DK149294B - MICROPHONE UNIT FOR APPLICATION IN A HEARING DEVICE - Google Patents

Description

149294

BACKGROUND OF THE INVENTION The present invention relates to a microphone unit for placement in a hearing aid and having a membrane which is influenced by sound over a first sound opening on the front and a second sound opening on the back, as well as with two mutually spaced sound inputs in the wall of the hearing aid housing. which a first sound input is in acoustic connection with the first sound opening, and the second sound input is in acoustic communication with the second sound opening, wherein the acoustic connection from the second sound input to the second sound opening can optionally be released and blocked to obtain a mode of operation respectively with and without directional characteristics and with a means for affecting the frequency response of the microphone unit.

Various types of hearing aids having non-directional or spherical characteristics are known, and other types of hearing aids having directional dependent characteristics are known.

2 149294

Further other hearing aids are known which can be used either as directional hearing aids or as non directional hearing aids by appropriate modification of the structure. However, such other readable hearing aids that can be used either as directional or non-directional devices have the distinct disadvantage that when the hearing aid is used as a non-directional hearing aid it will have a given frequency characteristic and when the hearing aid is used as a directional dependent device. it will have a completely different frequency characteristic. Eg. shows the curve or characteristic A in FIG. 3 is a typical characteristic of a non-directional apparatus in which the lower frequency portion of the curve is relatively flat and then drops off at the higher frequencies. Curve B shows the frequency characteristic of a direction-dependent apparatus, where the frequency curve rises from a low value as a relatively straight line to a maximum level and then decreases at the higher frequencies.

It is the object of the present invention to provide a microphone unit for use in hearing aids which can operate either in a directional or non-directional manner, but which has substantially the same frequency characteristic of sound arriving from the preferred direction, whether it works in a directional or non-directional way.

This is accomplished by designing the microphone unit as set forth in the characterizing portion of claim 1.

The invention will now be explained in more detail with reference to the drawing, in which fig. 1 is an isometric view with parts cut away of an embodiment of the microphone unit according to the invention; FIG. 2 is an isometric view of the microphone unit positioned reverse or face down with respect to FIG. 1 to better show the closure element for the audio input; FIG. 3 typical characteristics of previous direction-dependent and non-direction-dependent apparatus, where the ordinate axis indicates output power in decibels and the abscissa axis indicates frequency; 4 shows another embodiment of the microphone unit according to the invention mounted in a hearing aid of the type arranged to be placed behind the ear; FIG. 5 shows a further embodiment of a microphone unit according to the invention; FIG. 6 shows yet another embodiment of a microphone unit according to the invention; FIG. 7 shows a further embodiment of a microphone unit according to the invention, and Figs. 8 and 9 have characteristics useful for explaining the function of the structure of Figs. 5 and 6, with the ordinate axis indicating output power in decibels and the abscissa axis indicating frequency.

It should be noted at the outset that the present invention is generally applicable to head-mounted hearing aids including the type of glasses fitted as shown in FIG. 1 and 2, and the type for placement behind the ear as shown in FIG. 4 and 7.

Pig. 1 shows a microphone unit 11 according to the invention mounted in the rod part 12 of a hearing aid type 10 of the glasses. The rod portion 12 has a recess 13 in which a microphone capsule 15 is mounted on a suitable insulating pad 18 in a well-known manner. The microphone capsule 15 has an acoustically sensitive membrane indicated by a dotted line 14 and a transistor not shown connected to the membrane. Both the membrane and the transducer are well known in themselves. The recess 13 is formed in a relatively reverse position, i.e. the top of the recess may be fully closed, and sound openings or sound inputs 17 and 19 may be formed in the bottom cover 16. The sound inputs 17 and 19 are spaced along the longitudinal axis of the rod 12, and thus in a forward and backward direction with respect to the carrier. .

The audio inputs 17 and 19 are positioned downwardly to allow drainage of the recess 13 to prevent moisture or condensation water from accumulating therein and to reduce the ingress of dust or dirt into the recess, the direction in which the sound inputs 17 and 19 are facing, can be varied, the only limitation being that the inputs must be in line with the preferred direction of sound reception.

FIG. 2 shows an inverted view of FIG. 1 to better illustrate the movable or displaceable closure means 28 which selectively closes the audio input 19 for the purpose described below.

The closure member 28 is slidably mounted on the rod portion 12 and may be of any suitable type, provided it is selectively adjustable for closing and opening the rear audio input 19. Other means, such as a plug, for covering or closing the audio input 19 may is used instead of the closing means 28.

As explained in more detail below, when the audio input 19 is closed, the microphone unit 11 operates as a pressure-sensitive member with non-directional or spherical characteristics. When the audio input 19 is open, the microphone unit 11 acts as a directional means having its greatest sensitivity to sound coming from a forward direction relative to the carrier, and least sensitivity to sound coming from some backward direction in relationship with the wearer.

As shown in FIG. 1 and 2, the microphone capsule 15 has a first or front audio port 25 and a second or rear audio port 27. The audio ports 25 and 27 provide sound to opposite sides of the membrane 14. The microphone capsule 15 may be of the type shown, for example, in OSA patent no. 3,577,020 modified to have two input ports which, as mentioned above, are connected to opposite sides of the membrane 14.

One end of an elongated audio conductor 21 is connected to the audio input 17, and the other end of the tube 21 is connected to the audio port 25. The tube 21 thus directs or directs the sound entering the audio input 17 directly to the audio port 25 of the microphone 15. The tube 21 is connected through an acoustic impedance 34 which may comprise an acoustic material disposed over the aperture 33.

The rear audio input 19 leads to an acoustic cavity 22 formed in the recess 13. The cavity 22 again communicates with the second audio port 27 of the microphone capsule 15. An acoustic passage 26 transmits sound between the opening 33 of the tube 21 and the cavity 22. Sound which thus enters the front audio input 17, thus has a controlled acoustic leakage path leading through the aperture 33 and the acoustic impedance 34, the passage 26, the cavity 22 to the sound port 27 of the microphone capsule 15. When the closure means 28 is in the one shown in FIG. 1 and 2, the rear audio input 19 is open and the unit according to the invention operates in a direction dependent manner, i.e. such as a pressure gradient microphone, where the sound entering through the two spaced-apart LV inputs 17 and 19 undergoes a phase shift to provide directional characteristics.

Briefly, sound coming from a given direction, e.g. frontal direction or from the left as shown in FIG. 1 and 2, be effective at the sound input 17 to transmit through the tube 21 to the sound port 25 of the microphone capsule 15 and the front of the diaphragm 14. A discrete time later, the same sound stimulus or information bit will be effective at the sound input 19 to transmit through the cavity 22 and the rear audio port 27 of microphone capsule 15 to the rear of diaphragm 14. As in the prior art, audio port 27 and microphone capsule 15 have an impedance element to provide a suitable phase shift or acoustic time delay to form a direction-dependent characteristic which is maximum in a forward direction and minimum. in a backward direction.

Sound energy is also transmitted from the front audio input 17 through the parallel path comprising aperture 33, passage 26, cavity 22 to the rear audio port 27 and diaphragm 14. The relative acoustic impedances of the passages between the audio input 17 and the acoustic element 34 and between the audio input 19, however, the acoustic element 34 is selected to be small relative to the acoustic impedance of the connection through the acoustic element 34. The sound pressure at the sound port 25 from sound entering the input 17 is consequently substantially unaffected by the the presence of the element 34.

The inverse relationship applies to the effect of sound entering through the sound input 19. The element 34 thus has the effect of isolating or obstructing sound entering through the sound opening 19 in substantially affecting the sound pressure at the gate 25.

Similarly, the sound pressure at port 27 is substantially unaffected by the presence of element 34.

Therefore, in the direction-dependent mode of operation, the relative effect of sound entering through the sound input 17 and operating at the back of the diaphragm 14 is minimal, and the effect of sound entering through the sound input 19 is maximal.

When the closure member 28 is moved to close or cover the rear audio input 19, the sound enters only through the front audio input 17, and the microphone unit 11 acts as a non-directional or circular means.

In this non-directional mode of operation, sound enters through the front audio input 17 and usually passes through the tube 21 and the sound port 25 to the diaphragm 14. Sound entering through the front audio input 17 also passes through the opening 33, the acoustic impedance 34, the passage 26, the cavity 22 and the rear audio port 27 to act on the back of the diaphragm 14.

The value of the acoustic impedance in the element 34 is chosen such that, in cooperation with the cavity 22, it produces a phase shift or delay of the sound wave as it arrives at the sound port 27 which is equivalent to the delay of the sound originating from a forward direction, it passes between the sound input 17 and 19 outside the capsule 15. It is noted that the cavity 22 is essentially a rigidly closed tube providing an acoustic response, provided that the dimensions of the cavity are small compared to the wavelength. For sound arriving from the forward direction relative to the apparatus, the differential sound pressure of the diaphragm 14 is substantially the same, whether the rear audio input 19 is open or closed. It should be noted that sound arriving from an undesirable direction is 6 149294

Will be relatively muted when input 19 is open. Thus, the microphone unit according to the invention can operate either in a directional or non-directional manner without changing its frequency characteristics for sound coming from the forward or desired direction. A major feature of the invention is that if the microphone unit of FIG. 1 and 2 operate in a direction dependent manner, the characteristic is essentially the curve or line B of FIG. 3, and what is important when the microphone unit operates in a non-directional manner, curve B is also obtained.

FIG. 4 shows another embodiment of the microphone capsule 35 according to the invention mounted in a hearing aid 36 of the type for placement behind the ear, which is arranged in an acoustically permeable closure 40, and this hearing aid includes appropriate amplification means, receiver means and a battery in and for say well known way. The microphone unit of FIG. 4 may be designed as shown in FIG. 5 and 6.

The microphone capsule 35, as shown in FIG. 5 also work in a directional and non-directional manner and have similar frequency characteristics, whether operating in one way or another. The microphone capsule 35 comprises a unit which in itself includes means for adjusting the directional and non directional dependent characteristics. The microphone capsule 35 can e.g. mounted in an open recess in a hearing aid as in FIG. 4, or it may be conveniently placed in a recess in an associated hearing aid housing, such as in FIG. 1 and 2, wherein the upper cover 37 forms part of the hearing aid housing.

The top cover 37 of the microphone capsule 35 has a short tube forming a front audio input 41, and a second short tube spaced from the first tube to form a rear audio input 45 therein. The tubes at the sound inputs 41 and 43 can be used as connecting tubes. The orientation of the microphone capsule 35 may similarly as mentioned above be such that the sound inputs 41 and 43 face downward or sideways, provided that there is a relatively forward and backward distance between the sound inputs 41 and 43 to obtain a characteristic with maximum directional effect. or sensitivity in the desired direction relative to the user or carrier.

For the purposes of the following description, the microphone capsule 35 will be considered to be mounted for operation in the orientation shown.

The microphone capsule 35 contains a suitable diaphragm 45 arranged to divide the microphone into a first audio cavity 47 and a second audio cavity 49. The first audio cavity 47 abuts the front or front surface of the diaphragm 45 and interacts with the front audio input 41. The second audio cavity 49 abuts the back of the diaphragm 45 and interacts with the rear audio input 43.

A removable plug 39, when inserted into the input 43, prevents access for audio through the audio input 43.

A partition 51 is provided to form an acoustic seal between the upper and lower portions of the microphone unit 35 except for an opening on its lower left side 53 which permits direct connection between the sound input 41 and the sound cavity 47.

An acoustic seal flange or partition 57 divides the space between the partition wall and the top surface 37 of the microphone capsule 35 in substantially a first or anterior chamber 54 and a second or posterior chamber 56. A sound aperture 59 is formed on the flange 57, and a suitable acoustic impedance such as a a piece of cloth, screen material, a slit or porous material is disposed over the opening 59. The diaphragm 45 is attached to some suitable non-shown transor to activate the associated electronic circuitry in a manner well known in the art.

During operation and with the closing member 39 in position as shown in FIG. 5, the microphone capsule 35 functions as a directional dependent microphone with maximum sensitivity to sound coming from a forward direction along a longitudinal line between the audio inputs 41 and 43. In this mode of operation, sound coming from the forward direction will enter through the front audio input. 41 and pass through to the cavity 47 to act on the face of the membrane 45. A discrete time later, the same audio bit will enter through the rear audio input 43 into the cavity 56 and pass through the sound port 55 into the cavity 49 to act on the back of the diaphragm 45. Sound port 55 contains appropriate acoustic impedance means for providing a phase shift or delay for sound passing therethrough so as to provide a direction dependent characteristic. The relative acoustic impedances of the passage between the sound input 41 and the acoustic element 59 and between the sound input 43 and the acoustic element 59 are selected to be small relative to the acoustic impedance of the connection through the acoustic element 59. The sound pressure in the cavity 47 and Consequently, on the face of the membrane 45 from sound entering through the sound input 41 is substantially unaffected by the presence of the element 59. The inverse relationship applies to the effect of sound entering through the sound input 43, i. the element 59 has the effect of isolating or obstructing sound entering through the sound input 43 into the wall.

a U9294 δ

Significantly affecting the sound pressure in the cavity 47.

When the apparatus of FIG. 5 is to operate in a non-directional manner, the closing member 39 is moved to close the rear audio input 43. In this mode of operation, sound is transmitted to the diaphragm 45 only through the audio input 41. Sound entering through the audio input 41 passes to the front audio cavity. 47 to act on the face of the membrane45. Sound entering through the front audio input 41 also passes through the acoustic impedance of the sound opening 59 to the rear chamber 56 through the acoustic element 55 and the rear cavity 49 to act on the back of the diaphragm 45.

The aperture 59 provides a relatively high acoustic impedance. Accordingly, the phase shift produced by the acoustic impedance of the opening 59 and the chamber 56 can be selected to correspond to the phase shift of the sound moving outside the microphone capsule 35 between the sound input 41 and the sound input 43.

Stated otherwise, the impedance of the aperture 59 is too large an impedance to appreciably affect the sound pressure in the cavity 56 while the audio input 43 is open. In the operating state where the sound input 43 is closed, the impedance formed by the opening 59, in combination with the impedance of the chamber 56, provides the additional phase shift that the sound wave undergoes as it moves from the sound input 41 to the sound input 43 in the free space outside the microphone capsule.

If the chamber 56 is relatively large compared to the cavity 49, the effect of the microphone capsule 35 is substantially the same as that of the microphones of FIG. 1 and 2, i.e. For forward-sounding sound, there is a minimal difference in working characteristics, whether the microphone operates in the directional or non-directional fashion. However, if the chamber 56 is relatively small compared to the cavity 49, the transition from one mode to the other will have an effect on the upper end of the frequency characteristic. More specifically, in the latter case, the characteristics of the microphone capsule 35 are shown in FIG. 8, i.e. when the microphone capsule 35 operates in a directional manner, its output power is as indicated by line D, and its output power, when operating in a non-directional manner, is indicated by line N which drops off at a lower frequency than line D.

When the microphone capsule 35 operates in a non-directional manner with the audio input 43 closed, the acoustic transmission in the passage that can be followed from the audio input 41, the opening 59 and its acoustic resistance, the chamber 56 and the input port 55 to the rear of the memory 45 , as indicated above, substantially corresponds to the pre-arriving sound entering through the rear audio input 43, the chamber 56 and the rear audio port 55 when the audio input 43 is open.

A further embodiment of the invention is shown in FIG. 6, wherein the microphone capsule 65 is configured as the microphone capsule of FIG. 5. A main modification of the construction of FIG. 6 relative to the structure of FIG. 5 consists in the closure means serving to close the rear audio input 43A being different, and furthermore, the flange 57 and the aperture provided therein providing an acoustic impedance are omitted. A further minor difference is that the audio inputs 41A and 43A are not provided with the connected short tubes. In FIG. 6, a pivoting plate is mounted so that it is movable from a vertical position, as shown by fully drawn lines, to a horizontal position, as shown by dashed lines. The plate 67 can be adjusted, for example, by a suitable button 69 to a vertical position to keep the audio input 43A open or to close or prevent sound from passing from the front audio input 41A and the chamber to the sound port 55A. In this mode of operation, both audio inputs 41A and 43A are open and the microphone 65 acts as a directional means as described above.

By adjusting the button 69, the plate 67 can be moved or adjusted to its horizontal position or orientation to prevent sound from passing through the rear audio input 43A. In this mode of operation, the microphone 65 acts as a non-directional means.

When the plate 67 is in its horizontal position designated 67A, sound passing through the front audio input 41A, through the passage or chamber 66 to the sound port 55A, occurs. A very small phase shift or time delay occurs in a passage such as this not completed. so as to absorb considerable energy.

The overall phase shift between the sound reaching the front of the membrane in the cavity 47A and the back of the membrane in the cavity 49A is essentially that due to the acoustic element 55A and the cavity 49A. The result is some loss in the forward sensitivity, but a very small change in the frequency characteristic as shown in fig. 9. In Figure 9, the characteristic curve D is provided with the microphone capsule 65, operating in a directional manner, and the characteristic curve N is provided with the microphone capsule 65, operating in the non-directional manner. The curves D and N are similar in shape but represent different sensitivities. If the direction-dependent character is a cardioid curve, this offset when operating in a non-direction-dependent state is approx. 6dB.

Yet another embodiment of the invention is shown in FIG.

7, wherein a microphone capsule 75 is shown disposed in a suitable recess 77 in a hearing aid 79 of the type for placement behind the ear. Microphone capsule 75 contains a suitable diaphragm diaphragm with diaphragm 14 of FIG. 1. The capsule 75 is mounted on a suitable insulating pad 76. A recess 77 has a cover 88 with a front audio input 79 and a rear audio input 81 formed therein. A suitable closure means 84 is slidable to selectively open and close the rear audio input 81. The microphone 75 has a front audio port 83 which communicates with one side of the diaphragm 86 and a rear audio port 85 which communicates with the other. side of the diaphragm 86, the latter port being provided with a suitable acoustic impedance.

An acoustic impedance member 91 is arranged in the space between the hearing aid housing and the microphone so as to divide the recess 77 into a front acoustic cavity 87 and a rear acoustic cavity 89.

Acoustic impedance 91 performs the same function as acoustic impedance 34 of FIG. 1. The operation of the apparatus of FIG. 7 is substantially the same as described above for FIG. First

When the closure means 84 is in the position shown in FIG. 7, the apparatus of FIG. 7 in a direction dependent manner, and as the closure means 84 is moved to close the rear audio input 81, the apparatus of Fig. 7 operates in a non-direction dependent manner.

The acoustic impedance 91 is selected in the same manner as discussed above to have minimal effect on the sound pressure in the two cavities 87 and 89 when the sound input 81 is open and to cooperate with the cavity 89 to produce a further phase shift. when the audio input 81 is closed.

The construction of FIG. 7 conveniently allows the cavity 89 to be larger than the cavity 92 of the microphone capsule 75, the last cavity being located behind the acoustic element of the audio port 85. The foregoing ensures that there will be minimal difference in sensitivity and frequency characteristics regardless of the the setting of the closure means 84.

Claims (8)

11 149294 Patent Claims. 1. Microphone unit for placement in a hearing aid (lO, 36.7o) and with a diaphragm (14,45,86) which is influenced by sound over a first sound opening (25,53,83) on the front and a second sound opening ( 27,55,85) at the rear, as well as with two spaced sound inputs in the wall of the hearing aid housing, of which a first sound input (17,41, 79) is acoustically connected to the first sound opening, and the second sound input ( 19,43,81) is in acoustic communication with the second sound opening, whereby the acoustic connection from the second sound input to the second sound opening can optionally be released and blocked to obtain a mode of operation with and without directional characteristics and with a means for effecting frequency of the microphone unit, characterized in that a sound path (22,56,89) forming an acoustic auxiliary extends from the first sound input (17,41,79) to the second sound opening (27,55,85) and is provided with an acoustic impedance (34.59, 91) which is sized for an acoustic adapter ash to obtain the same frequency response in both modes of operation. Microphone unit according to claim 1, characterized in that the sound transmitted from the first sound input (17,41,79) to the second sound opening (27,55,85) has minimal effect on the released acoustic connection. Microphone unit according to claim 1 or 2, characterized in that the sound entering through the two audio inputs (17,41,79,19, 43,81) is effective at the rear of the diaphragm (14,45,86) with different sound pressures. Microphone unit according to any one of claims 1-3, characterized in that an acoustic impedance is provided in the second sound aperture (55) to produce a phase shift. Microphone unit according to any one of claims 1-4, characterized in that the acoustic connection is interlockable by an adjustable plate (67). Microphone unit according to any one of claims 1-5, characterized in that the second audio input (19,43,81) is optionally open and closed. Microphone unit according to any one of claims 1-6, characterized in that the first sound input (17) is connected to the first sound opening (25) over an elongated tube (21). Microphone unit according to any one of claims 1-6, characterized in that the diaphragm (45) is arranged in a housing with a chamber (47, 49) on the front and the back respectively, that a partition ( 51) so that two separate ends are formed.