2 and by US 2005/0068182 .
Furthermore, US 2005/000 81 75 A1 discloses a system for programming hearing devices with a host computer that is wirelessly connectable to the hearing devices via a hearing device programmer. This known system bears the risk that the hearing device programmer connects to the wrong hearing device resulting in malfunctions due to bad or wrong adjustment of the hearing device.
US 2005/0255843 A1 discloses a wireless hearing instrument communication protocol for instance to wirelessly transfer hearing aid programming data from a programmer to a hearing aid for configuring the hearing aid.
It is therefore an object of the present invention to provide a method for adjusting one or more hearing devices, which method does not have the above-mentioned disadvantages.
This object is accomplished by the measures specified in claim 1.
Therewith, the audiologist is able to unambiguously assign one or two hearing devices in a fitting session, even if multiple hearing devices are within the range of the wireless network or wireless transmitter, respectively.
It is expressly pointed out that the term "hearing device" does not only mean a device which is inserted into a user's ear to improve the hearing ability of a hearing impaired person, but also any accessory device used in connection with the device inserted into the user's ear, as for example a remote control. In addition, the term "hearing device" may also mean a communication device or an ear protection device, which is inserted into the ear canal. Thereby, it is independent on the fact whether the hearing device is inserted into the ear canal or whether it is implanted into the inner ear, for example.
The present invention is further explained in more detail by referring to drawings illustrating exemplified embodiments of the present invention.

Fig. 1: schematically shows a system for adjusting one or more hearing devices,
Fig. 2: shows a first screen shot of a software application controlling the hearing devices, and
Fig. 3: shows a second screen shot of another software application controlling the hearing devices.

Fig. 1 shows three hearing devices 1, 2 and 3, a central unit 4 - also called fitting device - and a host computer 5, which can be a commercially available computer, e.g. a personal computer or a notebook. It is expressly pointed out that the central unit 4 and the host computer 5 can be a single unit. Therefore, whenever the term "central unit" is used in this specification, the meaning is not only limited to the intermediate unit (i.e. the fitting device) but may also include a part or the whole host computer 5 in combination with the central unit 4 (i.e. the fitting device).
As is depicted in Fig. 1, the central unit 4 and the host computer 5 are interconnected via a connection 7, which is either implemented as a wireless or as a wired connection. Numerous possibilities exist for implementing this connection. For example, a connection via a so called Bluetooth device, which is a wireless interconnection, a cable using a USB-(Universal Serial Bus)-interface, or - to mention another wireless network - a network implemented according to the IEEE-802.11 standard, which is also called WLAN-(Wireless Local Area Network).
In case of an inventive system with a fitting device and a host computer 5, as it is depicted in Fig. 1, software applications, e.g. a fitting program to adjust a hearing device 1 to 3, are running on the host computer 5 that is standardized to a large extent (e.g. a personal computer), whereas specific hardware that is needed in some cases to adapt to specific data transmission to the hearing devices 1 to 3, is realized in the fitting device or the central unit 4, respectively.
According to the present invention, the hearing devices to be adjusted to the needs of an intended user are connected via a wireless connection to the central unit 4. Therefore, a wireless network 6 is provided that is implemented to be in line with either proprietary or open standards. As open standards for wireless networks, the above-mentioned standards that have been mentioned in connection with the interconnection between the host computer 5 and the fitting device - i.e. Bluetooth, WLAN, etc. - can very well be used.
The central unit 4 is able to establish a wireless connection to the hearing devices 1 to 3 on condition that these hearing devices 1 to 3 are responsive to the wireless network 6. Depending on the range of the network 6, further hearing devices might be detected that are not needed for an adjustment process. After the detection of all hearing devices in a specific range of the network 6, the hearing devices are unambiguously identified. This will be further described by several ways of implementation. By the step of identifying one or more hearing devices, the risk of adjusting a wrong hearing device 1, 2, 3 is eliminated. Once the hearing devices are identified, a desired hearing device is selected for the adjustment, and a wireless link can be established between the central unit 4 and the selected hearing device. In a further step, the adjustment can be made by downloading specific parameters and/or hearing programs.
It is pointed out that the term "detect a hearing device" means the awareness of the system that a hearing device is present, and the term "identify a hearing device" means the unambiguous assignment of a detected hearing device to its physical counterpart. The assignment is thereby not only unambiguous for the system but also for the audiologist carrying out the adjustment of the hearing device. In addition, the term "identify a hearing device" may also mean that further information must be provided to the inventive system in order that an unambiguous assignment can be completed. Such information can be, for example, the indication whether a hearing device will be or is inserted into the ear canal of the left ear of the user, into the ear canal of the right ear of the user, or whether a hearing device will not be inserted at all, for example in cases with detected hearing device which will not be adjusted in the current fitting session.
The step of identifying a hearing device 1 to 3 can be performed in several ways:
A first way to identify detected hearing devices is to instruct one hearing device to emit a signal, which preferably is an acoustic signal in the manner of a jingle, for example, which is very easily identifiable. The acoustic signal is generated by a loud speaker, for example the loudspeaker that is integrated into the hearing device and that is often called receiver in the technical field of hearing devices. The instruction for the hearing device to generate the signal is given by the central unit 4, which is controlled by the audiologist during the fitting session. Once the audiologist perceives the signal, he or she can match or assign the hearing device detected by the system to the hearing device that emitted the signal. The audiologist can instruct one detected hearing device after the other to generate a signal and thereby identify all detected hearing devices, or he can stop instructing further hearing devices to emit a signal as soon as all relevant hearing devices are identified, i.e. as soon as the hearing devices are identified, which will be adjusted during the present fitting session.
A second way to identify detected hearing devices is based on a so called RFID-(Radio Frequency Identification)-technique. An unambiguous RFID-tag, which is either active or passive, is provided at each or in each of the hearing devices to be identified. By stimulating a passive RFID-tag using a specific radio frequency signal, a response signal being also a radio frequency signal containing the identification code is generated. For active RFID-tags, no stimulation is necessary because an active RFID-tag emits a response signal on its own. The response signal is detected, i.e. the identification code is received by a receiving unit (not shown in Fig. 1) incorporated into the central unit 4. Therewith, the basis for assigning the stimulated hearing device to the corresponding physical hearing device is given.
In order to prevent any wrong assignment, a RFID-technique can be applied that only allows short range identification of a RFID-tag, i.e. the hearing device carrying the tag to be identified must be brought in close proximity to a RF-transmitter in order to obtain a RF-response signal carrying the identification code. Therewith, different RF-response signal may not be mixed.
A third way to identify detected hearing devices is to stimulate one of the detected hearing devices, while monitoring the detected hearing devices for a corresponding response to the stimulation in the central unit 4 at the same time. The hearing device, for which a corresponding response has been detected, is determined in the central unit 4. Based on this information, the stimulated hearing device can be assigned to the determined hearing device, which completes the identification.
It is pointed out that one or several of the following stimulation can be used to identify the hearing devices according to the third way:

A feedback signal can be provoked in the hearing device.
Operating a remote control which acts on the hearing device to be detected.
Tapping on the housing of the hearing device to be identified. The tapping is captured by a microphone of the hearing device and the resulting electrical signal is transmitted to the central unit 4, where it is monitored.
Actuating a switch provided on the hearing device. This might well be a program switch which is later used to switch from one hearing program to another.
Inserting a battery and thereby initiating first operation sequences might also be used as a stimulation to be monitored.
Closing a battery door results in a similar behavior as the one for inserting a battery.

A fourth way to identify detected hearing devices is to limit the range of the wireless network 6 in such a way that only one hearing device can be detected at the same time. This can be accomplished by causing the central unit 4 to enter a special mode with a rather small wireless range of the network 6, for example less than 10 cm, and the audiologist places the designated hearing device in close proximity of the central unit 4 or the transceiver contained therein, respectively, or the audiologist places the central unit 4 or the transceiver, respectively, in close proximity of the designated hearing device. The latter is appropriate in case the designated hearing device has already been inserted into the user's ear. This fourth way for identifying a hearing device is unambiguous, easy to implement and also easy to use.
A fifth way to identify the detected hearing device is by manually comparing the information automatically read out of the hearing device by the central unit 4 and the information indicated on the outside surface of the hearing device housing. The audiologist can read and compare this information to the information automatically read out of the hearing devices, thereby assigning the hearing device with identical information. For example, the serial number of the hearing device is often indicated on the outside surface of the hearing device housing and can therefore very well be used as information for the assignment. Other unique identification of the hearing devices can also be used. The assignment of the corresponding hearing devices is very reliable and technically rather easy to implement.
Figs. 2 and 3 show screen shots of a software application controlling the adjustment during a detection and identification process. The screen shots depict a so called window 20, 30, as it is well known from Microsoft or Apple Computers, Inc., for example, with three hearing devices detected within the range of the network 6. The detected hearing devices are listed with its product names (Savia), the type of the hearing device (BTE for Behind-the-Ear), a reference number (e.g. 311), and the serial number of the hearing devices (e.g. 123). In case that more than three hearing devices are detected, the window 20, 30 will automatically enlarge to show all detected hearing devices. Alternatively, or in case there is not enough space to show all detected hearing devices, a scroll bar is provided to scroll through the detected hearing devices (not shown in Figs. 2 and 3).
In Fig. 2, a window 20 is shown which is particularly suitable for the above-described first way to identify detected hearing devices. The audiologist, to whom the window 20 according to Fig. 2 is presented, can instruct one of the listed hearing devices by pressing a button 21, which is located to the right side of the row showing the particular hearing device. By pressing this button 21 a signal is emitted in the hearing device listed in this row of window 20. As has already been pointed out, the signal is preferably an acoustic signal in the manner of a jingle, for example.
Once a hearing device is identified and selected for adjusting, further information is provided for this hearing device regarding its location, e.g. whether it is used on the left or on the right ear. For easy information input into the central unit 4, a drop down menu 22 is presented to the audiologist after clicking onto the downward arrow on the same row as the hearing device information is presented (see Fig. 2). The drop down menu 22 preferably contains three offered selections: "Left Side", "Right Side" and "Side not set". As a default, the selection will be set to "Side not set", which means that this hearing device will not be used in the subsequent adjustment. The audiologist can now change this default setting to another selection. For a binaural or bilateral hearing system, for which two hearing devices are used, the audiologist has to assign one hearing device to the right ear and another hearing device to the left ear. Once the two hearing device are identified which will be used for the binaural or bilateral hearing device, the corresponding position is indicated for each of the two hearing devices in the drop-down menu 22 as described above. Therewith, the identification is completed and the adjustment of the hearing device can begin after a wireless link has been established from the central unit 4 to the two identified hearing device belonging to the binaural or bilateral hearing system.
In Fig. 3, a window 30 is shown which is particularly suitable for the above-described third way to identify detected hearing devices. The audiologist, to whom the window 30 according to Fig. 3 is presented, can stimulate one of the detected hearing devices by one or several of the predefined stimulating actions described in connection with this third way to identify detected hearing devices. The monitoring of a response due to the stimulation is performed by the central unit 4 and the result of this monitoring is presented in the last column 31 of the listed detected hearing devices. As can be seen from Fig. 3, the second hearing device of the list has been stimulated in this example. This is indicated by the information "Pressed < 5 sec" in the last column 31. Accordingly, the stimulated hearing device is the one with serial number 2222. In case this hearing device is the one or one of the two hearing devices to be used for the subsequent adjustment, the audiologist again selects in the drop-down 33 on the same line as the identified hearing device and assigns the desired position, which again is "Left Side" or "Right Side". In case of a binaural or bilateral hearing device, the audiologist stimulates - e.g. by pressing volume control or the like - the second hearing device. Again, the result is entered into the last column 31 of the list of detected hearing devices, and, as a last step, the desired side is again selected in the drop-down menu 33 by the audiologist. Therewith, both hearing devices are accurately assigned and the adjustment phase for these hearing devices can be undertaken. The fitting program guides the audiologist through the fitting or adjustment process.
Although there is no specific example for a window which is presented to the audiologist during the identification phase implemented according to the second, the fourth and the fifth way to identify detected hearing devices, it is pointed out that such windows and its content will be deducible by the skilled artisan given the information above in connection with the first and third way to identify detected hearing devices.

Claims

A method for wirelessly adjusting one or more hearing devices (1, ..., 3) with a central unit (4), the method comprising the steps of:
- establishing a wireless network (6) wirelessly connecting the central unit (4) to hearing devices (1, ..., 3), which are responsive to said wireless network (6),

- detecting said hearing devices (1, ..., 3),

- identifying one or more of the detected hearing devices (1, ..., 3) so as to achieve an unambiguous assignment of a detected hearing device to its physical counterpart,

- selecting one or more of the identified hearing devices (1, ..., 3),

- establishing a wireless link from the central unit (4, 5) to at least one of the identified hearing devices (1, ..., 3), and

- adjusting the at least one identified hearing device (1, ..., 3),
characterized in that the step of identifying one or more of the detected hearing devices further comprises the steps of:
- limiting the range of the wireless network (6) by causing said central unit (4) to enter a special mode with a rather small wireless range of the network (6), and

- placing the one hearing device to be identified in close proximity of the central unit (4) or placing the central unit (4) in close proximity of the one hearing device to be identified.
The method of claim 1, wherein the range of the wireless network (6) can be limited to less than 10 cm.
The method of claim 1 or 2, characterized by further comprising the step of:
- displaying the detected hearing devices (1, ..., 3), preferably with additional identifier such as a model identifier or a serial number pertaining to the detected hearing device.