DE102017207756B4 - Method for generating a compensation transfer function for sound actuators of a motor vehicle and motor vehicle - Google Patents

Abstract

Method for generating a compensation transfer function (H _Komp ) for a sound actuator (2) of a motor vehicle (motor vehicle), characterized in that
a. an input signal (X) is transmitted from a control unit (1) to a sound actuator (2),
b. by means of the sound actuator (2) an input sound signal (SX) is output,
c. a sensor unit (3) detects an output sound signal (SY) influenced by the vehicle acoustics and transmits an actual output signal (Y) to the control unit (1),
d. the control unit (1) generates a total transfer function (H _Ges ) which describes the relationship between the actual output signal (Y) and the input signal (X),
e. the control unit (1), determined by comparing the overall transfer function (H _Ges) with a reference overall transfer function (H _{Ges, Ref),} which and the input signal (X) describes the ratio of a reference output signal (Y ') a compensation transfer function (H _Comp) which describes the ratio of the reference total transfer function (H _{Ges, ref)} and the overall transfer function (H _total),
f. after the generation of the compensation transfer function (H _Komp ) by the control unit (1) a further input signal (X) is generated and the further input signal (X) from the control unit (1) by means of the compensation transfer function (H _Komp ) in an adapted input signal (X '. ) is transformed
G. the adapted input signal (X ') is transmitted by the control unit to the sound actuator (2),
H. an adapted input sound signal (SX ') is output by the sound actuator (2),
i. the sensor unit (3) detects an adapted output sound signal (SY ') influenced by the vehicle acoustics and transmits an adapted actual output signal (Y ") to the control unit (1), and
j. the control unit (1) a difference (dS) between the adapted actual output signal (Y ") and the reference output signal (Y ') determined.

Description

The invention relates to a method for generating a compensation transfer function for a sound actuator of a motor vehicle and equipped with a sound actuator motor vehicle.

In the design of a motor vehicle, it is common to provide a desired background noise in a motor vehicle interior of a motor vehicle. In particular, the noise of an internal combustion engine should be influenced so that they are perceived by motor vehicle occupants as pleasant. To enable a desired background noise in a motor vehicle interior by means of an active influence using sound actuators, it is necessary to describe the vehicle acoustics in a total transfer function. An overall transfer function describes the relationship between an actual output signal which describes an output sound signal influenced by the vehicle acoustics, for example in the motor vehicle interior, and an input signal which has been transmitted to the sound actuator and describes the input sound signal output by the sound actuator. By means of such a total transfer function, it is possible to drive a sound actuator with an input signal so that the actual output signal coincides with a reference output signal. The overall transfer function is stored in a control unit. The overall transfer function is usually generated by means of investigations on so-called reference vehicles and can be transferred to identical motor vehicles. However, this results in the problem that the vehicle acoustics of a particular motor vehicle may differ, for example due to series fluctuations, other equipment and / or aging processes. Thus, it is possible that the input signal output by the application of the reference total transfer function results in an actual output that deviates from the reference output.

In the EP 2 312 575 A2 For example, an apparatus and method for generating engine noise is described. The device is adapted to generate engine noise depending on the position of an accelerator pedal. It is provided that a sound actuator comprises a device for correcting the engine noise, which adjusts the detected position of the accelerator pedal.

In the US 6,386,039 B1 a device and a method for determining acoustic properties of a room, in particular a vehicle interior are described. The device is adapted to superimpose an output sound with a test signal that is imperceptible to humans, whose influence on the space is detected by the device. By means of the evaluation of the changes of the test signal, the acoustic properties of the room are determined.

In the DE 10 2015 112 094 A1 For example, a sound actuator for a vehicle and a vehicle having such a sound actuator will be described. It is a fixed to a fixed structure of the vehicle device which transmits a mechanical force on a component of the vehicle to thereby stimulate this to vibrate.

In the DE 102 46 048 A1 a device for seat occupancy detection is described in a vehicle. In the method, it is provided to emit acoustic signals through speakers in an interior of the vehicle and to detect by means of a microphone. A processor compares the acoustic signal emitted by the speakers with an acoustic signal received by the microphone to produce a transfer function therefrom. The transfer function is compared with stored transfer functions to determine a seat occupancy in the vehicle.

In the US 5 638 305 A a vibration and noise control arrangement is described. The arrangement is configured to detect reference signals and to update them in a reference signal storage means.

The invention is based on the object to provide a desired noise in an interior of a motor vehicle.

The object is solved by the subject matters of the independent claims. Advantageous developments of the invention are described by the dependent claims, the following description and the figure.

The invention provides a method for generating a compensation transfer function for a sound actuator of a motor vehicle. This is characterized in that an input signal is transmitted from a control unit to a sound actuator, which then outputs an input sound signal. A sensor unit detects an output sound signal influenced by the vehicle acoustics and transmits an actual output signal describing the output sound signal to the control unit. The control unit generates a total transfer function which describes the relationship between the actual output signal and the input signal. This total transfer function is compared to a reference total transfer function which determines the ratio of a reference transfer function. Output signal and the input signal describes. From this, the control unit determines a compensation transfer function which describes the ratio of the reference total transfer function and the total transfer function.

Overall, in other words, a control unit receives an input signal X generated and transmitted to a sound actuator. According to its nature, the sound actuator outputs an input sound signal, which is influenced by the vehicle acoustics or vehicle transmission characteristics and, after this influencing, is detected by a sensor unit as the output sound signal. The sensor unit outputs a corresponding actual output signal Y to the control unit. From the input signal X and the actual output signal Y the control unit calculates a total transfer function H _G and compares them to a total reference transfer function H _{G, ref} , From this, the control unit creates a compensation transfer function which determines the ratio of the total transfer function to the total reference transfer function H _{G, ref} describes.

• Gesamtübertragungsfunktion: $$\frac{Y}{X}=H_{Ges}$$
  
• Gesamtreferenzübertragungsfunktion: $$\frac{Y\text{'}}{X}=H_{Ges,Ref}$$
  
  wobei Y' das Referenz-Ausgangssignal ist.

$$H_{komp}\circ H_{Ges}=H_{Ges,Ref}$$

$$H_{komp}=\frac{H_{Ges,Ref}}{H_{Ges}}$$

Expressed in formulas, this means for the Laplace transforms of the signals and transfer functions:

• Total transfer function: $$\frac{Y}{X}=H_{Ges}$$
  
• Total reference transfer function: $$\frac{Y\text{'}}{X}=H_{Ges.Ref}$$
  
  where Y 'is the reference output.

$$H_{kOmp}\circ H_{Ges}=H_{Ges.Ref}$$

$$H_{kOmp}=\frac{H_{Ges.Ref}}{H_{Ges}}$$

A transfer function, also known as a system function, is a mathematical function that describes the relationship between the input signal and the output signal. This can be done for example by means of a Laplace-transformed. For example, the input signal in this invention may be an electrical signal that defines the input sound signal to be output by the sound actuator. This definition may include, for example, a volume, a phase, a frequency spectrum and / or a duration of the reproduction of the sound signal. An actual output signal is a signal which defines or describes an output sound signal detected by the sensor unit and influenced by the vehicle acoustics. By way of example, the actual output signal in this invention may be an electrical or digital signal which defines the actual output sound signal detected by the sensor unit. This definition may include, for example, a volume, a phase, a frequency spectrum and / or a duration of the reproduction of the actual sound signal. An actual output sound signal is a sound signal which is different in texture from the output sound signal of the sound actuator output because it has been changed by the vehicle acoustics. These changes can be caused for example due to the sound absorption and / or the Schallflexionseigenschaften the components of the motor vehicle and / or the geometry of the vehicle interior. A control unit may have, for example, a microprocessor or a microcontroller. A sound actuator may be for example a loudspeaker, a so-called shaker or a device which causes controlled vibrations in a component of the motor vehicle. An overall transfer function is a transfer function which describes the relationship between the actual output signal and the input signal. This makes it possible to describe a reaction of a system, in this case the respective motor vehicle, to a disturbance or excitation, in this case the input sound signal. An overall reference transfer function is a total transfer function which is the ratio of the reference output signal Y ' and the input signal X describes. The reference output signal differs from the actual output signal in that it does not describe the current acoustics of the respective vehicle, but rather the acoustics of a reference vehicle, which is recorded, for example, at a single time, which is for example from the same motor vehicle series as the respective motor vehicle. By knowing the overall transfer function, it is possible to define an input signal such that a desired reference output signal results. A sensor unit may for example be a microphone or a vibration meter of a component and be able to detect an output sound signal influenced by the vehicle acoustics. A compensation transfer function describes the ratio of the reference total transfer function and the total transfer function. In other words, the compensation transfer function describes how the overall reference transfer function differs from the overall transfer function.

For example, in the context of a possible inventive method a Control unit an input signal to a sound actuator, which is set up to influence the perceived in a motor vehicle interior engine noise, transmit, which then outputs an input sound signal in the form of a frequency sweep, also called "frequency sweep" or "sine sweep". The intensity of the input sound signal can be influenced frequency-dependent, for example, due to the sound absorption behavior of some materials and the resonance behavior of some components of the motor vehicle. The thus influenced output sound signal can be detected for example by a microphone and transmitted to the control unit as an actual output signal. The control unit can determine a total transfer function for the respective motor vehicle from the ratio of the input signal and the actual output signal. In the control unit, a total reference transfer function may be stored, which is a total transfer function of a reference motor vehicle. It may be that, for example due to series fluctuations, conversion measures or signs of wear, the total transfer function of the motor vehicle differs from the total reference transfer function of the reference motor vehicle. Thus, it is not possible to generate a particular reference output alone by the application of the total reference transfer function because the actual output differs from the reference output. To describe the differences in the overall transfer function to the overall reference transfer function, the control unit generates a compensation transfer function.

The invention provides the advantage that with the compensation transfer function H _comp a transfer function is provided, which makes it possible to describe differences in the vehicle acoustics of a respective vehicle to the vehicle acoustics of a reference vehicle. This compensation transfer function H _comp can be used to ensure that an input signal X can be adjusted so that a desired noise, in particular a motor noise-related background noise can be achieved.

At least once after the generation of the compensation transfer function H _comp is generated by the control unit, another input signal from the control unit by means of the compensation transfer function H _comp into an adapted input signal X ' is transformed. In other words, the control unit transforms at least one of its generated input signals X by means of the compensation transfer function H _comp into an adapted input signal X ' , For example, the control unit may perform the compensation transfer function H _comp use an input signal X into an adapted input signal X ' to transform, so that the actual output signal Y with the reference output signal Y ' matches. This results in the advantage that it is possible to produce a certain noise in a motor vehicle, even if the acoustics of the respective motor vehicle are not correct by the compensation reference transfer function H _comp , Ref is described.

The adapted input signal is transmitted by the control unit to the sound actuator. The sound actuator then outputs an adapted input sound signal. The sensor unit detects an adapted output sound signal influenced by the driving acoustics and transmits an adapted actual output signal to the control unit. The control unit determines a difference between the adapted actual output signal Y '' and the reference output signal. For example, an input signal from the control unit of the type may be transformed using the compensation transfer function such that an adapted actual output signal generated by the sensor unit and transmitted to the control unit coincides with the reference output signal. For verification, a difference between the adapted actual output signal and the reference output signal is determined. By means of this difference, it is possible to check the generated compensation transfer function, the sound actuator or the sensor unit.

A further development provides that the sound actuator and the sensor unit are both combined in the sound actuator, which is why this sound actuator is referred to here as a "sensitive sound actuator". The sensitive sound actuator is fixed to at least one component of the motor vehicle which can be excited to oscillate. In this development, the overall transfer function comprises at least one component transfer function for structure-borne noise. Due to the fact that both the sound actuator and the sensor unit are arranged in the sensitive sound actuator, the input sound signal is not affected, or only to a negligible extent, by an airborne sound component of the vehicle acoustics. The input sound signal is thus influenced by the at least one component. For this reason, the overall transfer function comprises the at least one component transfer function H _B , A sensitive sound actuator may, for example, be a device which comprises two coils in a magnetic field, one of the coils acting as a sound actuator and the other of the coils as a measuring coil. This sensitive sound actuator, for example, on a holder, which is attached to a system consisting of a disk cross member and a disc, fixed, whereby the overall transfer function H _Ges a Component transfer function of the holder H _H and a component transfer function of the system H _S consisting of the disc cross member and the disc comprises. This results in the advantage that the sound actuator and the sensor unit are combined in one device and that airborne sound influences are excluded.

In the above notation results for the overall transfer function H _Ges thus: $$\frac{Y}{X}=H_B=H_{Ges}$$

A further development provides that the sound actuator is fixed to at least one component of the motor vehicle which can be excited to oscillate and the sensor unit is arranged in a motor vehicle interior, wherein the sound actuator and the sensor unit are fluidically separated from one another by the at least one component. This includes the overall transfer function H _Ges the at least one component transfer function H _B and an air transfer function H _L , In other words, the input sound signal output by the sound actuator passes through the at least one component and the air in the region between the component and the sensor unit until it is detected by the sensor unit. The sound signal is thus influenced at least by the at least one component and the air. This may be the case that the sound actuator, for example, on a holder, which is attached to a system consisting of a disk cross member and a disc, is fixed. The sensor unit may for example be a microphone of a hands-free system and be arranged in a motor vehicle interior. The input sound signal influenced by the vehicle acoustics is thus influenced at least by the holder, the system of disk cross member and disk and the air in the vehicle interior. This refinement of the method affords the advantage that the influenced sound signal can be detected in the vehicle interior, which is the location in which the driver of the motor vehicle is located. This also allows sound-influencing changes to be detected in the vehicle interior and not just sound-influencing changes in a component.

In the above notation results for the overall transfer function H _Ges thus: $$\frac{Y}{X}=H_B\circ H_L=H_{Ges}$$

A development of the invention provides that the input sound signal is output as a pulse signal. In other words, the input sound signal is output as a sound signal having an output length under 1 second with a high amplitude. This has the advantage that the time and frequency behavior of a reverberation can be detected.

A development of the invention provides that the method has been carried out at least once during operation of the motor vehicle. In other words, it is provided that the method is carried out in a development at least once during vehicle operation. For example, it may be that the method is performed automatically immediately after the startup of the motor vehicle. This results in the advantage that the compensation transfer function is generated regularly and thus a desired background noise is ensured for each vehicle operation.

The invention also provides a sensitive sound actuator, ie a device which is set up both as a sound actuator and as a sensor unit. The sensitive sound actuator provides a coupling element, for example a rod, by means of which the sensitive sound actuator can be mechanically coupled to the component.

The sensitive sound actuator uses a magnetic force to act on the coupling element and thus the vibrating component with a force and / or movement. This makes it necessary to generate a magnetic field. For this purpose, a field generating device is provided, which may be, for example, a permanent magnet. It can be provided as a field generating means and an electromagnet, through which advantageously a stronger or adjustable magnetic field can be provided. On the other hand, weight can be saved for the generation of a magnetic field of predetermined field strength when using an electromagnet in comparison to a permanent magnet.

In the magnetic field, an electrical coil is arranged, which is adapted to act in response to a coil current flowing through the coil, the coupling element with the force and / or movement. For example, therefore, the electric coil can be arranged as a voice coil in the magnetic field. The structure described so far corresponds to that of the vibrator or shaker or sound actuator described above. A control unit configured to adjust the coil current in response to an actual output signal describing the body vibration of the component. In this way, therefore, the movement or force of the electric coil is set, which acts on the coupling element and thus on the component.

The said magnetic field has a range of inhomogeneity. In other words, the magnetic field strength and / or the orientation of the magnetic field lines differ within the homogeneity region at different locations or spatial points. The magnetic field is therefore locally inhomogeneous.

In this region of homogeneity, an electrical measuring coil coupled to the coupling element (ie, for example, the rod) is arranged, which is set up to output an electrical induction voltage induced in the measuring coil. Arranging the measuring coil in the inhomogeneity range ensures that a movement of the measuring coil and thus a movement of the coupling element connected to the measuring coil causes an induction voltage which can be used as the actual output signal. So moves the coupling element, this is signaled by the actual output signal. Thereafter, the control unit may adjust the coil current in the electrical coil to thereby impose a force and / or movement on the coupling element or to generate there.

The invention thus provides the advantage that it is recognized directly on the coupling element, whether this moves. This provides the control unit with an actual output signal that directly indicates whether the component coupled or connected to the coupling element vibrates or moves. Thereupon, by adjusting the coil current, the control unit can likewise fix or set directly on the coupling element to what extent this oscillation or movement of the coupling element is reduced or braked or damped. Thus, there is no significant corruption by a transfer function or time delay, which could be effective between sensor (measuring coil) and actuator (electric coil). Under body vibration is to be understood in the context of the invention, in particular a periodic movement with a frequency greater than 5 Hz, in particular greater than 10 Hz. An amplitude of the body vibration may be in a range of 100 μm to 30 cm.

The invention also includes a motor vehicle which is set up to carry out one of the cited methods. For this purpose, the motor vehicle has a sound actuator and a control unit. The motor vehicle according to the invention can be designed as a motor vehicle, in particular as a passenger car.

The invention also includes developments of the motor vehicle according to the invention, which have features as they have already been described in connection with the developments of the method according to the invention. For this reason, the corresponding developments of the method according to the invention are not described again here.

• 1 einen möglichen Ablauf eines erfindungsgemäßen Verfahrens;
• 2 eine mögliche Signalübertragung während der Durchführung des Verfahrens;
• 3 eine mögliche Signalübertragung während der Durchführung des Verfahrens unter Anwendung der Kompensationsübertragungsfunktion;
• 4 eine schematische Darstellung einer Ausführungsform des erfindungsgemäßen Kraftfahrzeugs mit einem sensitiven Soundaktor;
• 5 eine schematische Darstellung einer Ausführungsform des erfindungsgemäßens Kraftfahrzeug mit einem Soundaktor und einer im Fahrzeug Innenraum angeordneten Sensoreinheit;
• 6 eine schematische Darstellung eines möglichen sensitiven Soundaktors; und
• 7 eine schematische Darstellung eines weiteren möglichen sensitiven Soundaktors.

In the following, embodiments of the invention are described. This shows:

• 1 a possible sequence of a method according to the invention;
• 2 a possible signal transmission during the implementation of the method;
• 3 a possible signal transmission during the implementation of the method using the compensation transfer function;
• 4 a schematic representation of an embodiment of the motor vehicle according to the invention with a sensitive sound actuator;
• 5 a schematic representation of an embodiment of the motor vehicle according to the invention with a sound actuator and a sensor arranged in the vehicle interior sensor unit;
• 6 a schematic representation of a possible sensitive sound actuator; and
• 7 a schematic representation of another possible sensitive sound actuator.

The exemplary embodiments explained below are preferred embodiments of the invention. In the exemplary embodiments, the described components of the embodiments each represent individual features of the invention, which are to be considered independently of one another, which each further develop the invention independently of one another and thus also individually or in a different combination than the one shown as part of the invention. Furthermore, the described embodiments can also be supplemented by further features of the invention already described.

In the figures, functionally identical elements are each provided with the same reference numerals.

1 , shows a possible procedure of the method. A control unit 1 generates an input signal X and transmits this to a sound actuator 2 P1 , The input signal X may be, for example, an electrical signal. The sound actuator 2 gives after receiving the input signal X a sound signal SX from P2 , It can be a test character, its frequency spectrum and volume of the input signal X can depend. The input sound signal SX is influenced by the vehicle acoustics, which makes it here now an output sound signal influenced by the vehicle acoustics SY is. The influence can be done for example by a resonance behavior of a component. The output sound signal SY can by a sensor unit 3 are detected, which then an actual output signal Y to the control unit 1 transmitted P3 , At the sensor unit 3 For example, it could be a microphone. The actual output signal Y may be, for example, an electrical signal. The control unit 1 can by means of a comparison of the actual output signal Y with the input signal X a total transfer function H _Ges to generate P4 , In the control unit 1 can be a total reference transfer function H _{Ges, Ref} be saved. This can be a total transfer function H _Ges a reference motor vehicle. It may be that this overall reference transfer function H _{Ges, Ref} was generated experimentally or by means of a simulation. The control unit 1 can the overall transfer function H _Ges with the total reference transfer function H _{Ges, Ref} to compare. It may be that the control unit 1 a compensation transfer function H _comp generates the ratio between the total reference transfer function H _{Ges, Ref} and the overall transfer function H _Ges describes P5 , This may be, for example, a frequency-dependent compensation curve. The compensation transfer function H _comp can be used as a filter to generate an adapted input signal X ' from an input signal X be used. An adapted input signal X ' is an input signal X which by means of the compensation transfer function H _comp has been transformed such that the ultimately generated actual output signal Y with a reference output signal Y ' to a certain degree. It may be that at least once after the generation of the compensation transfer function H _comp through the control unit 1 an input signal X is produced P6 , It may be that the input signal X from the control unit 1 by means of the compensation transfer function H _comp into an adapted input signal X ' transformed and sent to a sound actuator 2 is transmitted P7 , It may be that the sound actuator has an adapted input sound signal SX ' outputs P8 , An output sound signal influenced by the vehicle acoustics SY ' can be from a sensor unit 3 are detected, which then an adapted actual output signal Y " can transmit to the control unit P9 , It may be that the control unit 1 a difference dY between the adapted actual output signal Y " and the reference output signal Y ' certainly P10 , It would be possible that in case of exceeding a limit by the difference dY another action by the control unit 1 can be initiated.

2 shows a possible signal transmission of an input signal X , An input signal X can be from a control unit 1 to be generated. It may be that the input signal X by a total transfer function H _Ges in the actual output signal Y is transformed. It may be that the total transfer function H _Ges from a component transfer function H _B the holder of the soundtracker H _H , a component commissioning function of a disk H _S and an air transfer function H _L composed. a disk may for example be a windscreen on which a disk cross member is fixed.

3 shows a possible signal transmission of an input signal X , It may be that the input signal X through a compensation transfer function H _comp and a total transfer function H _Ges in the actual output signal Y is transformed. This can be done with a reference output signal Y ' to match. It may be that the total transfer function H _Ges from a component transfer function H _B the holder of the soundtracker H _H , a component commissioning function of a disk H _S and an air transfer function H _L composed.

4 a motor vehicle automotive with a sensitive sound actuator 4 , In the execution the control unit transmits 1 the input signal X to the sound actuator 2 , which is in the sensitive sound actuator 4 can be arranged. The sound actuator can then receive an input sound signal SX output. The input sound signal can be due to the acoustic properties of the holder H and the system S consisting of a disc cross member and the disc are influenced, thereby producing an output sound signal SY can be. The influence can be due to the overall transfer function H _Ges be described, which is the component transfer function of the holder H _H and the system H _S The influencing can be, for example, of physically relevant parameters, such as the connection stiffness of the holder H be dependent. These can be, for example, over the life of the motor vehicle automotive to change. The output sound signal SY can from that in the sensitive sound actuator 4 arranged sensor unit 3 to be detected, which is the actual output signal Y transmitted to the control unit. It may be that the control unit 1 from the input signal X and the actual output signal Y a total transfer function H _Ges generated. It may be that the control unit has a total reference transfer function H _{Ges, Ref} with the total transfer function H _Ges compares and a compensation transfer function H _comp generated.

5 shows a motor vehicle with a sound actuator 2 and one in the vehicle interior 5 arranged sensor unit 3 , In the execution the control unit transmits 1 the input signal X to the sound actuator 2 , The sound actuator can then receive an input sound signal SX output. This can be done automatically during commissioning of the motor vehicle automotive respectively. The input sound signal SX may be, for example, a sine wave or a pulse signal. The input sound signal SX can be due to the acoustic properties of the holder H , the system S consisting of a disc cross member and the disc and the air L which is located between the disc and the sensor unit 3 is affected, thereby producing an output sound signal SY can be. The influence can be due to the overall transfer function H _Ges be described, which is the component Gesamtübertragungsfunktion the holder H _H , the system S and the air transfer function H _L composed. The influence can be, for example, on physically relevant parameters, such as, for example, the connection stiffness of the holder H be dependent. These can be, for example, over the life of the motor vehicle automotive to change. The output sound signal SY can from the in the motor vehicle interior 5 arranged sensor unit 3 to be detected, which is the actual output signal Y transmitted to the control unit. It may be that the control unit 1 from the input signal X and the actual output signal Y a total transfer function H _Ges generated. It may be that the control unit has a total reference transfer function H _{Ges, Ref} with the total transfer function H _Ges compares and a compensation transfer function H _comp generated.

6 shows a motor vehicle automotive , which may be, for example, a motor vehicle, especially a passenger car or truck. Shown is an example of a holder H which is connected to a system S , consisting of a disc cross member and a disc, is attached.

On the bracket H can be the sensitive sound actuator 4 concerning the disc S be held or fixed. The sensitive sound actuator 4 can also with a control unit 1 be connected, for example, may be formed on the basis of a microcontroller or microprocessor. The sensitive sound actuator 4 further includes a coupling element 6 on that with the bracket H can be connected.

By the output of an input sound signal SX can by means of a periodic excitation, the disc S and the holder H be excited to a body vibration. As a result, by way of example, the disk can act as a membrane and emit sound. It may be that the input sound signal SX from the acoustic properties of the mount H and the disc S is affected before it as the output shutter signal SY from the sensor unit of the sensitive sound actuator 4 is detected. The sensor unit 3 can after receiving the output sound signal SY an actual output signal Y to the control unit 1 to transfer.

The following is the operation of the sensitive sound actuator 4 related to both 1 as well 2 illustrated. From the sensitive sound actuator 4 are this a housing 7 and one in the housing 7 arranged field generating device 8th shown. The coupling element 6 can with a voice coil 9 be firmly connected. The voice coil 9 can be in a magnetic field 10 the field generating device 8th located. The voice coil 9 generally represents an electric coil according to the invention. The coupling element 6 and the voice coil 9 are relative to the field generator 8th movably mounted, eg for a translatory movement.

Through the control unit 1 can be an input signal X for generating an input sound signal SX by means of a body vibration by generating a magnetic field by means of the voice coil 9 in the disk S be generated by the magnetic field of the voice coil 9 with the magnetic field 10 the field generating device 8th interacts.

7 further illustrates how in addition to the voice coil 9 also a measuring coil 11 with the coupling element 6 connected or coupled so that both the voice coil 9 as well as the measuring coil 11 from the magnetic field 10 are permeated.

At least in the area of the measuring coil 11 has the magnetic field 10 an inhomogeneity area 12 on, so that by a proper movement of the measuring coil 11 with respect to the field-generating device 8th an electrical induction voltage in the measuring coil 11 is induced as the actual output signal Y to the control unit 1 can be transferred.

The input signal X can be the coil current in the voice coil 9 correspond.

By providing two coils 9 . 11 can be used for measurement by means of the measuring coil 11 on the one hand and for moving the coupling element 6 by means of the voice coil 9 different inductances L _S and L _A to be provided. This is an adaptation of the respective coil 9 . 11 to their task regardless of the other coil 9 . 11 possible.

The sensitive sound actuator 4 thus includes a sound actuator 2 , which is a delivery of an input sound signal SX based on an electromechanical transducer in the form of the voice coil 9 in the magnetic field 10 performs. It may be used, for example, in a motor vehicle interior 5 to produce or influence perceptible engine noise.

In the sensitive sound actuator 4 are the sound actuator 3 (or briefly actuator) in the form of the voice coil 9 with the coupling element 6 and the sensor unit 3 for detecting the output sound signal SY in the form of the measuring coil 11 as an integrated solution or integrated arrangement that provides the sensor unit 3 and the sound actuator 2 united in itself. As a technical basis or output device can be a sound actuator 2 be used. This sound actuator 2 can then be modified such that at least two voice coils are provided, namely the electric coil 9 for the movement generation and / or force generation on the one hand and the measuring coil 11 on the other hand. One of the voice coils thus becomes a sensor unit 3 and the other as a sound actuator 2 used. Thus, two tasks, namely the delivery of an input sound signal SX and the detection of an output sound signal SY Being united in a single component. The control takes place via a corresponding electronics of the control device 17 ,

Basis is thus e.g. a sound actuator or generally a structure-borne noise exciter with at least two separate voice coils, one of which is operated as a sensor and one as an actuator.

Overall, the examples show how the invention provides a method for generating a compensation transfer function which makes it possible to output an input signal of the type that gives a desired sound characteristic in a motor vehicle.

Claims (6)

Method for generating a compensation transfer function (H _Komp ) for a sound actuator (2) of a motor vehicle (motor vehicle), characterized in that a. an input signal (X) is transmitted from a control unit (1) to a sound actuator (2), b. by means of the sound actuator (2) an input sound signal (SX) is output, c. a sensor unit (3) detects an output sound signal (SY) influenced by the vehicle acoustics and transmits an actual output signal (Y) to the control unit (1), i. the control unit (1) generates a total transfer function (H _Ges ) which describes the relationship between the actual output signal (Y) and the input signal (X), e. the control unit (1), determined by comparing the overall transfer function (H _Ges) with a reference overall transfer function (H _{Ges, Ref),} which and the input signal (X) describes the ratio of a reference output signal (Y ') a compensation transfer function (H _Comp) which describes the ratio of the reference total transfer function (H _{Ges, ref)} and the overall transfer function (H _total), f. after the generation of the compensation transfer function (H _Komp ) by the control unit (1) a further input signal (X) is generated and the further input signal (X) from the control unit (1) by means of the compensation transfer function (H _Komp ) in an adapted input signal (X '. ), g. the adapted input signal (X ') is transmitted by the control unit to the sound actuator (2), h. an adapted input sound signal (SX ') is output by the sound actuator (2), i. the sensor unit (3) detects an adapted output sound signal (SY ') influenced by the vehicle acoustics and transmits an adapted actual output signal (Y ") to the control unit (1), and the control unit (1) outputs a difference (dS) between the adapted actual output signal (Y ") and the reference output signal (Y ') is determined. Method according to Claim 1 , characterized in that the sound actuator (2) and the sensor unit (3) are arranged to form a sensitive sound actuator (4), wherein the sensitive sound actuator (4) is fixed to at least one component of the motor vehicle (motor vehicle) which can be excited to oscillate, the total transfer function (H _Ges ) comprises at least one component transfer function (H _B ). Method according to Claim 1 , characterized in that the sound actuator (2) is fixed to at least one component of the motor vehicle (motor vehicle) which can be excited to oscillate and the sensor unit (3) is arranged in a motor vehicle interior (5), wherein the sound actuator (2) and the sensor unit ( 3) are mechanically separated from one another and acoustically coupled by the at least one component -the overall transfer function (H _Ges ) comprises at least one component transfer function (H _B ) and an air transfer function (H _L ). Method according to one of the preceding claims, characterized in that the input sound signal (SX) is output as a pulse sound signal. Method according to one of the preceding claims, characterized in that the method is carried out at least once during operation of the motor vehicle (motor vehicle). Motor vehicle (car), with a sound actuator and a control unit, which is set to a Method according to one of Claims 1 to 5 perform.

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