CH681671A5 - - Google Patents

Description

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CH 681 671 A5

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description

Technical field

The present invention relates to a microphone which responds to structure-borne noise. It also relates to a headset with such a microphone.

State of the art

In the case of headset sets, the majority of the speech function is created using dynamic noise-compensated microphones according to the state of the art that has become known. This is essentially due to the fact that these microphones are now able to provide a good degree of shielding against ambient noise, and that the reproduction of the vocal sounds has reached a high quality level in terms of sound character and timbre. This performance potential presupposes, however, that these microphones are handled in accordance with the strictly tolerated operating instructions. However, it is obvious that such a stem serving as a microphone holder in the area of the mouth opening can prove to be disruptive in various ways, because it is often desirable or an essential condition that the front face surface must remain free from such aids. In the light of these facts, attempts have been made time and again to remedy this by means of a microphone which responds to structure-borne noise. When using larynx microphones belonging to the state of the art, however, it must be taken into account that due to their place of action, they cannot find ideal conditions with regard to the collection of the speech sounds: If one looks at the quality of the speech sounds from the larynx, it is easy to determine that the the average proportion of the high frequency tones released there is only 20% of the entire spectrum; The proportion of low frequency tones, on the other hand, is approximately 80%, which is initially bad for a strong representation of the speech sounds. In addition, the physiological component in the larynx, even with normal speech strength, causes high levels of noise. The primary larynx sound is converted in the voice-forming part of this organ (glottis) to such an extent that a resonable voice results from resonance transformation, but the tone color is still rudimentary, because, as is well known, the final modeling of the voice takes place in other language-forming organs ( Tongue, lips, lower jaw, soft palate, teeth etc.), each based on the individual nature of such organs, which then leads to a distinctive vocal sound. The microphones that have become known to date and respond to structure-borne noise are unable to provide a satisfactory remedy for these requirements, which is why the use of lip microphones is still justified.

In the light of this situation, the proposal DE-PS 2 230 637 describes the proposal to collect the speech sounds in a different way: by using a volumetric moving coil gradient microphone, the place where the speech sounds are picked up is relocated to the area of the TMJ bone. This placement is based on the consideration of collecting the speech sounds where they are modeled as much as possible in terms of structure-borne noise. Although the quality of the sound of the reproduced speech sounds can be improved, the acceptance of the microphone proposed here has not been achieved to the desired extent not least because of its voluminous design and because of its still unmatched quality concept on the part of the user.

Presentation of the invention

This is where the invention intervenes. The invention, as characterized in claims 1 and 2 as a solution, is based on the object of maximizing the distance between the interference signal and the useful signal in the reproduction of intercepted speech sounds in a microphone of the type mentioned, with simultaneous elimination of sound interference from the ambient noise.

It is a further object of the invention to accomplish a miniaturization of the microphone which can decisively expand its possible uses.

Microphones that respond to structure-borne noise and that are placed in the area of the zygomatic outlet (arcus zygomaticus) or in the area of the articular process of the ascending branch of the jaw (processus con-dylaris mandibulae) are able to provide a high-quality reproduction of the speech sounds picked up there, because this decrease affects Speech sounds that originate from the oral cavity, i.e. from an environment where the voice is shaped in terms of color, and from where it then travels over the cranial auditory canal to the outer bone of the auditory canal (os tym-panicum), in the area of which the outlet of the Zygomatic arch and, afterwards, the articular process of the ascending branch of the jaw. These tapping points represent an optimum for a microphone that responds to structure-borne noise. If this constellation is paired with the microphone according to the invention, this results in the essential advantage of the invention, which can be seen in the fact that an increase in the frequency response in the speech area can be determined, which is a qualitative improvement playback means that more sound frequencies are preferred, which significantly increases the presence of speech. The invention accordingly achieves at least the reproduction quality of a lip microphone, insofar as the low frequency tones and nasal assertions of the speech sounds are filtered out, respectively. can be suppressed, and the relatively small proportion of high frequency tones, for the reasons mentioned above, is maximized in terms of voltage.

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The advantages of the invention have a common origin, which is closely related to the design of the subject matter of the invention itself: for example, the piezoelectric resonator and, analogously, the induction element 5 only transfers those vibrations to the amplifier that transversely hit the plate. While the piezoelectric resonator is integrated in the plate, which is preferably made of a metallic material, the induction element 10 is connected downstream of this plate at a certain distance. Regarding the plate itself, it must be said that it lies parallel to an upstream body-side membrane and has a three-point fixation compared to a mass-forming envelope. 15 Vibrations which strike the microphone outside the above-mentioned level are therefore unable to act on the transducers, an insulation preferably made of a silicone material being able to neutralize general sound interference.

In this context, reference should be made to the geometric shape of the plate mentioned, as well as to the physical processes taking place in this plate, and in effect to the transducers: the simplest flat sounders are vibrating membranes and plates. There is the same difference between them as there is between a string and a stick. From a physical point of view, a membrane is such a thin sheet-like structure that it offers no resistance to bending, and therefore no longer opposes it; it can therefore only carry out mechanical vibrations if it is tightened by an external force, as is the case, for example, with a drum. In contrast, due to its greater thickness than a membrane, a plate has so much bending elasticity that it can carry out elastic vibrations without external forces. Of course, only the transverse vibrations, also called bending vibrations, which cause the plate to vibrate, are of importance here. As such, a plate itself did not need to be fixed in order to develop the desired effects. By choosing a certain geometric shape of the plate and by specifying the number and location of the fixing points between the plate and the outer housing, the sound of a plate exposed to transversal vibrations can be changed decisively. Accordingly, the chosen geometric shape of the plate and its fixation constellation are primarily a measure of how regularly the sound figures turn out. By acting on these variables, the sound can be changed significantly, i.e. the relative proportions of high and low tones can be shifted. An increase in the relatively small proportion of high tones in a microphone that responds to structure-borne noise, coupled with a regular sound pattern, can be achieved with a plate that is anchored to the mass-forming body of the microphone via three fixing points that are regularly distributed around the circumference. The node lines of the 65th

Sound figure with this type of fixation form a sound figure regularly trimmed to harmonics. It should be taken into account that the optimal acoustic range is between 300-3000 Hz. So that the sound image resulting from the transversal vibrations, which is still characterized by a relatively large proportion of low frequency tones due to the point at which the speech sounds are picked up, is not too muffled, in such a way that a nasal transmission sound would be the consequence, the excitability of the record is made by appropriate Incisions increased, whereby these incisions are suitable for correcting the variables of the plate and its environment due to their variability. These variables come from both the physical properties and the geometrical shape of the respective plate. Furthermore, the “peak point” (= highest amplitude value depending on the frequency) is also influenced by the number and location of the fixing points between the plate and the envelope of the microphone. Even the quantity and quality of the insulation compound used in the microphone has an impact in this regard. These variables also have a great effect per se, because the desired miniaturization of the object according to the invention only allows a small plate, the minimum thickness of which may result in a disproportionate relationship to the specified areal extent.

What can thus be accomplished at most by an active tone controller, with its disadvantages in terms of additional space requirement and additional power consumption, can now be achieved passively by the inventive design of the microphone.

The invention can also achieve a substantial improvement in efficiency with regard to the timbre of the transmitted speech sounds when the object according to the invention is used as a larynx microphone.

Further advantageous and expedient further developments and use of the task solution according to the invention are characterized in the remaining claims.

Exemplary embodiments of the invention are explained in more detail below with reference to the drawing. All elements not necessary for the immediate understanding of the invention have been omitted. In the different figures, the same elements are each provided with the same reference symbols.

Brief description of the drawings

It shows:

1 is a microphone responsive to structure-borne noise,

2 shows a view of the microphone according to FIG. 1 along the sectional plane II-II, in particular a shape of the plate,

Fig. 3 is a portable hearing-speaking set.

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Way of carrying out the invention,

commercial usability

1 shows a microphone acting on structure-borne noise, which consists of an outer housing 1, an amplifier 2, an insulation body 3, an intermediate ring 4 enclosed by the insulation body 3, a diaphragm 5 on the body side, with an end pin 5a, a plate 6, into which a Piezoelectric resonator 7 is integrated, an impedance converter 9, a microphone-internal line 8 and a cable 10 led to the outside. The elements 1-10 shown in FIG. 1 have an interdependency with respect to one another which relate both to the actual transmission process and to all accompanying measures for increasing the transmission quality. The membrane 5 is to be designed in such a way that the resonance generated by the body vibrations is transmitted to the plate 6 and resonator 7, which is operatively connected to the pin 5a, with the greatest possible efficiency. The use of a membrane 5 would have a negative effect in this context, for example, due to its physical properties in particular, it would not be able to pass on the small portions of high frequency tones at all, or would have the property of suppressing these frequency tones. The body-side surface of the membrane 5 should preferably be coated with a noble metal in order to increase its skin friendliness. The membrane 5 is operatively connected to the plate 6 via the pin 5a, this connection preferably being made by means of a contact with parts. This plate 6 can easily have a centering recess for the pin 5a, whereby the assembly of these parts is subject to an essential quality assurance. This centering arrangement between pin 5a and plate 6 can be provided such that pin 5a is connected to plate 6 by hard soldering. This configuration has the advantage that the entire diaphragm 5 is not physically inhibited in relation to the outer housing 1 and is therefore absolutely free-swinging, which has a positive effect on the transmission of the body vibrations to the plate 6, because immediacy prevails. The plate 6 is embedded in the intermediate ring 4 and lies there on the shoulder surface, the mutual fixation of these two parts being dealt with in detail under the description of FIG. 2. The plate 6, and consequently the piezoelectric resonator 7 integrated there, is accordingly subjected to a focus in the form of vibrations which are absorbed by the membrane 5. The integration of the piezoelectric resonator 7 in the plate 6 is to be provided in such a way that the center of gravity of the two elements coincide, which ensures that the resonator 7 is only activated at points. The intermediate ring 4, which serves as a carrier for the plate 6 and the resonator 7, is in turn embedded in the insulating body 3 in such a way that the piezoelectric resonator 7, with the exception of the membrane-side surface, is insulated on all sides from ambient noise. As damping or Insulation material, for example, a silicone compound can be used, which can be poured into the free space between the outer surface of the intermediate ring 4 and the inner surface of the outer housing 1. The impedance converter 9 is integrated in the amplifier 2, and this is connected in voltage terms to the piezoelectric resonator 7 via the line 8. The latter two elements help to qualitatively increase the efficiency yield in the transmission of the vocal sounds by capturing body vibrations. In particular, the impedance converter 9 perceives an impedance adaptation to a radio device which may be connected downstream and which is connected via the cable 10 to the microphone acting on structure-borne noise. The material of the plate 6 is to be chosen so that it has a low absorption capacity against vibrations, which can already be achieved with a common spring steel. This leads to the fact that the vibration amplitudes of the applied piezoelectric resonator 7, which forms a symbiosis with the plate 6 according to what has been said, can be acted upon in such a way that a sharper resonance is achieved, which improves the reproduction quality of the vocal sounds leads. Further precautions for this final purpose relate to the configurations of the plate 6, which will be explained under the description of FIG. 2. Because the body-side vibrations, initiated by the vocal sounds, on the membrane 5 and subsequently on the pin 5a experience an almost punctiform concentration, which trigger a compressing and maximized effect on the piezoelectric resonator 7, the plate 6 must have a minimum material thickness, should be Resistance can provide the necessary bending elasticity. This minimum material thickness of the plate 6 is also due to the fact that the entire microphone is only 10 mm in diameter and that the plate 6 will therefore have a diameter of perhaps 6-7 mm.

Instead of the piezoelectric resonator 7, an induction element not shown in the figure, which preferably consists of a coil and a magnetic core, can be provided as the transducer. This element is connected at a certain distance from the plate 6. The coil and magnetic core form a so-called dynamic converter, which does not require the voltage that is absolutely necessary for piezoelectric ("phantom power"). The transmission takes place here through the induction generated by the transducer as a function of the vibrations emanating from the plate 6 due to its action by the diaphragm 5 on the body side. Such a variant is suitable wherever a voltage for supplying the piezoelectric resonator 7 is not available, as is the case, for example, with sets for pilots.

Fig. 2 shows a section through the plane II-II of Fig. 1. Here you can see the type of anchoring and the geometric shape of the plate 6. This is

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of round shape, and it is connected to the inner wall of the intermediate ring 4 via a three-point fixation 6a, 6b, 6c. If you connect these three fixation points with each other by a line of thought, an equilateral triangle is created. This configuration is causally responsible for a uniformity with regard to the resulting node lines of the sound figure, so that the sound figure results in a sound image trimmed to harmonics, in which the high frequency tones are transmitted preferentially. Of course, other types of fixation can be provided, which can easily form a corrective to the other variables of an inserted plate. Incisions 6d, 6e, 6f in the plate 6 are assigned to each fixing point 6a, 6b, 6c, which geometrically also describe a uniform course. These incisions 6d, 6e, 6f form a further effective method of being able to act on the physical properties caused by the respective plate 6. Through these incisions 6d, 6e, 6f, the excitability of the plate 6 is changed in the sense that an excessively sharp resonance of this plate 6, the curve of which the frequency response would show above the optimal 3000 Hz, is alleviated. So that the anchoring branches 6g, 6h, 6i of the plate 6 are not too weak, the incisions 6d, 6e, 6f are continued to be angled when the resonance is reduced further as required against the interior of the plate 6, whereby it should be noted in this connection that the plate 6 has the largest possible free area in the area of the piezoelectric resonator 7. Another variable of the plate 6 is the width of these incisions 6d, 6e, 6f, which is to be adapted from case to case to the respective needs with regard to the desired frequency response. Horizontal or quasi-horizontal vibrations impinging on the fixing points 6a, 6b, 6c are not able to propagate inside to the piezoelectric resonator 7 because of the stiffness gradient resulting there against the plane of action of the plate 6: In general, these vibrations bounce off where they are are primarily absorbed by the insulation body 3. The only way that vibrations of high energy are at best open is a surface propagation along the end faces of the plate 6, from one fixation point to the rest. The more precisely the equilateral triangular shape of the fixing points 6a, 6b, 6c with one another, the greater the mutual neutralization of the vibrations which move from one point to the other. Thus, the selected three-point fixing type of the plate 6, based on the geometry of an equilateral triangle, proves to be advantageous in two respects. In addition, a small surface roughness of the entire plate 6 has an energy-reducing effect on these vibrations. The environment of the maximum activatable point of the piezoelectric resonator 7 is therefore in any case not exposed to vibrations from the ambient noise.

Any vibrations incident on the microphone over another level are neutralized by the insulation body 3 anyway. The compactness of the entire microphone, which has a height of approx. 8 mm, then makes it impossible for self-oscillation behavior to occur. The only "vibration-permeable" level is the membrane-side, which lies on the body side, which is why the microphone, i.e. the iezoelectric resonator, i.e. the induction element can only be subjected to body vibrations.

Fig. 3 shows a possible example of use of the microphone according to Figs. 1 and 2, wherein the headset shown here also seeks to remedy the disadvantages of known sets of identical use.

A known ear-side portable device consists of a kidney-shaped bow which is connected to the supporting part of the hearing and speaking capsule and is bent at the head, the opening of which is smaller than the average size of an ear. The placement of this set turns out to be unsatisfactory, because this process always presupposes that the ear has to be forced through the ren-shaped opening. In addition, the offset of the bracket, compared to the hearing-speaking surface, does not prove to be ideal for all ear shapes: If the ears protrude, the clothing will hang loose and unpositioned; pressure marks will inevitably become painfully noticeable when the ears are in contact. But not only can the set of the set be ergonomically and comfortably satisfying, the subsequent removal is also unwieldy. This unwieldiness is then compensated for by excessive use of force, which leads to painful ear deformations. With such a set with a closed ear hook, injuries to the ear are also always possible, so if the set is connected to a fixed connection point via a cable, and the set is not put down when leaving the place, whereupon the ear is dangerous and painful is pulled.

This is different from the clothing now proposed here, the bracket 11 of which can be optimally adapted to any ear shape without producing any pressure points on the ear itself. This is achieved in that the ear hook 11 has a degree of compliance in at least one plane of its spatial extent, i.e. the ear hook 11 is resiliently movable relative to a hearing / speech insert 12. A degree of compliance of the ear hook 11 can be seen from FIG. 3: in the idle state, this ear hook 11 is bent up to approximately the middle of the hearing / speech insert 12 by a spring part 11 b acting at the beginning of the ear hook 11, as symbolized by the position 11 a of the ear hook 11 want. This means that the spring part 11b is cranked in relation to the inner ear-side surface of the insert 12, in such a way that the tension release when the clothing is in the state of wear is given by the spring-loaded offset force from the spring part 11b, as a result of which a second level of flexibility of the ear hook 11 acts. The offset distance for clothing on man is a measure between the inner ear side

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The area of the insert 12 and the position of the ear hook 11, corresponding to the difference in height between the ear entrance, where the ear capsule 13 nestles, the area around the sleeper bone, where the microphone rests, and the back ear root, where the bracket 11 rests, where it provides the necessary stability for the whole set. The flexibility of the ear hook 11, be it solely via the spring part 11b shown, or via a holistically resilient bracket, makes it possible for the clothing to be easily put on and removed. A holistically flexible ear hook deforms and adapts easily, according to the respective contour of the posterior ear root, which in turn has a positive effect on the position of the earphone 13 and the microphone 1-10 by this and those taking the positions intended for them in an optimal manner. Of course, the ear hook 11 can have a further comfort-producing offset 11c, which is raised on the skull side from the lines of the ear hook 11, whereby this offset 11c can easily only grasp the lower part of the ear hook 11, while the remaining part of the ear hook 11 up to the insert 12 maintains the original lines. The cable 14 to a connection point is guided inside the ear hook, which, when the clothing is in use, relieves tension on the entire clothing and has no disruptive effect on the front of the face.

The cable 14 preferably has a screw-shaped extension which is able to bridge different distances between the ear and the connection point without interference.

Claims (9)

Claims 1. Microphone responsive to structure-borne noise, consisting essentially of a microphone capsule, a body-side membrane, a transducer downstream of the body-side membrane, characterized in that the transducer downstream of the body-side membrane (5) consists of a plate (6) and a plate (6) integrated piezoelectric resonator (7), that the body-side membrane (5) is in operative connection with the plate (6) and resonator (7), that the plate (6) is fixed by a three-point fixation (6a, 6b, 6c) is in operative connection with the microphone capsule (1) and that each fixation point (6a, 6b, 6c) is assigned at least one incision (6d, 6e, 6f) in the plate (6). 2. Microphone responsive to structure-borne noise, consisting essentially of a microphone capsule, a body-side membrane, a transducer connected downstream of the body-side membrane, characterized in that the transducer downstream of the body-side membrane (5) consists of a plate (6) and one at a distance There is an induction element downstream of the plate (6) that the body-side diaphragm (5) is in operative connection with the plate (6), that the plate (6) is in operative connection with the microphone capsule (3a, 6b, 6c). 1) stands for each fixing point (6a, 6b, 6c) being assigned at least one incision (6d, 6e, 6f) in the plate (6). 3. Microphone according to claim 1, characterized in that the center of gravity of the plate (6) and the center of gravity of the piezoelectric resonator (7) coincide. 4. Microphone according to claim 1 or 2, characterized in that the three-point fixing points (6a, 6b, 6c) form an equilateral triangle with one another. 5. Microphone according to one of claims 1-3, characterized in that the body-side membrane (5) acts via a pin (5a) directly on the center of gravity of the plate (6). 6. Microphone according to claim 1 or 2, characterized in that the plate (6) consists of a bronze alloy. 7. Microphone according to claim 1 or 2, characterized in that the incisions (6d, 6e, 6f) with respect to the fixing points (6a, 6b, 6c) are uniform and rectified in the plane. 8. Microphone according to claim 1 or 2, characterized in that the incisions (6d, 6e, 6f) have a center-directed bend. 9. headset with a microphone according to claim 1 or 2, which consists essentially of an insert, the carrier of the hearing capsule and the microphone, and further consists of an ear-root-shaped support device, characterized in that the carrying device is a curved ear hook (11) which is connected to the insert part (12, 12a) and runs freely in the area of the ear lobes and has a degree of compliance in at least one plane of its spatial extent. 5 10th 15 20th 25th 30th 35 40 45 50 55 60 65 6