FI62920B - MIKROFONENHET - Google Patents

Description

ΓΓΤ. · _ -N .. /4.ν KU RELEASE PUBLICATION. _ B (11) utläcgni ncsskrift 62920 c i4S) Patent evännet ly 10 03 1933 'Ss v— ^ (51) Kv.iit / int.a ^ * H 04- E 1/38 FINLAND — FINLAND (M) iwttOfkwnu »- r * m ** »6to * t 30ii / ik (22) Htk» nilip * lvt - AmMwhp <n 21.10.7 ^ (23) AlkupMvl — GiMglMttdat 21.10,7I * (41) Become Public - Mvlc off «Mllg 22.04. J6

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Patent and octane tyralane AmMcm uttagd och utUkrlfcM published 30.11.82 (32) (33) (31) FyjMtey «uoUuim — l« | M priorttac (71) A.R.D. Anstalt, P.O. Box 34613, 9490 Vaduz, Liechtenstein (LI) (72) Saad Zaghloul Mohamed Gabr, Canterbury, Kent, England-England (GB) (74) Oy Kolster Ab (54) Microphone Unit - Microphone

The invention relates to microphone units and in particular to those designed to operate substantially without echoes and interference sounds, such as ambient and field interference noise.

Except in relatively rare circumstances, the microphone unit in use is susceptible not only to incoming sound vibrations which it must convert into an electrical output signal, but also to sound and / or mechanical vibrations, e.g. from the engine of the vehicle in which the unit is installed, which should not form part of this output signal. . In some cases, when the microphone unit is used, for example, in a crowd or near machines, it is important to substantially completely eliminate harmful vibrations so that the unit can provide an output signal that can be understood when converted to sound through a speaker.

It is therefore an object of the invention to provide a microphone unit which has features which eliminate to a large extent or even completely the effects of undesired input sound - noise and echo - on the electrical output signal.

The invention provides a microphone unit comprising a pair of 2,62920 housings for mounting substantially identical electroacoustic transducers, each having a sound-responsive element, the housing forming two wires extending in opposite directions from each of the respective sound-responsive elements to the main sound input.

The microphone unit according to the invention is characterized by sound inlet portions between the sound-responsive elements and between each sound-responsive element and the associated main sound input opening.

Unwanted sound vibrations arrive at one or each transducer membrane or other sound-responsive element directly through the air and also through the microphone structure, i. through its housing and converters or other installation means of converters. The effect of the airborne noise on the microphone is reduced so that the noise is applied substantially evenly to both sides of the film, so that the sum of these interfering sounds in the movement of the film and thus in the output signal is substantially zero.

The effect of interfering sounds entering the membrane through a support and mounting structure connected to it can be reduced by making the structure of several parts consisting of three or more different materials and preferably so that a part of one substance is not adjacent to a part of the same substance. substantially unmanageable or "dead." Alternatively or in addition, two identical microphones, arranged as described in relation to the desired input sound, may be electrically connected so that the combined output signal is substantially free of the sound components produced by these interfering sounds.

Instead, when the unit is used with one or more speakers, such as a speakerphone or audio equipment in public places, the output signals of the two microphones can be analyzed, if desired, to separate substantially pure interference or unwanted components for rejection purposes. The invention then uses combined acoustic and electronic interference cancellation methods to deal with both direct and indirect, air-transmitted interference sound and a mechanical oscillation path through which random external interference sounds and echoes can affect the output signal from the microphone.

An understanding of the invention will be facilitated by the following illustrative illustration relating to the accompanying drawings, in which: Figure 1 shows a schematic cross-sectional side view of a microphone unit according to the invention, 62920 used in the unit.

Figure 1 shows a microphone device 10 including a tubular housing 12 open at both ends and including two electro-acoustic transducers 14, 16 used as microphones. The transducers 14, 16 may be of the winding or other suitable type. The transducer 14 shown is, by way of example, a revolving coil microphone with a substantially coplanar membrane 18, whereas the transducer 16 is of the same general type but has a conventional conical Calso 20. However, it is clear that the two microphones used in practice in the microphone unit according to the invention are similar due to symmetry. The diaphragms of the electro-acoustic transducers extend at right angles to the axis 12 of the housing.

The housing, which may have a circular or other desired cross-sectional shape, has two annular partitions 22 on which the transducers are mounted and an internal separator 24 which acoustically separates the two transducers. However, the separator 24 can be omitted. To allow random sound to enter the interior of the transducer, one or more openings are made in the housing wall and / or partitions 26 and 28, respectively. The separator 24 may also be provided with one or more openings, as in step 30. If desired, means can be used to selectively adjustment and which can preferably be easily operated from outside the housing.

The microphone unit is intended to be used with its other end facing the user's mouth, and to facilitate this it may further be shaped or provided with a handle. The other side of the closer microphone is thus directly exposed to the desired audio signals. In order to minimize the exposure of the second microphone to this desired sound, one or more external separators 32 may be used on the housing. The ends of the housing 12 may extend outwardly past the transducers, forming, if desired, filling chambers for the transducers, which may or may not be similar.

The output signals of the windings of the converters 14, 16 are connected in a reducing and different phase via potentiometers 34, so that the output signal of each microphone can be selectively adjusted. The output signal of the microphone unit is obtained from the terminals 36, and is the difference between the output signals of the microphones taken from the potentiometers 62920 meters 34.

The sounds hitting the microphone unit 10 can be divided into sounds that are parallel to the planes of the membranes 18, 20 and can be considered as interference or unwanted sounds, and sounds that are perpendicular to the membranes and can be considered as desired sounds. The previous sounds produce pulses on the two diaphragms that are identical in all respects, assuming that the diaphragms are close together and their spacing is comparable to the wavelength of the sounds. In practice, it has been stated that the distance should not exceed 1/4. the wavelength of the frequency or 1/4 of the wavelength of the highest frequency handled by the unit. The resulting forces are then substantially equal. For best results, of course, the distance should be kept even smaller.

The sounds hitting the unit, which run in parallel with the membranes, then cause the movement of both membranes, which is theoretically zero and normally negligible. In such insignificant electrical movements, the electrical signals become combined asynchronously, resulting in a substantially complete elimination of the electrical output signal they cause.

The input sounds, which are distributed perpendicular to the membranes, apply their greatest force to the membrane they first encounter. Of course, if a separator 24 is used, this sound does not affect the second film, and the sound running parallel to the film does not substantially alter the output signal from the film receiving this desired signal. If there is no separator between the two diaphragms, then the second diaphragm, which does not directly receive the incoming desired sound, moves with the former diaphragm due to the vibrations of this which pass through the air between them.

In practice, the microphone unit 10 is effectively echo cancelling. For example, a desired sound from a speaker holding the unit so that he is directly toward the second converter will be fully reproduced in the power output signal, as will speech from the second speaker opposite the first. Potentiometers 34 can be used to adjust the unit to compensate for its deviations from accurate electrical or structural symmetry around the central transverse plane of the housing 12. Although the unit shown in Figure 1 has two microphone transducers, the invention can be implemented in the form of a unit containing only one transducer.

Such a solitary microphone may be in the shape of the transducer 16 shown in Figure 1, but is preferably in the shape of a transducer 14 for more accurate symmetry, which may be achieved or accurately reproduced by reproducing a microphone supported on either side of the membrane 62920 or adding a dummy structure. In some respects, the unit of one microphone is made as symmetrical as possible, not only around the axis of the membrane, as is the unit shown in Fig. 1, but also around the plane of the membrane, which is of course in the middle position of the separator 30 in the unit of Fig. 1.

As in the unit of Figure 1, the arrangement of one transducer causes the ambient sound to be distributed substantially evenly on the two sides of the membrane and the speech or other desired sound to come substantially only to the other side. In either secret unit, there are no collecting, sound-guiding, or reflective devices, such as tunnels or barrier walls, that wobble between the bare sides of the film and the extension of the unit.

The structure of the housing or the nature and dimensions of the various parts of the unit do not theoretically affect the performance of the unit, but are preferably chosen to help eliminate the effect of noise and echoes as much as possible. The housing is thus preferably constructed as shown in Fig. 2, showing a tubular housing made of a plurality of rings or the like having inner and outer diameters arranged coaxially to form a tube. The rings are made of different materials A, B, C each of which has different sound-conducting properties. One ring can be made of metal, the next of fiberglass and the third of rubber or hard or soft plastic. The sound transmitted through one of the rings becomes substantially attenuated at the interface and the entire structure is effectively "dead" or non-microphone acoustically.

Instead of repeating e.g. the order, the metal glass fibers and the plastic rings, it is preferred that the same three substances are used in the next three rings, but in a different order, again according to Fig. 2. The next three rings can then again be arranged in a different order. In this way, there is a ring of a different substance on each side of each ring. Of course, this aspect of the invention is not limited to the use of only three substances, the use of the above-mentioned substances or any particular order of the rings.

It is obvious that the tubular microphone housing constructed as described has an almost infinite resistance to axially conducted sound. In contrast, the sound conducted radially in the housing in each ring will not be reduced at all more than if the housing had been made of a single piece of tire material. In order also to achieve the desired radially attenuated sound attenuation properties, the housing can be formed not only of axially adjacent single rings, but of axially adjacent, 6,62920 concentric rings, preferably of at least three in number and again of different materials, according to Figure 3.

It will be appreciated that the structure described for the microphone housing can be readily applied to housings of any shape and to housings and lower housings of devices other than the microphone unit described. For example, flat panels can be formed of several layers of different materials, which themselves consist of a part of a different material. The various components of the described housing can be connected together in any suitable manner, e.g. by means of binder layers or interlocking key connections, taking advantage of the inherent flowability of some of the materials used.

The invention can, of course, be applied in hearing aids to eliminate instability and unsatisfactory performance due to acoustic feedback, which occurs in these devices mainly through the microphone structure and mechanical vibrations.

The invention may, of course, be embodied in different ways and in a manner different from that described above, within the scope thereof.

Claims (22)

62920 7 A microphone unit (10) comprising a housing (12) for mounting a pair of substantially identical electroacoustic transducers (14, 16), each having a sound-responsive element (18, 20), the housing (12) forming two wires extending in opposite directions each of the respective sound-responsive elements (18, 20) to the corresponding main sound input port, characterized by sound inlet portions (26) between the sound-responsive elements (18, 20) and between each sound-responsive element (18, 20) and the associated main sound input port. Microphone unit according to Claim 1, characterized in that the membranes (18, 20) of the transducers (14, 16) are coaxial. Microphone unit according to claim 1 or 2, characterized in that the dimension of each conductor in the axial direction of the associated membrane (18, 20) is smaller than the smallest dimension of the conductor in the transverse direction of the membrane. Microphone unit according to one of the preceding claims, characterized in that the housing (12) has a baffle plate (24) between the transducers (14, 16), one of the additional sound input openings (26) being formed in each of the transducers (14, 16) and the baffle plate (24). Microphone unit according to Claim 4, characterized in that the transducers (24) acoustically insulate the transducers (14, 16). Microphone unit according to Claim 4, characterized in that the baffle plate (24) is provided with openings (30) / Microphone unit according to one of Claims 4 to 6, characterized in that the unit (10) is substantially symmetrical with respect to the baffle plate (24). Microphone unit according to one of the preceding claims, characterized in that the housing (12) is a tubular housing with main sound inlet openings at its ends and additional sound inlet openings (26) in the tubular housing wall. 8 62920 Microphone unit according to Claim 4, characterized in that the cross section of the housing (12) is annular. Microphone unit according to one of the preceding claims, characterized in that the transducers (14, 16) are fastened to the annular partitions (22) inside the housing (12). Microphone unit according to claim 10, characterized in that each partition wall (22) has one or more openings (28) which form an acoustic connection. Microphone unit according to one of the preceding claims, characterized in that the openings (26, 28) are optionally adjustable. Microphone unit according to Claim 12, characterized in that the openings (26, 28, 30) are optionally adjustable from outside the housing (12). Microphone unit according to one of the preceding claims, characterized in that the electrical outputs of the converters are connected together so as to form a difference between them. Microphone unit according to one of the preceding claims, characterized by adjustable resistance parts (34) between the transducers (14, 16) and the output terminals (36) of the unit (10) for selectively adjusting the effect of the outputs of the individual transducers to the output of the unit (10). Microphone unit according to one of the preceding claims, characterized by at least one baffle plate (32) mounted outside the housing (12). Microphone unit according to one of the preceding claims, characterized in that the sound-responsive elements (18, 20) are spaced apart by a distance which is not greater than a quarter of the wavelength of the highest frequency substantially canceled by the unit (10). Microphone unit according to one of the preceding claims, characterized in that the cables are assembled from parts, each of which is made of one of three or more different substances (A, B, C). Microphone unit according to Claim 18, characterized in that the parts comprise layers and / or rings. 62920 Microphone unit according to claim 18 or 19, characterized in that said three or more substances (A, B, C) are selected from the group consisting of wood, rubber, plastics, fiberglass and metal. Microphone unit according to Claim 18, 19 or 20, characterized in that the parts are fastened together by means of their compatible formations and / or adhesive. Microphone unit according to one of Claims 18 to 21, characterized in that no part of one substance is directly parallel to another part of the same substance.