DE2361595A1 - Hearing aid with directional microphones - has at least two microphones connected in series opposing in hearing spectacles - Google Patents

Abstract

In the first embodiment two microphones are provided for directional reception of sound. Alternatively, the sound is applied to both sides of a single microphone or of sound paths to microphone and/or of sound entry apertures are so staggered in the forward direction, that a noticeable propagation time difference is produced, and the sound waves coming from the front reach the rear microphone or the diaphragm rear side with a delay of a half wavelength of a mid-frequency of the transmission range, or of the middle speech range (1500-2500 Hz). When sounds come from a side or from the back, the delay is less than half wavelength as above.

Description

Hearing aid with directional microphone, especially hearing glasses

The present application relates to hearing aids, especially hearing glasses, which are equipped with a directional microphone arrangement.

The development of hearing aids has the goal in recent years had to make the devices as small as possible and place them inconspicuously. But many people with hearing loss attach more importance to it Participate in a large-scale conversation, in a noisy environment, or at a party in a satisfactory manner can. When there are many sources of sound around the hearing impaired he has the impression of a noisy rumbling, so that he can understand individual speakers or presentations difficult, even impossible.

Hearing aids are known which have a directional microphone with a cardioid diagram own, but these devices bring limited improvement. Fig. 1 shows such a diagram in principle. The spatial reception angle is significantly greater than 180 ° and almost 240 ° with a slight drop. In an anechoic room, this diagram can be used to achieve a noticeable improvement over a microphone with a circular diagram will. On the other hand, there is almost no improvement in the usual rooms with reflective walls, since the one from behind The sound coming from it is reflected on the walls in front and on the sides and recorded by the cardioid diagram.

This is to be explained with reference to FIG. 1.

The area of the cardioids is divided into three sectors in which One speaker each X, Y and Z should be assumed. In the empty one A sound source Q should be located in the sector. ¥ om cardioid microphone the speakers X, Y. and Z are recorded in any case as well as the wall surfaces x, y and ζ of the wall surfaces in the background reflected parts q of Q, namely qx, qy and qz.

The speaker Y is desirable, which is unavoidable _; the reflected part qy. It would be a success if we succeeded in eliminating sectors X and Z and thus also qx and qz «

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In principle, this would be with an eighth shape of the reception diagram to reach. Such a diagram, however, brings preferred reception from the directions 0 ° and 180 °. So there still have to be further measures can be applied to achieve the goal.

The following operational characteristics are aimed at with the proposal:

1. A noticeable increase of Frequencies from the middle language range (1000 - 2500 Hz) can be reached

2. At the same time, from the direction of 0 °, the Amplitudes of the lowest frequencies can be achieved.

3. From the 90 ° lateral direction, the amplitudes of all frequencies should be reduced as much as possible.

4. From the backward direction 180 °, the amplitudes of all frequencies should also be reduced if possible.

The deep basic noise, the hard of hearing at a party and The like torments, should above all be largely reduced. The actual information is in the middle or medium high Frequency range of speech (1000 - 3000 Hz) This should preferably be conveyed to the hearing impaired »'The low frequencies experience has shown that they are dispensable.

The present deregistration is based on hearing aids, the two microphones in counter-circuit or one microphone on both sides have a loadable membrane and two openings for sound absorption.

The requirements 1 and 2 are to be met in that the microphones and / or Bchall openings are arranged so that the Path difference for the sound from the direction 0 ° for one lying in the speech range and transmission range of the device Frequency has the value Λ / 2. The neighboring sequences - 500 Hz are also raised.

In order to be able to meet conditions 3 and 4, the path difference for two microphones that belong together must not be so great that a λ / 2 is achieved for a frequency in the transmission range of the device, otherwise the side and reverse reception will be suppressed instead. due to the negative feedback) an increase as would take place from the pre-alignment.

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The differences in side and reverse reception (90 ° and 180 °) between the cooperating microphones must therefore should be kept as small as possible and may not exceed 3.5 cm. (A = 7 cm; f = 4700 Hz) Path differences are useful 3.0 cm (f = 5500 Hz) or less. The upper end of the transmission range is with most Gerriten at about 4000 Hz. In the case of need, you could set the limit set to 3500 Hz, as is customary and has proven itself in telephone operation.

So that the rel. long detour for the sound from the pre-alignment not be effective to the same extent for reverse reception the return path is to be laid in such a way that the sound only traverses part of the forward path for each reception from the direction of 180 ° is.

For the microphones whose output voltages are switched against each other should be, it must be ensured that they are as far as possible at least in the range between 500 and 3500 Hz in the .Amplitudekurve match, but above all have no mechanical or electrical resonances, as these are mostly uncontrollable bring additional phase angles with them.

The arrangement is expedient to be set up in such a way that instead of two Separate microphones a microphone with both sides at% fschlagbaren Membrane is used. In this case, resonance centers can be approved under certain circumstances, as these coincide.

The relevant requirements are to be discussed and implementation options are to be explained using a few examples.

The microphones M can be attached to glasses at the following locations be. Fig2 »On the temples B and / or on the front side F, especially on the nose bridge. between the glasses G. The sound openings 0 can be attached similarly, preferably to the bracket B. The microphones are in the shape of small squares and the sound openings indicated in the form of small triangles, ovals or circles.

Amplitude variators can be installed in the output lines of the microphones A in the form of attenuators or amplifiers and, if necessary, phase correction elements Ph can also be inserted.

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In order to be able to set the degree of the negative feedback between 100% and 70 fo , for example, the amplitude can also be changed with the aid of the nature of the sound lines L, the conduction capacity of which can be selected accordingly.

The distance between the "two related microphones "is Λ / 2 measured in Yororientation. At d§Jiseni Laußreg— differed and due to the opposing switching of the microphones, an addition occurs, while for frequencies supplied an addition occurs Subtraction takes place.

The detour U describes the distance that the sound has to travel after reaching the nearest microphone, to get to the other microphone, that of the respective Sound source is further away.

In the drawings, the temple B is stylized into a measuring beam of 10 units - corresponding to the length of 10 cm.

FIGS. 3a-3c show a microphone arrangement in which the rear sound opening Oh has moved almost to the end of the horizontal part of the bracket B. The front microphone 1 including Opening Ov is located approximately at the end of the first third of the bracket.

For the Yororientation 0 (Fig. 3a), the detour Uv for the sound up to microphone 3 from the air gap Sv (calculated from microphone 1) and line L3 together.

Uv = Sv + 13 = 7.0 + 3.5 = 10.5 cm λv / 2 tv = 1570 Hz Pur the lateral direction 90 ° (Fig. 3b) the detour Us to the microphone 3 consists of the line L3

Us = L3 = 3.5 cm - As / 2 fs = 4710 Hz

For the backward direction 180 (FIG. 3c), the detour Ur is calculated from the distance between the microphones 1 and 3, which was assumed to be 3.5 cm.
Ur = 3.5 cm } \ τ / 2 fr = 4710 Hz

FIGS. 4a-4e show a microphone arrangement in which the rear viewing port Oh at the end of the curved part of the The temple is behind the ear and the front sound opening Ov is slightly in front of the ear. The temple can do something for that be extended in such a way that it is not directly behind the

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Pinna, s _o Change-A with a "t Terlängerung backwards approximately in the middle of the ear ends.

Fig. 4a shows the construction principle. FIGS. 4b-4d serve to illustrate the sound paths.

For the pre-alignment O ⁰ (FIG. 4 "b), the detour TJv for the sound" up to the rear microphone 3 is composed of the horizontal part of the air path Sv and the line 13.

The horizontal distance between the microphones is 4 cm.

Sv is calculated as 4.0 + the horizontal part of L3, which results in Sv = 4.0 + 2.0 = 6.0 cm

Uv = 6.0 + 3.0 = 9 cm Λ v / 2 fv = 1835 Hz

For the lateral direction 90 ° (FIG. 4c), the detour Us to the microphone 3 consists of the line L3. (The microphones 1 and 3 as well as the openings Ov and Oh are assumed to be in one plane)
Us = L3 = 3.0 cm. \ s / 2 fs = 5500 Hz

For the reverse direction 180 ° (FIG. 4d) there is the detour Ur to microphone 1 from the horizontal Ted. the distance between Ov and Oh, from which the conduction path L3 has to be subtracted, Ur = Sv - 3.0 = 6.0 - 3.0 = 3.0 Ar / 2 fr = 5500 Hz

Fig. 4e is intended to show the amplitude curve as a function of the Illustrate frequencies.

The output amplitude aider oppositely switched microphones 1 and 3 are drawn on a linear scale in order to be able to see the essentials more clearly.

The horizontal line represents the idealized amplitude curve of the microphone 1 alone.

When placing both temples with microphones, you can Choose the distance between the microphones and / or sound openings differently on the two sides and thus widen the reception curve for 0 °.

The arrangements according to FIGS. 3 and 4 operate with separate Microphones. Switching the microphones in the same direction is recommended for broadcast reception. If you have both hangers equipped with microphones and their outputs correspond to the side

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feeds to one ear each, an advantageous stereo reception is possible, since in this case side reception is preferred and forward and backward reception is reduced correspondingly Λ / Ζ.

The arrangements according to FIGS. 5 and 6 work with microphones which have a membrane that can be acted upon on both sides. For the For broadcast reception it is necessary to close a channel or a sound opening and possibly adjust the gain.

The Pig. 5a-5c show an arrangement in which the two-sided microphone -J / 3 is arranged approximately in the middle of the bracket B. The opening Oh to the sound line L3 is approximately at the rear end the horizontal part of the handle. The anterior sound opening Ov is 1 cm in front of the microphone 1/3.

For the pre-alignment 0 ° (Fig. 5a), the detour Uv for the sound up to the membrane (3) consists of the air gap Sv and the line L3 together.

Uv = Sv + 3.5 = 4.5 + 3.5 = 8 cm Xv / 2 fν = 2060 Hz For the lateral direction 90 ° (Fig. 5b), the detour Us consists of the difference of 13-11 = 3.5-1.0 ρ 2.5 cm

2.5 = A ^§ / 2 fs = 6600 Hz

For the reverse direction 180 ° (Fig. 5c) there is the detour Ur from the air path Sr and the line L3

Ur = 1.5 + 1.0 = 2.5 cm Xr / 2 'fr = 6600 Hz

FIGS. 6a-6c show a microphone arrangement similar to FIG. 4, However, with the difference that a double-sided microphone 1/3 is used, the acoustically required a different structure m makes or makes appear advisable. The openings Ov and Oh. Have a distance of e.g. 4 »5 cm in the right of the Ifag. the Line 11 from Ov to membrane (1) is also 4.5 cm, the line from Oh to membrane (3) is 8 cm. These The line will be "wound" the directions 0 °, 90 ° and 180 °.

For d ± e. Pre-alignment, the Wige from Ov to Oh and from Ov to the membrane (1) are of the same length. Only line L3 can be used for the delay.
Uv = SV + L3 - L1 = 4.5 + 8.0 - 4.5 = 8.0 cm

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IJ-V = 8 cm \ v / 2 f V = 2060 Hz

Pur the lateral direction 90 ⁰ "is the detour Us from the difference of 13 - 11 = 8.0 - 4.5 = 3.5 fs = 4710 Hz

I ¹ Ur the reverse direction 180, the detour Ur to the membrane (1) consists of Ur = Sv + L1 - L3 Ur = 4.5 + 4.5 - 8.0. = 1.0 cm> r / 2 fr = 16,500 Hz

The latter construction allows only minor changes with regard to the frequency fv that is to be raised from the pre-alignment. On the other hand, it allows one special good suppression of the sound from the backward direction. Fig. 6c is intended to show the amplitude curve as a function of the ! Illustrate frequencies.

The output of the double-sided microphone 1/3 is in linear Scale drawn in order to be able to show the essentials more clearly.

The horizontal line represents (idealized) the amplitude curve when the diaphragm is only facing from side 1 Effect would be brought about.

It was already pointed out at the beginning that with the proposals an improvement over a Qardioid diagram, especially a reduction in reception from the directions 90 ° and 270 ° is aimed for.

In order to bring the side sound to a minimum without letting the rear sound emerge, the following arrangement is made recommended. ■

The microphone 1 or the microphones 1 + 2 are on the Uasenbügel Ii attached between the glasses G. The distances between the hare bar IT and the beginning of the side bar B are each according to construction 6.5 - 7.5 cm. For further considerations, a mean value of 7.0 cm should be used. On the Bracket B has a length of approx. 10 cm. Figure 7a

The line length, L between Oh and the associated microphone is available for the delay from the pre-alignment. Taking into account the side and backward sound, the length of the line 1 is measured to be 7 cm.
From Fig. 7b it can be seen that for the sound from the direction

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«- · Q -

up to the microphones 1 + 2 "or 4 each 7 cm away from the
Side edge of the glasses, of all things, are to be traversed.
From Fig. 7b it can also be seen that the backward sound of
the side edge of all things, up to the microphones 1 + 2 "or 3
also has to traverse a path of 7 cm.
With negative feedback of the output voltages, these would have to be in
Cancel the extent of the negative feedback.

The routes mentioned so far are not the only ones through which sound can reach the microphones.

On the hand of the pig. 8 it is shown that sound also comes from behind
can reach microphone 1 + 2 via the head or forehead. The sound from backwards washes around - especially for the deep ones
Frequencies applies - as it were to the head. If you go through the
outer corner of the eye thinks a vertical plane E, which is about 2-3 cm behind the front side F of the glasses, then this should serve as a reference plane for further considerations.
From a point above the forehead on this level E, the
Sound coming from backwards must cover a distance of approx. 8-10 cm to microphone 1 + 2. If you continue to insert the openings Oh for the microphones 3 and 4 on the temples B into these
Level E, then there are still about 7 - 8 cm on the hangers
available to the microphone. 9 shows the arrangement with the microphones just explained.

On the right side an elongated shell-shaped aperture R is indicated. There are reflectors and bezels in the glasses
"Executable quantities for low frequencies have no effect. This is also not necessary, since the negative feedback intervenes helpful with regard to the low frequencies. In the case of medium and medium-high frequencies
Frequencies can be achieved by relocating the microphone 1 + 2 to the
Nose clip and a lateral conch R already a diminution
the on% üime of the sound from backwards, so that one
can pay more attention to the lateral sound through paths of the same length as possible to the counter-coupled microphones
to diminish.

These. Reduction of the sound from the direction 90 is also preserved if the opening Oh is about 2 cmj from the front side F The glasses moved back, because amch then the way for the side. Sound for microphones 1 + 2 and 3 remain the same length.

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The detour TJv from the pre-alignment is then 2 cm. to 9 cm ■ extended so that the boost frequency is correspondingly lower lies. For the sound from the direction of 180 °, the detour Ur is no longer zero, but it remains very small.

If you occupy both sides of the temples with microphones and place the or the front microphone on the front of the glasses, you can compensate for the vibrations coming from the right to the left microphone and the vibrations from the left to the right microphone. Serve the Amplitudenvariatoren with which the interference compensation can be influenced in any descent Look _o This option is appropriate for singlesided listening with a Ohrtelephon.

The rel. strong negative feedback brings an increase (addition) of the amplitudes for frequencies in the middle language range and their neighboring sequences up to theoretical value of 2. This alone does not bring much, but at the same time the tensions of the low frequencies rel. strong are reduced, a considerable preference results for the desired frequencies. The available gain can thus be brought into full effect for the desired frequencies.

The frequencies selected in the arrangements and the location of the Sound openings and the microphones are only examples which, if necessary, can be modified within the framework of the proposals can be.

Combinations of the individual measures shown and described are entirely within the scope of this application.

Fig. 10 shows a simplified embodiment with a single microphone on both sides, which in principle corresponds to the arrangements according to FIGS. 7-9.

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Claims (14)

_ _1C _ 2381595 Expectations Hearing aid with directional microphone arrangement consisting of at least two opposing microphones or microphones with a membrane that can be acted upon on both sides and at least two sound openings, esp. Hearing glasses - characterized in that the positions of the microphones or the sound paths to the microphones and / or the Sound absorption openings are staggered in advance so that a noticeable difference in transit time between the recorded Oscillations with respect to the goal alignment arise in such a way that the sound waves coming from the front reach the rear microphone or membrane side with a delay corresponding to the value a / 2 for desired frequencies from the middle transmission range of the device ©. 2. Apparatus according to claim 1, .dad. gek. that the delay regarding the pre-alignment of half a wavelength corresponds to a frequency in the middle language range (1500 - 2500 Hz). 3. Apparatus according to claim 1 and 2, dad. approved that the line (s) to one or both microphones are dimensioned so that a propagation delay for vibrations coming from the side is smaller than the value A / 2 in the middle language area or in the Transmission range of the device lying frequency. 4. Apparatus according to claim 1 and 2, dad.gek. That the line (s) to one or both microphones is (are) dimensioned so that for from backward vibrations the propagation delay is smaller than the value of A / 2 one in the middle language range or in the transmission range of the device lies & the same frequency. 5. Apparatus according to claim 1, dad. gek. that the sound absorption openings are provided on the front side and / or one (the) temple side (s) of glasses and that the sound absorption openings directly and / or indirectly via pipelines to at least two microphones or the membrane sides of a double-sided microphone to lead. 6. Apparatus according to claim 1, dad.gek. That between the rear Sound opening Oh and the associated microphone "or membrane side a tubular, the delay of A / 2 essentially 509824/0788 "causing line is located in or on the bracket · is. (Pig. 6 to 9) 7. Device after. Claim 1, dad. gk. that "in front of the one in front Microphone or idembranseite is also a pipe. (Pig. 5 and 6) 8. Apparatus according to claim 1, dad. gek. that the distance between two 3 _c reverberation openings that belong together - measured as an air gap in the horizontal plane - is at least 4.5 cm, preferably more than 4.5 cm. 9. Apparatus according to claim 1, dado gek. That in arrangements in which the delay path (A / 2) is formed with respect to the pre-alignment essentially by an external air gap, the pipeline between the rear viewing opening Oh and the associated microphone or M _e The transfer side is at most 3.5 cm (Pig. 5.4 and 5) 10. Apparatus according to claim 1, dad.gek. That the related two sound openings one behind the other on the temple in the ear-.? near, ins / ^ bes. lie immediately in front of and behind the ear. (Pig. 3 to 6) 1t. Device according to claim 1, dad.gek. That the sound openings and / or microphones are partly on the hare arm and partly on the side arm of a pair of glasses. (Pig. 7 to 9) 12. Apparatus according to claim 10, dad. gek _o that in arrangements in which both sound openings are on each side of the bracket, the outputs of each side are fed separately to one ear and that a switch is provided which allows the microphones to be switched in the same direction. (Stereo operation) 13. & erät according to claim 11, dad. gek. that with orders, at where the sound openings are tetds on the front side and temls the side of the bracket, the outputs of all microphones are amplified together after a possible amplitude variation. fed to a single earphone. 14. Apparatus according to claim 1, dad. gek. that when using separate microphones into the output lines of individual microphones amplitude variators and / or phase elements are inserted as required. 509824/0788