DE102009058414A1 - Hearing aid for treatment of hearing-impaired patients, has signal processing device receiving sensor signals from acoustic sensors as input signals and processing sensor signals depending on spatial arrangement of acoustic sensors - Google Patents

Abstract

The aid (1) has a microphone device (2) comprising a surface extended arrangement of acoustic sensors (6) formed in micro-electro-mechanical system-technology. A signal processing device (3) receives sensor signals from the acoustic sensors of the microphone device as input signals. The signal processing device processes the sensor signals depending on spatial arrangement of the acoustic sensors. The microphone device exhibits thickness of 3 mm. The microphone device is arranged on or at a housing and designed as a flexible foil.

Description

The The invention relates to a hearing aid with a microphone device.

hearing aids serve the treatment of hearing impaired, hard of hearing Patients. They basically consist of a microphone as a sound pickup for picking up ambient sound from a signal processing device and reinforcement, and also as a listener or receiver designated speakers. The following will be under Receiver understood any output signal generator hearing aid, So for example, a generator for nerve stimulation signals or for Signals for direct stimulation of the cochlea. The receiver generates from the hearing aid Recorded and processed acoustic output signals for Hearing of Patients are guided.

hearing aids are known in various basic housing configurations. For HDO hearing aids (Behind-the-ear, behind-the-ear) will be a housing with components such as battery and signal processing device worn behind the ear and a Hose or sound tube, also referred to as tube, leads from the casing to the auditory canal. For IDO hearing aids (In-the-ear, in-the-ear) becomes a housing, all of them Components including Microphone and receiver may be worn in the ear canal. Other configurations are Completely-In-Canal (CIC) or Receiver-In-Canal behind-the-ear (RIC-BTE).

The human ear consists of a multitude of individual components, the hearing cause and influence. The auricle serves as a bell and by its shape it modulates the sound simultaneously direction-dependent. Of the ear canal Forwards the sound to the eardrum and also causes it a directional one Modulation. The eardrum is flat and is extended by sound is vibrated in the inner ear other by ossicles and Cochlea in a for the brain is put into actionable nervous signal.

A conventional hearing aid can have a single microphone as a sound pickup. The ambient sound is determined by the head shape of the patient, by the pinna, and due to other environmental influences modulated. This modulation is related to so-called Head-Related Transfer Functions (HRTF) and causes a directional dependence of the recorded sound. Depending on where the microphone is located, z. Behind the ear or in the ear at the entrance of the ear canal, changes the directional acoustic Signal. Even though, this modulation is due to the signal processing in the hearing aid considered is not natural spatial hearing impression simulated. A spatial Simulation possible on the one hand, the acoustic reproduction of signals for the hearing aid wearer more authentic and to make it more realistic. On the other hand allows a spatial Simulation or analysis the separation of different sound sources and targeted oppression of interfering signals an interfering sound source, to the useful signal Störsignal- or to increase the signal-to-noise ratio.

Therefore are hearing aids known to have two or more microphones as a sound pickup. If at least two microphones are provided, then it can be achieved that signal processing is at least basic spatial Take information into account can, for. B. whether a signal source is arranged in front of or behind the head of the hearing aid wearer. It is obvious that a higher number of microphones the spatial evaluation options improved. In order to capture all three spatial directions are theoretically at least 4 microphones required on different Space axes must be arranged. in principle allows an increase the number of microphones an improvement in signal-to-noise ratio as well a more realistic and natural Output.

to increase wearing comfort and improving cosmetics become hearing aids preferably made small. Because of the space requirements of a microphone, it is therefore not possible, a to provide any number of microphones. Added to that the small size of one Hearing aid too the possibilities the arrangement of microphones on different spatial axes difficult. Of the caused by a small size of the hearing aid small distance of the microphones to each other reduces the spatial resolution in terms of of the ambient sound to be recorded additionally, so that the sensitivity and accuracy of spatial Sound detection is limited.

With usual Microphone equipment is therefore a natural spatial hearing impression only limited simulated.

A The object of the invention is a hearing aid with a microphone device indicate that improved spatial coverage of ambient sound allows.

The Invention solves this task by a hearing aid with the characteristics of the independent Claim.

A basic idea of the invention is a hearing aid comprising a microphone device, a signal processing device and a Specify a receiver whose microphone device consists of a surface extended arrangement of a variety of built-in MEMS technology (micro-electro-mechanical system) acoustic sensors whose signal processing device receives as input a plurality of sensor signals from individual sensors or grouped together sensors of the microphone device , and whose signal processing means processes the plurality of sensor signals in response to a spatial arrangement of the sensors.

One Advantage of this basic idea is that the areal extent and the multitude of acoustic sensors a more accurate and precise spatial Recording the ambient sound allows. The improved spatial Capture enabled continue a better repression undesirable noise the ambient sound. By using the MEMS technology, the acoustic sensors are made sufficiently small, despite the low available space on or on a hearing aid or a variety of them in the area of the human ear or ear canal to be able to provide. The MEMS technology allows serial or mass production with high availability and low cost.

According to one advantageous development of the basic idea of the invention the microphone device designed as a flexible film and contoured such that it is inserted into the ear of a hearing aid wearer can be.

One Advantage of this basic idea is that the spatial Modulation of sound through the auricle by the microphone device modulated recorded signals and taken into account in the signal processing can be to the spatial Improve detection of ambient sound. At the same time forms the Auricle is a large area compared to a hearing aid or ear canal for the Microphone device can be used to increase the sensitivity and accuracy of spatial Improve detection of ambient sound. While conventional microphones for an arrangement in the auricle in great Number are too big and also Even the fixation of the auricle is a problem Slide listed area, thin microphone device in the contours of the auricle, for example helix or concha, fixable and comfortable wearable. With suitable optical design, For example, in flesh-colored, dull coloring, it is also optical unremarkable.

According to one further advantageous development of the basic idea of the invention is the microphone device designed to replace the Eardrum or eardrum covering the ear canal of a Used to hearing aid wearer become.

One Advantage of this basic idea is that for the hearing impaired with damaged or dysfunctional eardrum to create a tympanic membrane replacement can. By the flat execution The microphone device as a film can be in the form of an eardrum be reproduced what the placement of the microphone device favored. The good spatial Detection by the microphone device also allows it, too the spatial Replace detection of an intact eardrum. The placement of the eardrum replacement in the area of the eardrum or at the Place guaranteed doing that, the spatially dependent modulation the ambient sound can be used by head shape, auricle shape and ear canal can.

Further advantageous developments of the basic idea of the invention and Further advantages emerge from the dependent claims and from the following description of exemplary embodiments with reference to FIG Characters. Show it:

1 Schematic representation of hearing aid components

2 IDO hearing aid with two-dimensional microphone device

3 Flat microphone device in the auricle

4 Schematic planar microphone device

5 Flow arrangement of the hearing aid components

6 Test device with artificial ear canal

7 IDO hearing aid

8th . 9 Flat microphone device as eardrum replacement

10 - 12 Scheme of different MEMS transducers

In 1 is a schematic representation of basic components of a hearing aid 1 played. A microphone device 2 includes a variety of acoustic sensors 6 , The acoustic sensors are adapted to receive ambient acoustic signals. They are an advantage legally executed in MEMS technology; exemplary effect schemes are explained below.

The output signals of the acoustic sensors 6 or the microphone device 2 become a signal processing device 3 fed. The signal processing device 3 Processes the acoustic signals such that a suitable for the hearing aid wearer and his individual hearing damage output signal and frequency spectrum is generated.

In the signal processing in particular, the spatial information of spatially distributed arranged acoustic sensors 6 considered. Due to the spatial arrangement, the sensor signals contain information about the spatial arrangement of the respective ambient acoustic signal source. So z. B. signal sources are assigned to the visual field or the space behind the head of the hearing aid wearer, or it can be distinguished between signal origin from above or from below. Diverse further possibilities of spatial ambient sound analysis with more precise spatial associations, which may also automatically respond to respectively determined signal or interference signal sources, are also conceivable. The basic principles of the spatial ambient sound evaluation are known and transferable from conventional two- or multi-microphone hearing aids.

Depending on the number and spatial extent of the acoustic sensors 6 additional analysis parameters not considered in conventional hearing aids can be analyzed. For example, at a relative to the hearing aid 1 moving sound source the relative speed of their movement are analyzed. For this purpose, in addition to the evaluation of the spatial origin additionally, for example, a Doppler effect in relation to this signal source can be analyzed in order to obtain further information regarding spatial position and movement. It would also be conceivable to evaluate a Doppler effect in order to be able to identify relatively moving signal sources and to be able to suppress them as an interference signal, for example.

The output signal of the signal processing device 3 becomes an amplifier 4 supplied, which amplifies it to a suitable for the hearing aid wearer or manually adjusted volume level. The amplified signal becomes a receiver 5 supplied, which is shown in the example shown as a speaker. The receiver 5 generates an acoustic output signal that is supplied to the hearing aid wearer's hearing aid directly or through a hose.

For the scheme shown, it is irrelevant whether the hearing aid 1 as HDO, IDO, CIC or other configuration.

In 2 is a hearing aid 11 in IDO configuration with flat microphone device 12 shown. The hearing aid 11 includes a housing 16 in which all functional components of the signal processing device are arranged. A receiver 15 is arranged at one end, which is directed to the interior of an ear canal, in which the hearing aid 11 can be used. An on / off switch 17 as well as a volume control 18 are on the opposite, outward-facing side of the housing 16 arranged so that when the hearing aid 11 is inserted into an auditory canal, are accessible from the outside and can be operated.

The hearing aid 11 included a microphone device 12 which are also on the outward side of the case 16 is arranged. The microphone device 12 is flat and comprises a plurality of individual, separate acoustic sensors, which are suitable for recording ambient sound. The acoustic sensors are indicated in the figure as a grid pattern. The spatially extended arrangement and the plurality of acoustic sensors provides comprehensive spatial information about the recorded ambient sound, the signal processing device of the hearing aid 11 as mentioned above can take into account. In addition, the arrangement in the region of the auditory canal causes the surrounding auricle to modulate the ambient sound, whereby additional spatial information about the ambient sound is obtained.

In 3 is a two-dimensional microphone device 22 shown in an auricle 20 is arranged. The microphone device 22 comprises a plurality of areally arranged, separate acoustic sensors, which are indicated in the figure as a grid pattern.

The microphone device 22 is designed as a flexible, thin foil that matches the contour of the auricle 20 mimics. Due to its flexibility, it can become the auricle 20 and adapt their anatomical contours flexible and therefore be worn comfortably. Due to its contour, it can be fixed in the anatomical structures of the auricle, for example Concha, Helix, etc. With appropriate optical design and color, its visual conspicuity can be reduced to make it cosmetically acceptable to the wearer.

The microphone device 22 points in the area of the auditory canal 21 an opening on to the ear canal 21 not to obstruct, ambient sound to the ear canal 21 to penetrate and prevent occlusion effects in the ear canal. The arrangement of the microphone device in the auricle 20 and her auricle 20 Aimed contour and design causes the ambient sound through the auricle 20 is modulated in a natural way, thereby affecting the microphone device 22 additional spatial information of the ambient sound is detected.

In 4 is a two-dimensional microphone device 32 shown schematically. It has a plurality of individual, separate acoustic sensors, which are indicated as a grid pattern. The signals of the individual sensors could be supplied to a signal processing device either individually. Or groups of sensors can be formed. In this way, averaged over several individual sensors signal is obtained. The groups can be arranged so that a particularly precise spatial information is obtained. For example, the sensors can each be a quadrant 34 . 36 . 38 . 40 be grouped together, or the sensors of certain spatial sensor areas 33 . 35 . 37 . 39 ,

By doing in the signal processing the spatial Arrangement of the sensors whose signals are processed, considered is, is a spatial analysis the recorded ambient sound possible, as before explained is.

In 5 an arrangement of hearing aid components corresponding to the sequence of signal processing is reproduced. In a first functional block S1, a microphone device receives acoustic ambient signals. The microphone device comprises several spatially distributed acoustic sensors and outputs as an output from a plurality of signals generated by the sensors or sensor groups.

In a subsequent Function block S2 checks the microphone functionality and it becomes sensor information the respective spatial sensor arrangement assigned, z. B. front / back / up / down.

In a subsequent Function block S3, the sensor signals are pre-amplified and subjected to basic noise suppression, at the example of noise sources identified and suppressed be or Doppler effect interference signals can be reduced.

In a subsequent Function block S4 is a final signal improvement and high-performance output gain. The Output signal is supplied to a receiver, not shown.

In 6 is a test device 53 with artificial ear canal 52 shown schematically. The test device 53 simulates an ear canal to examine or test the acoustic properties of a particular auditory canal hearing aid configuration.

A hearing aid to be tested 50 is in the artificial ear canal 52 introduced. At the position where the eardrum would sit in the actual ear is in the artificial ear canal 52 a flat extended acoustic sensor 51 arranged. As previously explained, the planar sensor comprises a multiplicity of separate, individual acoustic sensors. As a result, based on the sensor signals, a precise spatial evaluation of the acoustic signals in the artificial auditory canal 52 respectively.

The test device 53 with the areal microphone device 51 allows a more detailed and accurate analysis of the auditory signals in the artificial ear canal 52 than would be possible with a simple conventional microphone device.

In 7 is an IDO hearing aid for use with blocked ear canal 65 shown in section. The auditory canal 65 is by design or due to accidental circumstances due to a blockage 63 locked. By the blockade 63 through is a sound channel 64 led, through the sound to behind the blockade 63 inside area of the ear canal 65 and on to the eardrum 66 can get. The blockade 63 prevents sound from passing through the sound channel 64 can happen.

In order to be able to completely capture all information of the ambient acoustic signals, including the spatial information, the IDO hearing aid is on the outer, free side with a flat-extending microphone device 61 Mistake. The microphone device 61 sits in the area of the entrance of the ear canal 65 where the acoustic signals modulated by the surrounding auricle arrive. The flat microphone device 61 includes a variety of acoustic sensors and can record with them the ambient sound including spatial information content precisely.

A signal processing and amplifying device 62 receives the sensor signals of the microphone device 61 as input signals and processes them further. In this case, as explained above, a spatial analysis of the ambient sound is made on the basis of the information about the spatial arrangement of the acoustic sensors or sensor groups.

In 8th is a two-dimensional microphone device 70 as a sectional image - not to scale - darge represents, which is used as eardrum replacement. The rest of the illustration shows a tympanic membrane 66 , the inner ear bones hammer 73 , as well as cut parts of the outer ear and the inner ear, which surround the eardrum 66 are around.

The microphone device 70 is on or in the eardrum 66 arranged so that they are the eardrum 66 covered or replaced. The microphone device 70 includes in the manner explained above, a plurality of acoustic sensors, which are arranged spatially distributed so that they allow the detection of spatial information of the surrounding scarf. It can therefore be limited or even unusual function of the eardrum 66 serve as the earliest possible eardrum replacement.

The microphone device 70 is with a transformer 71 connected to the output signals of the microphone device 70 go. The transformer 71 provides signal processing, signal amplification, and signal transformation functions as needed. He transmits the recorded acoustic signals to the eardrum 66 if it is basically functional, or other parts of the hearing aid if there is no functioning eardrum.

ever according to the scope of the device, the natural function of the eardrum with it or replaced. The power supply of the device can for example, by battery or accumulator, or the Energy required for operation can be supplied from outside of the ear canal located energy source, eg. B. one behind the ear to be worn external unit, about one - not shown - cable or wirelessly transmitted become.

In 9 is the planar microphone device previously described as eardrum replacement or support 70 shown in more detail in detail. It includes a variety of acoustic sensors 72 , which are arranged spatially distributed. The acoustic sensors 72 take ambient sound signals. The output signals of the individual or grouped acoustic sensors 72 go to the transformer 71 to. The transformer 71 transmits the signals, possibly after signal processing and amplification, to the inner ear bone hammer 73 , If an intact tympanic membrane is present, the transmitter 71 the signals directly on the eardrum and thus indirectly on the hammer 73 transfer. Otherwise, the transfer can also directly to the hammer 73 respectively.

In the 10 . 11 . 12 Basic schematics of different MEMS transducers for recording acoustic signals are shown schematically.

In 10 a simple capacitive transducer is shown. Sound presents itself as an oscillating force on the transducer and is therefore as a spring 81 illustrated. The spring force acts on the capacitor plate used as a transducer membrane 82 , Between the capacitor plate 82 and the further capacitor plate 83 there is a voltage. Will the capacitor plate 82 now by the force of the spring 81 (ie the sound) moves, the distance between the two capacitor plates changes 82 . 83 to each other and thus the capacity of the capacitor formed from the plate pair. This capacitance change is measured, which is an indirect measure of the causative force of the sound.

In 11 is shown a slightly more complicated structure of a capacitive pickup. As explained above, the sound is transmitted through a spring 81 illustrated. However, the capacitor applied by the force of the sound is designed to increase the capacitance and the changes in capacitance caused by sound in a comb structure in which the teeth of the comb designed as the transducer diaphragm 84 with the teeth of the wider crest 85 interlocked, ie interlock. Between the crests 84 . 85 As previously explained, a voltage is applied and upon application of sound capacitance changes are caused which are measured.

In 12 a construction of a piezoresistive transducer is shown in cross-section. A transducer membrane 86 made of piezoresistive material is transformed by the turn as spring 81 illustrated power of sound applied. The transducer membrane 86 is on a carrier 89 applied and located in front of a cavity 87 , Behind the cavity 87 is located in the carrier 89 a barometric compensation opening 88 , The arrangement allows the transducer membrane 86 to move when exposed to sound. The on the transducer membrane 86 acting force or movement of the transducer membrane 86 due to the piezoresistive properties of the membrane material leads to a change in the electrical resistance (piezoresistivity) that is measured, which is an indirect measurement of the causative force of the sound.

The invention can be summarized as follows: The invention relates to a hearing aid with a microphone device. With conventional microphone devices, a natural spatial hearing impression can only be simulated to a limited extent. An object of the invention is therefore to provide a hearing aid with a microphone device, which provides improved spatial detection of ambient sound allows. A basic idea of the invention consists in a hearing aid with a microphone device comprising a planar arrangement of a multiplicity of acoustic sensors constructed in MEMS technology (microelectromechanical system), wherein the signal processing device controls the multiplicity of sensor signals depending on a spatial arrangement of the sensors processed. An advantage of this basic idea is that the planar extension and the multiplicity of acoustic sensors enable a more accurate and precise spatial detection of the ambient sound. The MEMS technology allows serial or mass production with high availability and low costs. According to an advantageous development of the basic concept of the invention, the microphone device is designed as a flexible film and contoured such that it can be inserted into the auricle of a hearing aid wearer. According to a further advantageous development of the basic idea of the invention, the microphone device is designed to be inserted into the auditory canal of a hearing aid wearer instead of the eardrum or the eardrum.

Claims (6)

Hearing aid comprising a microphone device, a signal processing device and a receiver, characterized in that the microphone device consists of a surface-extended arrangement of a plurality of built in MEMS technology (micro-electro-mechanical system) acoustic sensors that the signal processing means as input signals a plurality of Receives sensor signals from individual sensors or combined into groups sensors of the microphone device, and that the signal processing device processes the plurality of sensor signals in response to a spatial arrangement of the sensors. hearing aid according to claim 1, characterized in that the microphone device from an array of at least 5 by 5 acoustic sensors consists. hearing aid according to one of the preceding claims, characterized in that the microphone device has a thickness of at most 3 mm. hearing aid according to one of the preceding claims, characterized that a case is included, and that the microphone device is arranged on or on the housing is. hearing aid according to one of the claims 1 to 3, characterized in that the microphone device as flexible film executed and contoured so as to be inserted into the pinna of a hearing aid wearer can be. hearing aid according to one of the claims 1 to 3, characterized in that the microphone device thereto is formed, instead of the eardrum or covering the eardrum in the ear canal a hearing aid wearer used to become.

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