WO2005020628A1 - Microphone arrangement - Google Patents

Abstract

The aim of the invention is to provide microphones that are suspended from the ceiling with magnetization such that the microphone is oriented within the geomagnetic field. Said aim is achieved by a microphone arrangement comprising a microphone for recording audio signals and an orienting unit for generating a magnetic field. The magnetic field of the orienting unit interacts with the geomagnetic field in such a way that the microphone arrangement is oriented. Said automatic orienting of the arrangement dispenses with the need for the microphone arrangement to be fixed at a second point, making such microphone arrangement easier to handle.

Description

Sennheiser electronic GmbH & Co. KG Am Labor 1, 30900 Wedemark

microphone array

The present invention relates to a microphone arrangement.

Mobile devices are known from DE 30 43 788 which have small suspended figures such as fish and are provided with small magnets. These small magnets are then aligned in the north / south direction.

US 2002/0104945 shows a microphone arrangement in which a microphone hangs from the ceiling on its connecting cable, for example. The required orientation results from a holder which engages the microphone and the cable in order to bend a microphone axis with respect to the vertical of the hanging cable. Furthermore, the rigidity of the connection cable itself provides further orientation. In theaters, large halls or on stages in particular, it is well known to provide microphones which hang from cables, for example, on cables. It proves important here that the microphones cannot rotate arbitrarily in the horizontal plane. Since these microphones are usually intended to record audio signals from a stage, for example, optimal alignment of this microphone is very important. This is all the more true if it is a directional microphone. Here it is necessary to take into account the directional characteristic of the microphone in such a way that the microphone is not changed in its horizontal orientation. Such deflections of the microphone from its main recording direction can occur, for example, due to changes in the torsion stress in the fastening cable. Such a rotation is currently prevented by the microphone having a second fixed point. The second fixed point can be ensured by thin, transparent plastic ropes or the like. However, these ropes have to be fastened somewhere in the building. This is not without its problems, especially in buildings with a high ceiling. Furthermore, such ropes often represent a visual impairment. Furthermore, the orientation of the microphone can only be changed by attaching the second end of the rope to another location in the building, which in turn is very expensive.

It is therefore an object of the invention to provide a microfan arrangement which maintains a desired orientation without a second fixed point.

The object of the invention is achieved by a microphone arrangement according to claim 1. The invention is based on the idea of providing microphones hanging from the ceiling with a magnetization such that the microphone is aligned in the earth's magnetic field.

A microphone arrangement is therefore provided with a microphone for recording audio signals and an alignment unit for generating a magnetic field. The magnetic field of the alignment unit interacts with the earth's magnetic field in such a way that the microphone arrangement is aligned.

The automatic alignment of the arrangement in the earth's magnetic field makes a second fixation of the microphone arrangement superfluous, as a result of which such microphone arrangements are easier to handle.

According to one embodiment of the invention, the microphone arrangement is designed so that it can be suspended, so that such a microphone arrangement can be suspended in a building by means of a rope or a cable, without the need for a second fixed point.

According to a further embodiment of the invention, the microphone and the alignment unit are rotatably connected to one another. The microphone can thus be oriented in a direction other than the north / south orientation of the earth's magnetic field.

According to a further embodiment of the invention, the alignment unit has at least one permanent magnet, as a result of which a cheap and simple variant of the magnetization of the microphone arrangement can be implemented.

According to a preferred embodiment of the invention, the microphone has a main recording direction. The north / south orientation of the

Magnetization of the alignment unit can be done by the

Main recording direction shifted by an angle or be twisted. The main recording direction of the microphone can thus be set independently of the north / south orientation without the need for mechanical adjustment.

According to a further embodiment of the invention, the alignment unit has two magnetizable rods that can be rotated in the horizontal direction. By adjusting the two magnetizable bars in the horizontal direction, a resulting magnetic field can be set with a desired orientation.

According to a particularly preferred embodiment of the invention, the alignment unit has at least one electromagnet. By varying the current and the voltage at the electromagnets, the magnetic field of the alignment unit can be generated and controlled with greater degrees of freedom without having to make mechanical changes to the microphone unit.

Further embodiments of the invention are the subject of the dependent claims.

The exemplary embodiments of the invention are described in detail below with reference to the drawing.

FIG. 1 shows a schematic cross section of a microphone arrangement according to a first exemplary embodiment,

FIG. 2 shows a schematic top view of a microphone arrangement according to a second exemplary embodiment, FIG. 3 shows a schematic top view of a microphone arrangement according to a third exemplary embodiment, and

4a, 4b each show a schematic top view of a microphone arrangement according to a fourth exemplary embodiment.

Figure 1 shows a schematic cross section of a microphone arrangement according to a first embodiment. The microphone arrangement consists of a first element 1, which is used to suspend the microphone unit, a second element 2, which is connected to the first element 1, and a microphone 3, which in turn is connected to the second element 2. A first end of a rope 4 can be attached to the first element 1, the second end of the rope being attached, for example, to a ceiling of a theater or concert hall. The microphone arrangement thus hangs on the cable 4 from the ceiling. The connection between the first and second elements 1, 2 or the connection between the second element 2 and the microphone 3 is designed to be rotatable, so that mechanical rotation in a plane perpendicular to the cable 4, i.e. in the horizontal plane. The first element 1 or the second element 2 can be magnetized. Alternatively, a permanent magnet can also be attached in the first or second element 1, 2.

The magnetic field generated by the magnet or the magnetized part of the first or second element 1, 2 interacts with the earth's magnetic field and the microphone arrangement will align itself in a north / south orientation according to the magnetic needle principle. If the microphone arrangement according to the first embodiment thus hangs down from the rope 4 on a ceiling, the interaction of the earth's magnetic field and the magnetic field of the first or second Element 1, 2 counteract the torsional stress changes in the rope 4 and compensate for it, so that the microphone remains stable in its horizontal orientation. This is particularly important for directional microphones with a directional characteristic in their main recording direction, since directional instabilities affect the quality of the recorded audio signals. (Here, the axis of rotation is not in the longitudinal direction of the microphone but at an angle to it.) The cable 4 can be implemented, for example, by a microphone cable, so that the output signals of the microphone can be transmitted to subsequent signal processing. Alternatively, the microphone 3 can also be designed as a wireless microphone, so that a microphone cable is not required and a simple rope is used. Furthermore, it is also possible to magnetize the microphone itself or to provide a permanent magnet therein.

Figure 2 shows a plan view of a microphone arrangement according to a second embodiment. The microphone arrangement according to the second exemplary embodiment is based on a microphone arrangement according to the first exemplary embodiment. The microphone arrangement thus hangs on a rope 4 from a ceiling. As in the first exemplary embodiment, the alignment unit is implemented by magnetizing the first and / or second element 1, 2, so that the material of the first and / or second element 1, 2 is designed to be magnetizable. The microphone 3 is connected to the second element 2. Since the audio signals of an audio source are rarely received exactly from the direction which corresponds to the north / south orientation of the earth's magnetic field, a shift of a main recording direction 20 of the microphone 3 with respect to the north / south orientation of the earth's magnetic field 10 must be provided. According to the second embodiment, the first and / or the second element 1, 2 is magnetized such that between the north / south orientation 10 and the main recording direction 20 an angle a is formed. This angle a must be determined exactly in advance for the future position of the microphone arrangement with respect to the audio source, since magnetization of the first and / or second element 1, 2 takes place in accordance with this angle a. The angle a can be in a range of 0-180 °.

FIG. 3 shows a top view of a microphone arrangement according to a third exemplary embodiment of the invention. The microphone arrangement according to the third exemplary embodiment is based on the microphone arrangement according to the first exemplary embodiment of the invention. Instead of a single permanent magnet, magnetization bars 50, 60 which can be rotated in the horizontal direction are provided, which can also be designed as permanent magnets. The interaction of the magnetic fields of the magnetizing bars 50, 60 results in an overall magnetic field which represents the desired magnetic field direction. The overall magnetic field and thus the orientation of the microphone arrangement with respect to the earth's magnetic field can be adjusted by correspondingly rotating the magnetization bars 50, 60 in the horizontal direction. The two poles north / south of the rods should preferably be kept as far apart as possible in order to be able to generate a torque with the aid of a large lever arm. The rod 50, 60 must act magnetically. A long, rod-shaped magnet, a soft iron rod with magnets at its ends, or many small individual magnets that form a rod magnet when placed on top of one another can be used. If the arrangement shown in FIG. 3 is two permanent magnets, one must have a south pole and the other a north pole at the connection point in the middle, because otherwise similar poles would repel there. The two free poles at the other ends then form the actual drive poles together with the earth field. The same goes of course if the two magnetic bars are crossed in the middle, i.e. exactly in the area between the poles. FIG. 4a shows a schematic top view of a microphone arrangement according to a fourth exemplary embodiment. The microphone arrangement according to the fourth embodiment is based on the microphone arrangement according to the first embodiment. In contrast to the permanent magnet in the first exemplary embodiment, this microphone arrangement has two electromagnets 100, 200. These two electromagnets are arranged orthogonally to one another, although a different orientation is also possible. The electromagnets 100, 200 are each supplied with current / voltage via a first and second current / voltage supply unit 300, 400. The first and second current / voltage supply units 300, 400 are controlled via a control unit 500. By controlling the first and second supply units 300, 400, the current distribution in the electromagnets 100, 200 can be set with any magnetic orientation. The microphone arrangement is aligned accordingly by the interaction of the resulting magnetic orientation of the electromagnets 100, 200 with the earth's magnetic field. Appropriate control of the first and second supply units 300, 400 thus enables a continuous and noiseless rotation of the microphone and thus its main recording direction even after the suspension. The control unit 500 can be activated either wirelessly or by wire. In the case of a wired control, the control unit 500 receives the corresponding signals via the microphone cable designed as a cable 4.

FIG. 4b shows a schematic top view of a microphone arrangement according to the fourth exemplary embodiment, the microphone arrangement according to FIG. 4b essentially corresponding to that from FIG. 4a. The two iron bars are arranged separately because the poles form at the ends of the iron due to the low magnetic resistance of soft iron. The coil 300 and the coil 400 generate substantially the same magnetic field, so control can be omitted. It makes sense to arrange two or more independent electromagnets in such a way that each individual electromagnet has its own specific alignment.

According to a fifth exemplary embodiment of the invention, which is based on the fourth exemplary embodiment, the microphone arrangement has an ultrasound pickup. The microphone 3 is preferably also receivable for ultrasound. Alternatively, an ultrasound transducer separate from the microphone can be used. If an ultrasound transmitter is assigned to an audio source, the alignment of the microphone unit can be controlled such that the microphone arrangement is aligned in accordance with the maximum ultrasound volume.

Since the magnetic field of the alignment unit is a constant field, influences by e.g. B. Induction can be neglected. Since, for reasons of weight, electret microphones are preferably suspended from the cable, the magnetic field has no negative influence, since the electret microphones do not react to the magnetic field. In dynamic microphones, the air gap induction of the magnet system is orders of magnitude higher than the field of the magnet of the alignment unit that is effective at this point, so that influences do not occur here either.

Claims

Expectations

1. Microphone arrangement, with - a microphone (3) for receiving audio signals, and - an alignment unit (1, 2) for generating a magnetic field which interacts with the earth's magnetic field in such a way that the microphone arrangement is aligned.

2. Microphone arrangement according to claim 1, wherein the microphone arrangement is designed to be suspended.

3. Microphone arrangement according to claim 1 or 2, wherein the microphone (3) and the alignment unit (1, 2) are rotatably connected to each other.

4. Microphone arrangement according to claim 1, 2 or 3, wherein the alignment unit (1, 2) has at least one permanent magnet which brings about a north / south orientation (10).

5. Microphone arrangement according to claim 4, wherein the microphone (3) has a longitudinal axis (20) which is adjustable by an angle (a) with respect to the north / south orientation (10) of the alignment unit (1, 2).

6. Microphone arrangement according to claim 4, wherein the permanent magnets are designed as rotatable rods (50, 60).

7. Microphone arrangement according to claim 1, wherein the alignment unit (1, 2) has at least one electromagnet (100, 200).