WO2008148841A2 - Audiological measuring instrument for generating acoustic test signals for audiological measurements - Google Patents

Abstract

The invention relates to an audiological measuring instrument for generating acoustic test signals for audiological measurements. Said measuring instrument comprises: - a room loudspeaker arrangement (1, 2) for supplying at least two acoustic signals in at least two measurement positions encompassing a first measurement position (M1) and a second measurement position (M2); - a means (4) for generating control signals (S1, S2) that can be converted into a first acoustic signal and a second acoustic signal. A predefined acoustic test signal can be generated by supplying exclusively the first acoustic signal in the first measurement position (M1) and exclusively the second acoustic signal in the second measurement position (M2); - a crosstalk compensating device which processes the control signals (S1, S2) during operation in such a way and feeds the same to the room loudspeaker arrangement (1, 2) in such a way that the predefined test signal is generated in the first and second measurement position (M1, M2).

Description

 Audiological measuring device for generating acoustic test signals for audiological measurements

description

The invention relates to an audiological measuring device for generating acoustic test signals for audiological measurements and to a corresponding method for generating acoustic test signals for audiological measurements.

The invention is in the field of audiology, which is a branch of medicine and deals with all aspects of auditory perception and hearing. The invention enables the provision of test signals for audiological measurements. In this case, audio-logical measurements are understood as any measurements with which the auditory perception or the hearing of living beings is researched or with which the functioning of hearing aids in the case of persons with hearing loss is checked or adjusted. By audiological measurements, for example, hearing tests are to be understood, which preferably take place in accordance with prescribed standards. Audio logical measurements also include measurements to determine speech intelligibility or psychophysical tests for localization perception of test signals in reflection-prone or reflection-poor environment.

In the field of hearing aid acoustics, it is desirable that audio logical measurements for persons with hearing aids be carried out via room loudspeakers. Spaces speakers are understood here and below loudspeakers, which do not deliver the sound directly and directly to the ear of test persons, as is the case with headphones. Room loudspeakers thus relate in particular to all types of loudspeakers with the exception of headphones. The use of room loudspeakers in the hearing aid acoustics is necessary in particular because electroacoustic feedback from loudspeakers placed directly on the patient's ear should be avoided with the hearing aids.

When using room loudspeakers in hearing aid acoustics today specially equipped rooms are needed in which reflections are avoided, which would falsify the measurement results. The corresponding equipment of such rooms is very expensive. In addition, conventional measurements in hearing aid acousticians are very complex because the room speakers must be arranged at different spatial positions to produce different test signals.

The object of the invention is therefore to provide an audio logical measuring device, with the simple and inexpensive audiological measurements can be performed with the help of room speakers.

This object is solved by the independent claims. Further developments of the invention are defined in the dependent claims.

The audiological measuring device according to the invention serves to generate acoustic test signals, wherein these test signals are predetermined signals which generate a predetermined acoustic perception and which can be composed of several acoustic signals. The audiological measuring device includes a spatial loudspeaker arrangement for providing at least two acoustic signals at at least two measuring positions comprising a first measuring position and a second measuring position. In this case, the first and the second measuring position are preferably selected such that they correspond to the distance between the ears of a test object, in particular a test person.

The audio logical measuring device further comprises a per se known means for generating in a first acoustic signal and a second acoustic signal convertible control signals, by providing only the first acoustic signal at the first measuring position and of only the second acoustic signal the second measuring position, a predetermined acoustic test signal can be generated. This generating means thus generates signals in which, in the case of a non-existing crosstalk, the desired test signal is generated. Crosstalk here means a sound transmission of the first acoustic signal to the second measuring position or of the second acoustic signal to the first measuring position.

The crosstalk is prevented in the prior art, in particular by the use of headphones. However, according to the invention, room loudspeakers are now used. Since crosstalk occurs in room loudspeakers, a crosstalk compensation device is used in the device according to the invention, which compensates crosstalk between the at least two acoustic signals of the room speaker arrangement by appropriate computer-aided processing of the control signals generated by the generating means. The crosstalk compensation device thus processes the control signals and supplies them to the spatial loudspeaker arrangement for providing the at least two acoustic signals such that the predefined test signal which corresponds to the test signal which would be present without crosstalk is generated by the spatial loudspeaker arrangement at the first and second measurement positions. The implementation of crosstalk compensation is known per se from the prior art. In particular, there are a variety of algorithms for performing crosstalk compensation. For example, the performance of crosstalk compensation is described in document [1]. Special algorithms for over-speech compensation can also be found in references [2] to [8]. All of these references [1] to [8] are incorporated herein by reference. In the audiological device according to the invention, any method for crosstalk compensation can be used. In a specific embodiment, algorithms according to documents [1], [2] and [8] were used in particular.

The essence of the invention is the use of the known crosstalk compensation in an audio logical measuring device for audio logical measurements. Such use of crosstalk compensation in the field of audio logics is still unknown. In particular, headphones are used in the field of audio technology for corresponding measurements either, which, however, are disadvantageous in the hearing aid acoustics, or measurements are carried out with room speakers in elaborate soundproofed rooms.

The device according to the invention thus has the advantage that audiological measurements can be carried out with the aid of room loudspeakers with the aid of crosstalk compensation in arbitrary rooms. Elaborate room equipment to reduce the Schallrefiexion can be dispensed with. In addition, any test signals can be virtually generated with the device without having to change the spatial speaker arrangement in position. The audiological measurements are thus much simpler than in the prior art.

In the measuring device according to the invention, the position of the Raumlautspre- cheranordnung and / or the at least two measuring positions can be fixed.

In this case, when using the audio logical measuring device, the test object is ject always at the predetermined measuring positions with respect to the speaker assembly position. In such a device, the same parameters can always be used in the crosstalk compensation, whereby the implementation of the crosstalk compensation becomes very simple. However, if necessary, it is also possible for the position of the spatial loudspeaker arrangement or the at least two measuring positions in the device to be varied. In this case, the parameters for the crosstalk compensation must be adjusted according to the respective set positions.

In a particularly preferred embodiment of the device according to the invention, the spatial loudspeaker arrangement is realized in a simple manner by providing a plurality of room loudspeakers, wherein at least two room loudspeakers in the form of a first and a second room loudspeaker are provided, which generate the at least two acoustic signals.

The inventors have been able to determine that, when setting certain distance ranges with respect to the room loudspeakers or the measuring positions, audio logical measurements can be carried out which essentially always deliver the same test signals in any surroundings. In particular, the following arrangements are advantageous for the audiological measuring device:

The distance between the first and the second room loudspeaker is between 0.1 m and 0.7 m (m = meters), in particular between 0.2 m and 0.5 m, and particularly preferably at substantially 0.3 m, this being Distance is preferably variable.

The first and the second room loudspeakers are arranged or arrangeable in relation to the first and second measuring positions in such a way that the connection line between the first room loudspeaker and the first measuring position and the connecting line between the second room loudspeaker and the second measuring position an angle of substantially 30 ° or less, in particular of 20 ° or less is clamped.

The first and second room loudspeakers are arranged or arrangeable such that the connecting line between the first and second measuring positions is substantially parallel to the connecting line between the first and second room loudspeakers. The connecting line between the first and second measuring positions preferably has a distance to the connecting line between the first and the second spatial loudspeakers of between 0.5 m to 1.5 m, in particular between 0.8 m and 1.2 m, and particularly preferably substantially 1.0 m up.

With the device according to the invention, different test signals can preferably be achieved by varying the control signals, depending on the audiological tests performed.

In a particularly preferred embodiment of the device according to the invention, a user interface is provided, via which parameters of the audiological measurement can be entered by a user, in particular the test signals to be generated and / or the positions of the room loudspeakers and / or the measurement positions. Preferably, measured values acquired during the measurement can also be entered via the user interface, the input measured values being evaluated in particular in an evaluation unit and the evaluations output at the user interface.

The erfmdungsgemäße device can be used for any tests. In a variant, acoustic test signals for performing hearing tests can be generated with the device. Additionally or alternatively, the device can be used to generate test signals for measuring speech intelligibility and / or for performing localization perception tests and their changes. Likewise, in a preferred variant of the device it is possible to use test signals for adapting generating and / or checking hearing aids. Hearing aids, in addition to conventional hearing aids, also other hearing aids, such as cochlear implants or implantable hearing aids to understand.

In a further, preferred embodiment of the device according to the invention, a test signal can be generated which contains an interference signal which is perceived by a test person from the front or from the side. In this way, the device can be used in particular to perform ILD tests or BILD tests (ILD = Intelligent Level Difference).

The crosstalk compensation device used in the device according to the invention is preferably designed such that it performs crosstalk compensation on the basis of the impulse responses at the first and second measurement positions in response to the at least two acoustic signals provided by the spatial loudspeaker arrangement.

Particularly accurate audio logical measurements are achieved, in particular, when the device according to the invention contains a measuring device, in particular in the form of microphones which can be arranged at the first and second measuring positions, wherein the impulse responses can be measured with the measuring device. When using measured impulse responses, a particularly good overcompensation is achieved. Nevertheless, the inventors have been able to demonstrate that impulse responses in crosstalk compensation, which do not exactly take into account the present room acoustics, can also be used, in particular in the case of a close arrangement of the room loudspeakers. In this case, the device according to the invention is preferably designed in such a way that the overcompensation device can access a database, wherein the database stores impulse responses which are used by the crosstalk compensation device and / or from which those used by the crosstalk compensation device Pulse arrangement calculated / synthesized become. In a preferred variant, the crosstalk compensation device uses impulse responses in the time domain.

In addition to the device described above, the invention further relates to a method for generating acoustic test signals for audiological measurements with the aid of the device according to the invention, comprising the following steps:

Setting up a room loudspeaker arrangement for providing at least two acoustic signals at at least two measuring positions comprising a first measuring position and a second measuring position; Generating control signals that can be converted into a first acoustic signal and a second acoustic signal, wherein a predetermined acoustic test signal can be generated by providing only the first acoustic signal at the first measuring position and only the second acoustic signal at the second measuring position; - Performing a crosstalk compensation, in which the control signals are processed in such a way and the spatial loudspeaker arrangement for providing the at least two acoustic signals are supplied such that at the first and second measuring position, the predetermined test signal is generated by the Raumlautsprecheranordnung.

In a preferred embodiment of the method according to the invention, the room loudspeaker arrangement is set up in the free field so that measurements can be performed in the free field with the generated test signals. It is also possible that the room speaker arrangement is placed in a room. In this case, the spatial loudspeaker arrangement and the at least two measuring positions are preferably arranged in the space such that the distance between the first measuring position to the loudspeaker arrangement and / or the second measuring position to the spatial loudspeaker arrangement is less than the distance between the measuring positions and / or the spatial loudspeaker arrangement to the room walls. In this arrangement, the acoustic test signals generated by the device are substantially independent of the room acoustics present. Embodiments of the invention are described below in detail with reference to the accompanying drawings.

Show it:

Fig. 1 is a schematic representation showing the components used in one embodiment of the device according to the invention;

FIG. 2 shows a schematic representation of the implementation of the crosstalk compensation according to an embodiment of the invention; FIG.

3 shows a schematic representation of the performance of a speech intelligibility test with the aid of an embodiment of the device according to the invention.

Fig. 1 shows schematically the essential components of an embodiment of the inventive audio logical measuring device. In FIG. 1, a square space R is shown in plan view in which an audiological measurement is to be performed on a subject T, wherein the subject with the nose and the two ears is shown schematically by the subject T. The ears correspond to the measurement positions Ml and M2. In particular, the left ear is at the measuring position M1 and the right ear is at the measuring position M2. In front of the subject T is the audiological measuring device, wherein a loudspeaker arrangement consisting of two loudspeakers 1 and 2 is arranged in front of the face of the subject T. These loudspeakers are room loudspeakers, ie the sound of these loudspeakers is blasted freely into the room and not emitted directly and directly to the ears of the person T, as is the case with headphones. FIG. 1 shows the individual spacings of the loudspeakers 1 and 2 and the measuring positions M1 and M2, respectively. In particular, the distance dl denotes the distance between the two speakers 1 and 2, this distance being along the line Ll extends. The connecting line L2 between the measuring positions M1 and M2 is parallel to the line L1, and the distance along this line between the measuring positions M1 and M2 (ie, the ear distance of the subject) is indicated as d2. Further, in Fig. 1, the distance between the parallel lines L1 and L2 is designated as d3.

The device according to FIG. 1 has the advantage that it is possible to dispense with the arrangement of headphones directly at the ears of the subject T by the use of two room loudspeakers 1, 2. This is particularly advantageous in tests with persons who wear hearing aids, as this disturbing interactions between the headphone speakers and the components of the hearing aid are avoided.

The audiological apparatus according to FIG. 1 comprises a processing unit 3, which in turn consists of the units 4 and 5. The unit 4 in this case represents a signal generating device, with the corresponding electrical control signals can be generated, which can be converted by transducers in the form of any two speakers in two audio signals. The signal generator 4 is implemented as software or hardware or as a combination of software and hardware and allows the generation of a plurality of test signals, which can be used in audiological tests. The device 4 thus stores a plurality of possible audio logical tests with corresponding test signals, and a user performing corresponding tests can call and execute corresponding programs for generating the signals for the respective tests. For this purpose, a user interface connected to the processing unit 3 is provided, which is indicated schematically in FIG. 1 by a monitor 7 and a keyboard 8.

In the signal generating device 4, control signals are generated which generate desired test signals when outputting via a headphone to the test person T. The device 4 can simulate test signals that the test person as Perceives signals originating from predetermined spatial directions. In order to maintain the spatial impression of such test signals in the device according to the invention when using room loudspeakers, it is necessary to prevent the crosstalk which would occur if the signals generated in the device 4 were output directly to the loudspeakers 1 and 2. This crosstalk occurs because the sound from the speakers 1 and 2 can now overlap and thus sound signals from speaker 1 to the measuring position M2 and sound signals from speaker 2 reach the measuring position Ml.

In order to compensate for the crosstalk, a so-called crosstalk compensation device 5 is used in the device according to FIG. 1 as a further component, which performs a crosstalk compensation on the control signals which are generated by the signal generating device 4. With the aid of the crosstalk compensation, the signals from the device 4 are compensated for and equalized, so that the signals generated by the crosstalk compensation are configured after their sound conversion at the loudspeakers 1 and 2 in such a way that the crosstalk between the acoustic signals of the loudspeakers 1 and 2 is prevented and thus the same perceptible test signal is generated by the room speakers, as if the subject T would wear a headphone.

When performing the crosstalk compensation in the device 5, any algorithms known in the art may be used. Examples of such algorithms are mentioned in references [1] to [8]. Preferably algorithms are used in particular, which are specified in the publications [1], [2] or [8]. To carry out the crosstalk compensation

Impulse responses at the measurement positions Ml and M2 needed, namely the answers to these measurement positions on emitted sound pulses from both the speaker 1 and the speaker 2. These impulse responses are equalized in the Übersprechkompensationseinrichtung 5. In the embodiment of the invention described here, synthesized impulse responses are used, which are read from a database 6. In this database are impulse responses stored for a variety of different arrangements of room speakers and measurement positions, the most suitable for the considered arrangement impulse response is used or is approximated with appropriate mathematical methods. Such a database can be found, for example, at the Internet address http://interface.cipic.ucdavis.edu/CIL_html/CIL_HRTF_data_base.htm.

The impulse responses in the database do not reflect the room acoustics of the room R, since they were determined in other rooms. However, it has been shown that despite these different spatial characteristics, the crosstalk compensation still works very well and provides the desired test signals. Nevertheless, actually measured impulse responses can be used in the inventive device in the crosstalk compensation, which reflect the actual existing room acoustics R. For this purpose, a measuring device (not shown) is preferably provided, which has two probe microphones, which are arranged at the measuring positions M1 and M2. These probes then measure corresponding pulses from the loudspeakers 1 and 2, respectively, and these measured pulses are then stored and used by the crosstalk compensation device.

When using a database from which the impulse responses are read out, the user also uses the user interface 7, 8 to input the individual spatial arrangements of the loudspeakers relative to one another and the measurement positions relative to each other and to the loudspeakers, so that suitable impulse responses can then be retrieved from the database similar or identical arrangements can be read.

After performing the crosstalk compensation by the device 5, the resulting signals are supplied to the loudspeakers 1 and 2, whereby an acoustic test signal is generated, which is identical to the test signal which is available without a crosstalk compensation via a headphone of the test subject T. would be. According to the above explanations, according to the invention control signals, which are generated by the device 4, processed by a known crosstalk compensation such that a corresponding test signal is not provided via headphones, but via room speakers.

In the crosstalk compensation two control signals Sl and S2 are processed, these signals generate the test signal, which when using a headset at the measuring positions Ml and M2 is produced. These signals are now supplied to a corresponding filter matrix with the entries Hn, H21, H12 and H22. The filter matrix is dependent on the selected crosstalk compensation algorithm. In addition, the space transfer matrix C, which reproduces the acoustic properties of the room and the arrangement of the loudspeakers 1 and 2 in the room, flows into the filter matrix. In order to express that the matrix C is influenced by the properties of the room, the entries of the matrix Cn, C ₂₁ , C ₁₂ and C22 between the loudspeakers 1, 2 and the subject T are shown in FIG. Nevertheless, the entries of the matrix flow in before the actual acoustic output when performing the crosstalk compensation.

The entries of the matrix C contain the measured or synthesized impulse responses. The entry Cn corresponding to the impulse response at the measurement position Ml for one pulse of the speaker 1. The entry C ₂₁ represents an impulse response at the measured response M2 1 for a pulse of the speaker of the entry C ₁₂ corresponds to the impulse response at the measurement position Ml for a pulse of the loudspeaker 2 and the entry C ₂₂ represents the impulse response at the measuring position M2 for a pulse of the loudspeaker 2. After the crosstalk compensation has been carried out, corresponding acoustic signals x 1 and x 2 are reproduced, which together form the test signal which gives the corresponding spatial impression. which would be achieved by the original signals Sl and S2 without crosstalk compensation, ie when the sound signal from the speaker 1 only to the Measuring position M1 arrives and the sound signal from the speaker 2 only reaches the measuring position M2.

3 shows schematically a measuring arrangement in which the device according to the invention can be used. In particular, FIG. 3 shows preferred positions for the two loudspeakers 1 and 2 and the measuring positions M1 and M2. According to

Fig. 3 is used as a preferred distance d3 between the lines L1 and L2 d3 = 1.0 m. The distance between the speakers 1 and 2 is preferably set to dl = 0.3 m. Analogous to FIG. 1, the distance between M1 and M2 corresponds to the distance between the ears of the subject T.

In the measurement according to FIG. 3, the so-called ILD difference is determined (ILD = intelligence level difference). In this measurement, a test person is first presented with a first test signal in which a useful signal in the form of a spoken text and a noise signal in the form of a noise frontally, ie at zero degree angle according to the scale shown in Fig. 3, is presented. With the device according to the invention, a second test signal is subsequently generated, which is shown schematically by dot-dashed loudspeakers at the positions So or N _x . By the second test signal, a perception is generated in the person T such that the useful signal again acts frontally on the user, whereas the interference signal now passes from the direction + 90 ° to the right ear of the subject T. Such virtual arrangements of useful and interference signals can be simulated according to the invention without problems due to the performance of the crosstalk compensation.

In order to determine the so-called ILD difference according to the measurement of FIG. 3, the threshold (as signal-to-noise ratio in db) of speech intelligibility of 50% is determined both for the first test signal and for the second test signal. The difference between the two thresholds corresponds to the ILD difference. The inventors were able to show that with the device according to the invention with crosstalk compensation ILD differences are approached, which come close to the ILD differences in measurements performed with headphones.

The inventive device thus has the further advantage that ILD measurements can now be performed in any room with two room speakers, which was previously not possible with a corresponding real arrangement of the room speakers. For hearing healthcare professionals in particular the possibility is created to make hearing tests or adjustments and adjustments of hearing aids, without the need for special low-noise rooms to reduce the sound reflections would be required. Audio logical measurements can thus be made with two room speakers even in small rooms without special electro-acoustic equipment with the help of crosstalk compensation.

Bibliography :

[1] US 3,236,949

[2] Kallinger, M. and Mertins, A .: Room Impulse Response Shortening by Channel Shortening Concepts, Conference Record of the 39th Asilomar Conference on Signals, Systems and Computers, Oct. 2005, Pacific Grove, CA, USA

[3] Kallinger, M. and Mertins A .: "A Spatially Robust Least Squares Crosstalk Canceller." In Proc. IEEE Int. Conf. on Acoustics, Speech and Signal Processing Proc. IEEE Int. Conf. on Acoustics, Speech and Signal Processing (ICASSP): Honolulu, Hawaii, USA, vol. I, April 2007,

[4] Kirkeby, O., Nelson, P.A., Hamada, H. and Orduna-Bustamante, F .: "Fast Deconvolution of Multichannel Systems Using Regularization", ITSAP, 1998, of 1.6, no. 2

[5] Gardner, W.G .: "3-D Audio Using Loudspeakers", Phd Thesis, 1997

[6] Nelson, P.A. and Hamada, H. and Elliott, S.J .: "Adaptive Inverse Filters for Stereophonic Sound Reproduction", IEEE 1992, vol. 40, no. 7

[7] Ward, D. and Elko, G .: "Optimum Loudspeaker Distance For Robust Crosstalk Cancellation", Proc. ICASSP 1998

[8] Ward. D .: "Joint Least Squares Optimization for Robust Acoustic Crosstalk Cancellation", IEEE vol. 8, no. 2, February 2000

Claims

claims An audio logical measuring device for generating acoustic test signals for audiological measurements, comprising: - a room loudspeaker arrangement (1, 2) for providing at least two acoustic signals at at least two measuring positions comprising a first measuring position (M1) and a second measuring position (M2); a means (4) for generating in a first acoustic signal and a second acoustic signal convertible control signals (Sl, S2), wherein by the provision of only the first acoustic signal at the first measuring position (Ml) and exclusively the second a- acoustic signal at the second measuring position (M2) a predetermined acoustic test signal can be generated; a crosstalk compensation device, which in operation processes the control signals (S1, S2) in such a way and the spatial loudspeaker arrangement (1, 2) such that at the first and second measuring position (Ml, M2) by the Raumlautsprecheranordnung (1, 2), the predetermined test signal is generated. 2. Apparatus according to claim 1, characterized in that the position of the spatial loudspeaker arrangement (1, 2) and the at least two measuring positions (Ml, M2) is fixed or variable. 3. Device according to claim 1 or 2, characterized in that the room loudspeaker arrangement (1, 2) comprises a plurality of room loudspeakers comprising a first and a second room loudspeaker (1, 2). 4. Apparatus according to claim 3, characterized in that the distance (dl) between the first and the second spatial loudspeaker (1, 2) between 0.1 m and 0.7 m, in particular between 0.2 m and 0.5 m and especially preferred is substantially at 0.3 m, this distance (dl) is preferably variable. 5. Apparatus according to claim 3 or 4, characterized in that the first and second spatial loudspeakers (1, 2) with respect to the first and second measuring position (Ml, M2) are arranged or can be arranged such that through the connecting line between the first room speaker (1) and the first measuring position (Ml) and the connecting line between the second spatial loudspeaker (2) and the second measuring position (M2) an angle of substantially 30 degrees or less, in particular of 20 degrees or less, is clamped. 6. Device according to one of claims 3 to 5, characterized in that the first and second spatial loudspeakers (1, 2) are arranged or can be arranged such that the connecting line (L2) between the first and second Measuring position (Ml, M2) is substantially parallel to the connecting line (Ll) between the first and second room speaker (1, 2). 7. The device according to claim 6, characterized in that the connecting line (L2) between the first and second measuring position (Ml, M2) a distance (d3) to the connecting line (Ll) between the first and second spatial loudspeaker (1, 2) or can be set to a distance which is between 0.5 m and 1.5 m, in particular between 0.8 m and 1.2 m, and particularly preferably substantially 1 m. 8. Device according to one of the preceding claims, characterized in that the first and second measuring position (Ml, M2) are set such that the distance (d2) between these measuring positions (Ml, M2) substantially the distance between the ears of a test object , in particular a human subject. 9. Device according to one of the preceding claims, characterized in that with the device by changing the control signals (Sl, S2) different test signals can be generated. 10. Device according to one of the preceding claims, characterized in that a user interface (7, 8) is provided, via which parameters of the audio logical measurement can be entered, in particular the test signals to be generated and / or the positions of the room loudspeakers (1, 2) and / or the measuring positions (Ml, M2). 11. The device according to claim 10, characterized in that via the user interface (7, 8) further detected measured values can be entered, wherein the input measured values are preferably evaluable in an evaluation and the evaluations on the user interface (7, 8) can be output are. 12. Device according to one of the preceding claims, characterized in that with the device acoustic test signals for performing hearing tests can be generated. 13. Device according to one of the preceding claims, characterized in that with the device test signals for measuring the speech intelligibility and / or for performing tests for Lokalisationswahrnehmung and / or to perceive a localization change are feasible. 14. Device according to one of the preceding claims, characterized in that with the device test signals for adaptation and / or verification of hearing aids can be generated. 15. Device according to one of the preceding claims, characterized in that the test signal generated by the device contains a noise signal, which is perceived by a subject from the front or from a side. 16. Device according to one of the preceding claims, characterized marked, that the crosstalk compensation device (5) is designed such that it crosstalk compensation on the basis of the impulse responses at the first and second measuring position (Ml, M2) in response to the respective the room speaker assembly (1, 2) performs provided acoustic signals. 17. The device according to claim 16, characterized in that the device comprises a measuring device, in particular in the form of at the first and second measuring position (Ml, M2) can be arranged microphones, wherein the impulse responses can be measured with the measuring device. 18. The apparatus of claim 16 or 17, characterized in that the Ü override compensation means (5) can access a database (6), wherein in the database (6) impulse responses are stored, which are used by the crosstalk compensation means (5) and or from which the impulse responses used by the crosstalk compensation device (5) are calculated. 19. Device according to one of claims 16 to 18, characterized in that the crosstalk compensation device (5) uses impulse responses in the time domain. 20. A method for generating acoustic test signals for audiological measurements using a device according to one of the preceding claims, comprising the following steps: - Setting up a room speaker arrangement (1, 2) for providing at least two acoustic signals at at least two measuring positions comprising a first measuring position (Ml) and a second measuring position (M2); Generating in a first acoustic signal and a second acoustic signal convertible control signals (Sl, S2), wherein by the provision of only the first acoustic signal at the first measuring position (Ml) and excluding the second acoustic signal at the second measuring position (M2 ) a predetermined acoustic test signal can be generated; Performing a crosstalk compensation, in which the control signals (Sl, S2) are processed in such a way and the Raumlautsprecheranordnung (1, 2) are supplied in such a way that at the first and second measuring position (Ml, M2) by the Raumlautsprecheranordnung (1, 2), the predetermined test signal is generated. 21. The method according to claim 20, characterized in that the spatial loudspeaker arrangement (1, 2) is placed in the open field. 22. The method according to claim 20, characterized in that the spatial loudspeaker arrangement (1, 2) is placed in a room (R). 23. Method according to claim 22, characterized in that the spatial loudspeaker arrangement (1, 2) and the at least two measuring positions (M1, M2) are arranged in the space such that the distance between the first measuring position (M1) and the spatial loudspeaker arrangement (1, 2) and / or the second measuring position (M2) to the spatial loudspeaker arrangement (1, 2) is less than that Distance of the measuring positions (M1, M2) and / or the room loudspeaker arrangement (1, 2) to the room walls.