WO2019206866A1 - Device and method for testing the function of an antenna system - Google Patents

Abstract

The invention relates to a device for testing the function of an antenna system, more particularly for detecting foreign metal, the device comprising: an antenna system having a plurality of antenna units (AE0,..., AE15), wherein each of the antenna units (AE0,..., AE15), which comprise an antenna (A0,..., A15) and at least one resistor (R0,..., R15), is connected between a node (K) to which a bias voltage (Vofst) is applied and an associated input of the selection unit (SE); a computing unit (CU), which is designed to provide a control signal (CTRL_MUX_I, CTRL_MUX_II) for the selection unit (SE) at a first output (CUO1), the control signal defining which input of the selection unit (SE) should be connected to an output (SEO) of the selection unit (SE), and to receive at an input (CUI1) of the computing unit (CU) the antenna signal present at the output (SEO) of the selection unit (SE); a diagnosis circuit (DC), which is connected between the output (SEO) of the selection unit (SE) and a diagnosis voltage terminal and can be controlled by the computing unit (CU), a diagnosis voltage (Vaux) being present at the diagnosis voltage terminal. The computing unit (CU) is designed to infer a fault in the antenna system from the comparison of antenna signals at the output (SEO) of the selection unit (SE) which are determined with the diagnosis circuit activated and with the diagnosis circuit not activated.

Description

description

DEVICE AND METHOD FOR FUNCTIONAL TESTING OF AN ANTENNA SYSTEM

The invention relates to a device and a method for functional testing of an antenna system, which is used in particular for foreign metal detection.

In inductive charging, energy is transferred by means of the transformer principle over distances of a few centimeters to about 20 cm. Depending on the distance, structure and power, a large magnetic field can arise between an outer bottom coil (so-called primary coil) and a vehicle-side underbody coil (so-called secondary coil). The worse the two coils are aligned with each other, the larger the stray magnetic field (EMC) can become, the greater the magnetic load for humans and / or the less power can be transmitted to the battery of the vehicle. In addition, the efficiency of the transmission system deteriorates.

Due to the high transmission power, the alternating magnetic field which arises in the air gap in the energy transmission leads to an air-gap-shaped metallic body, such as e.g. a coin, a nail and the like, is heated. The case occurring in the metallic body temperatures can be so high that the enclosing the outer bottom coil housing, which usually consists of a plastic, could be damaged. In addition, there is a risk that flammable substances, such as those in the vicinity of the hot metallic body, may be present. Paper, causing the danger of the emergence of a major fire. On the other hand, if a person tries to remove the already heated metallic object from the outer bottom coil, there is a danger of burning.

Therefore, in inductive motor vehicle charging systems, there is the requirement of a so-called foreign metal detection, which is used in the Detection of a metallic object in the bottom gap deactivated the outer bottom coil and / or outputs a warning. Since even such foreign metal detection can have a defect, the sensors used for this purpose must be checked regularly for their functionality.

It is an object of the invention to provide an apparatus and a method for functional testing of a used for foreign metal detection antenna system of an inductive motor vehicle charging system, which are simple, inexpensive and reliable. In particular, a diagnosis of the measuring path and the receiving antennas before and during operation of the inductive charging system should be made possible.

These objects are achieved by a device according to the features of patent claim 1 and a method according to the features of patent claim 8. Advantageous embodiments will be apparent from the dependent claims.

According to a first aspect, a device for func onsprüfung an antenna system, in particular for Fremdme tallerkennung, proposed. The device and the antenna system are in particular components of an inductive motor vehicle charging system. The device comprises an antenna system having a plurality of antenna units, wherein each of the one antenna and at least one series resistor connected in series therewith each antenna unit between a biased bias node and an associated input of a selection unit of the device is connected before direction, wherein the selection unit comprises a number of multiplexers, which may be connected in particular in a cascade. The first resistors of the coupled to the inputs of a multiplex antenna units have at least two different Wi resistance values. An arithmetic unit of the device is adapted to provide a control signal for the selection unit be, which is determined by the control signal, which input of the selection unit with an output of Selection unit is to connect. The arithmetic unit of the device is further configured to receive at an input of the arithmetic unit the antenna signal applied to the output of the selection unit. The device further comprises a connected between the output of the selection unit and a diagnostic voltage connection and the Re chen unit controllable diagnostic circuit, wherein applied to the Di agnosespannungsanschluss a diagnostic voltage. The arithmetic unit is further designed to conclude from the comparison of when he activated and not activated diagnostic circuit he averaged antenna signals at the output of the selection unit to an error of the antenna system.

The principle underlying the device according to the invention is based on the fact that for each antenna of the antenna system with non-activated diagnostic circuit, a specific target voltage at the output of the selection unit results. Short circuits to ground, open connections and short circuits between two antennas can be detected by detecting a deviation from the specific setpoint voltage. By comparing the voltage present at the output of the selection unit with and without activated diagnosis circuit, the complete measuring path of the apparatus can be automatically checked beyond that.

The check of the functionality of the device can be used before and during the operation of the above-mentioned inductive charging device.

Depending on the number of multiplexers results in a corresponding number of antenna units, wherein a respective antenna unit is connected to an associated input of one of the multiplexers. A first resistor, in conjunction with the diagnostic resistor, provides a voltage divider, the output of the selection unit representing the junction between the diagnostic resistor and the first resistor of the (active) antenna unit being viewed. This allows different voltage potentials at the output of the Selection unit, depending on whether the diagnostic circuit is activated or not.

By a suitable choice, which antenna is provided with which first resistor (so-called series resistance), the correct function of the multiplexers can also be checked in selection units which comprise a multiplicity of multiplexers. The choice of series resistors is such that each multiplexer coupled to an antenna unit provides at least one input a different result than the other inputs. As a result, a drive error can be clearly detected. The selection of the resistance values is further carried out in such a way that a clear result pattern is delivered.

The device can be realized in a simple and cost-effective manner. In particular, compared to conventional antenna systems for detecting foreign metals, only a few additional components are necessary. The functionality check can be performed using the existing signal analysis structures. An evaluation of the functionality can be realized by the computing unit in the form of software.

According to an expedient embodiment, the diagnostic circuit comprises a series circuit of a controllable by the computing unit switching element and a diagnostic resistor. With the aid of the diagnostic circuit, it is possible to specifically change the voltage applied to the output of the selection unit by activating the diagnostic circuit. Due to the known value of the diagnostic resistance results - with the correct functioning of the antenna system - an expected deviation from the value of the signal at the output of the selection circuit, which can then be evaluated to assess the operability of the antenna system to.

In particular, the controllable switching element can be switched on or off by a control signal applied to a second output of the arithmetic unit for activating or deactivating the diagnostic circuit. This allows the output of the selec- tion circuit selectively connected to the diagnostic voltage terminal to which the diagnostic voltage is applied, or be decoupled from this.

Each antenna unit may further comprise a second resistor which is connected in parallel with the series circuit of the first resistor and the antenna of the respective antenna unit. By providing the second resistor, there is no floating when the antenna is disconnected from the biased node. In particular, the second resistor also permits testing of the functionality of the selection unit and its activation.

The arithmetic unit is expediently designed to connect each antenna unit by a suitable control signal for the Selekti onseinheit with disabled diagnostic circuit with the output of the selection unit and to detect all detected signals in a first result table for a complete test of the antenna system. The arithmetic unit is further adapted to connect each antenna unit by a suitable control signal for the selection unit with activated fourth diagnostic circuit with the output of the selection unit and to detect all detected signals in a second result table. From a comparison of the first with the second result table is then concluded that an error in the antenna system.

From the comparison of the first and the second result table, it is further possible to deduce the location of an error in the antenna system. As fault locations, the antenna unit assigned to an antenna, the antenna unit associated antenna connection, the selection unit or the signal conditioning unit, the lektionseinheit between the output of Se and the input of the arithmetic unit is connected, be distinguished.

According to a second aspect, a method for functional testing of an antenna system, in particular for Fremdme- tallerkennung, suggested. The antenna system comprises a plurality of antenna units, wherein each of the one antenna and at least one series-connected first resistor antenna units is respectively connected between a biased node and an associated input of a selection unit, wherein the selection unit on a number of multiplexers and wherein the first resistors of the antenna units coupled to the inputs of a respective multiplexer have at least two different resistance values. In the method, a control signal for the selection unit is provided by a computing unit at a first output, it being determined by the control signal which input of the selection unit is to be connected to an output of the selection unit, and at an input of the computing unit that at the output of the selection unit receiving antenna signal. Furthermore, a diagnostic circuit is selectively controlled. From the comparison of detected when activated and non-activated diagnostic circuit antenna signals at the output of the selection unit is then concluded that an error of the anten nesystems.

The invention has the same advantages as described above in connection with the device according to the invention.

For a complete test of the antenna system, each antenna unit is expediently connected to the output of the selection unit by a suitable control signal for the selection unit with the diagnostic circuit deactivated and all detected signals are recorded in a first record table. Furthermore, each antenna unit is connected to the output of the selection unit by a suitable control signal for the selection unit with activated diagnosis circuit, and all detected signals are detected in a second result table. From a comparison of the first with the second result table is then concluded that an error in the antenna system. According to a further expedient embodiment, the location of a fault in the antenna system is concluded from the comparison of the first and the second result table. The error can be limited to the following locations: the antenna assigned to an antenna unit, the antenna connection assigned to an antenna unit, the selection unit or a signal conditioning unit connected between the output of the selection unit and the input of the arithmetic unit.

The invention will be described in more detail below with reference to an example Ausfüh tion in the drawing. Show it:

Fig. 1 is a schematic representation of an electrical

 Equivalent circuit diagram of an inventive device for functional testing of an antenna system for detecting foreign metal;

FIG. 2 is an enlarged view of a selection unit of the device of FIG. 1; FIG.

Fig. 3 is a matrix in the result values for the possible

 Ansteuersituationen the selection unit of Figure 2 are shown, when the antenna system has no malfunction;

Fig. 4 is a matrix in the result states for a

 Multiplexers of the selection unit of Figure 2 are shown when an error occurs; and

5 shows an expanded error matrix when occurring under different error conditions at the selection unit.

Fig. 1 shows a schematic representation of an electrical equivalent circuit diagram of a device according to the invention for functional testing of an antenna system. The antenna system is used for foreign metal detection, which in the detection of a metallic object, such as a coin, a screw, a nail and the like, issues a warning and / or disables a connected to the device technical system. The device serves to be able to check defects in the antenna system and connected to the antenna system signal processing components on their ability to function.

In particular, the device described below is provided for use in an inductive vehicle charging system, in which energy is transmitted by means of the transformer principle over distances of a few centimeters to about 20 cm. In such a power transmission system is formed between an outer bottom coil and a vehicle-side underbody coil depending on the distance, structure and power a large magnetic field. When the bottom coil is active, a metallic body located in the effective region of the bottom coil can be heated. The temperatures which occur in the metallic body can become so high that the housing enveloping the outer bottom coil, which typically consists of a plastic, can be damaged. In addition, there is a danger that flammable substances located nearby may be ignited by the hot metallic body. There is also the danger of burning for living beings, which comes into contact with the already heated me tallischen object.

The apparatus described below allows a functional test of the antenna system and the antenna system downstream drive and / or Signalverarbei processing components with regard to short circuits, open lines and the like.

The antenna system to be tested comprises a plurality of antenna units, in the example AE0,..., AE15. Each of the antenna units AE0,..., AE15 comprises an antenna A0,..., A15, a first resistor R0,..., R15 (so-called series resistance), which is connected in series with the antenna A0, a purely op tional, second resistor RP0, ..., RP15, which is connected in parallel to the series circuit of the first resistor R0, ... R15 and the antenna A0, ..., Al5. Each of the antenna units AEO, AE15 is in each case interconnected between a node K acted upon by a bias voltage Vofst and an input of a selection unit SE assigned to the respective antenna unit AEO,..., AE15. Depending on the voltage supply, not shown, the bias voltage may have a positive or a negative value (in the case of a unipolar power supply) or may be at a ground potential. The interconnection is such that a respective node of antenna A0, ..., Al 5 and parallel resistor RPO, ..., RP15 to the node K and a node from the series resistor R0, ..., R15 and the parallel resistor RPO, ..., RP15 of a respective antenna unit with a respective uniquely assigned input SEI0, ..., SEI15 the selection unit SE is connected.

In the exemplary embodiment shown in FIG. 1, the selection unit SE consists of a cascade of multiplexers MUX, MUXa,..., MUXd. In this case, the selection unit has only two cascade stages MUX I and MUX II at play. The Kas kadenstufe MUX II, which represents the input of the selection unit SE, in the present embodiment, for example, four multiplexers MUXa, ..., MUXd on. The Kaska denstufe MUX I, which represents the output of the selection unit SE, has the multiplexer MUX. Accordingly, the outputs of the multiplexers MUXa, ..., MUXd the second Kas kadenstufe MUX II are connected to the inputs of the multiplexer MUX of the first cascade stage MUX I. An output of the multiplexer MUX represents an output SEO of the selection unit SE.

It is understood that the selection unit SE can be formed from a different number of cascade stages (one, three or more). Likewise, the number of multiplexers from the second cascade stage MUX II can be chosen differently than here. As will also be apparent from the following description, each multiplexer MUXa, ..., MUXd, MUX has four inputs and one Exit on. It goes without saying that this too is only by way of example.

The output SEO of the selection unit SE is connected via a Sig nalverarbeitungseinheit SPU, which includes, for example, a filter and an amplifier and the like, with an input CUI a computing unit CU. The arithmetic unit CU is designed to provide a control signal for the selection unit SE at a first output CUO1, it being determined by the control signal which input SEI0,..., SEI15 of the selection unit SE is to be connected to the output SEO of the selection unit SE. As a result, the arithmetic unit can determine which antenna unit AE0,..., AE15 is connected to the arithmetic unit for evaluating an antenna signal.

Due to the multiple cascade stages having selection unit SE two control signals CTRL_MUX_I and CTRL_MUX_II for controlling the multiplexer MUX the first cascade stage MUX I and the multiplexer MUXa, ..., MUXd the second cascade stage MUX II are needed in the present case. In practice, this means that the arithmetic unit CU for this purpose comprises four first outputs or output terminals, which are summarized here under the first output CUOl.

The arithmetic unit CU is further configured to receive at its input CUI1 the antenna signal present at the output SEO of the selection unit SE and prepared by the signal processing unit SPU.

The device further comprises a diagnostic circuit DC. The diagnostic circuit DC includes a series circuit of a controllable switching element S1 and a diagnostic resistor DR. The series circuit of the controllable switching element S1 and the diagnostic resistor DR is connected between a diagnostic voltage terminal Kl and the output SEO of the selection unit SE. The control of the controllable switching element S1 is carried out with the aid of a control signal CTRL_DIAG, which is output at a second output CU02 by the arithmetic unit CU. With the aid of the output at the second output CU02 the arithmetic unit CU control signal CTRL_D IAG can be determined by the computing unit CU, whether the controllable switching element S1 is switched on or off. In the following description, the diagnostic circuit DC is active or ak tiviert in a conductive switched controllable switching element S1 and in a blocking switched controllable switching element S1, the diagnostic circuit DC referred to as not active or disabled.

The diagnostic resistor DR forms together with the Serienwi resistance R0, R15 of the control unit CU just selected antenna unit AEO, AE15 a voltage divider, wherein the voltage applied to the output SEO of the selection unit SE depending on the activation or deactivation of the diagnostic circuit DC results in a different voltage level. From the comparison of the detected when activated and not ak tivated diagnostic circuit DC antenna signals at the output SEO of the selection unit SE can be concluded by the Re cheneinheit CU on an error of the antenna system and the location of the occurrence of the error.

Since the resistance values of the diagnostic resistance DR and the resistance values Ra, Rb of the series resistances R0,..., R15 of the antenna units AEO,..., AE15 are known, AEO,..., AE15 results for each of the antenna units when the function is intended the output SEO of the selection unit SE he waeable voltage value, both with activated as well as deactivated diagnostic circuit DC. If an error occurs, be it due to an open connection of the antenna, a short circuit to ground or a short circuit between two antennas, the output SE of the selection unit SE for the antenna unit AEO,..., AE15 results in a voltage value deviating from the expected value , This can be evaluated by the arithmetic unit CU and, depending on the result of the evaluation, it can be concluded that a function or an error has occurred as well as its location. The basic principle of diagnosis is as follows:

A diagnosis of the antennas A0, Al 5 or the connection between a respective antennas A0, A15 to the arithmetic unit CU can by the knowledge of each antenna A0, Al 5 known and defined series resistance of the size Ra, Rb and the known size of the diagnosis resistor DR be determined. For each of the antennas A0, Al5 results in a specific

Target voltage. Short circuits to ground, open connections and short circuits between two antennas A0, ..., A15 can be determined in this way. If the voltage measured at the output SEO is Vsns = Vref (which results from the known quantities of the series resistor Ra, Rb and the size of the diagnostic resistor DR), then there is no error. When shorted to ground, Vsns is much smaller than Vref. For an open line: Vsns> Vref. If there is a short circuit to the neighboring antenna: Vsns <Vref. By comparing Vsns with and without activated diagnostic circuit DC, the measuring path of the signal processing unit SPU is also automatically checked.

By evaluating the voltage value at the output SEO of the selection unit, it is possible to deduce the following errors depending on the magnitude of the voltage value: No error is present if the voltage value is Va or Vb if the diagnostic circuit DC is activated. An open line results in a voltage value Vc. A short circuit to ground results in a voltage value Vd. A short circuit to an adjacent antenna results in a voltage value Ve, Vf or Vg depending on whether the adjacent antenna has the same series resistance value Ra or Rb or a different series resistance value Ra or Rb. The voltage values Va, Vb, Vc, Vd, Ve, Vf and Vg are different voltage values which result from the known values of the series resistance Ra, Rb and the size of the diagnosis resistor DR and the error which is occurring. The diagnosis of the control of the multiplexer MUX, MUXa, MUXd thus takes place inter alia by the use of at least two different series resistances Ra, Rb per multiplexer MUXa, ..., MUXd. By a suitable choice, which of the antennas A0, ..., Al 5 are provided with which series resistance value Ra or Rb, all multiplexer drives can be checked for correct operation by the control signals CTRL_MUX_I, CTRL_MUX_II. The prerequisite for this is that each multiplexer MUXa, ..., MUXd of the second cascade stage MUX II has a so-called "marker bit" MB (see FIGS. 4 and 5), ie each input of the currently considered multiplexer MUXa or MUXb or MUXc In addition, each multiplexer MUXa, ..., MUXd of the second cascade MUX II must supply a unique result pattern.

This procedure is explained below on the basis of the selection unit SE shown in FIG. 2 and the result matrices shown in FIGS. 3 to 5.

The diagnosis of the type described here can, if the antenna system is installed in an inductive charging system, be carried out before starting the charging process or during the inductive charging process. In the latter case it is expedient to interrupt the charge for a short time and to carry out the diagnosis as described herein. Alternatively, the antennas A0, ..., A15 can also be designed such that the signal of the transmitting antenna does not completely compensate for zero, as is the case with conventional metal detectors. Thus, in normal operation, a certain minimum signal can be measured by the computer unit. If this signal fails for one or more antennas, an error can be immediately deduced.

FIG. 2 shows an enlarged illustration of the selection unit SE from FIG. 1 for explaining the drive signals used in the matrices of FIGS. 3 to 5. Visible are those of the Arithmetic unit CU for controlling the multiplexer MUX, MUXa, MUXd used control signals CTRL_MUX_I and CTRL_MUX_II, wherein the bit values for the drive signal CTRL_MUX_I with yy and bit values for the drive signal CTRL_MUX_II are specified with xx. Furthermore, the inputs SEI0, SEI15 of the multiplexers MUXa, MUXd can be seen. It is readily apparent that the multiplexer MUXa the inputs SEI0, ..., SEI3, the multiplexer MUXb the inputs SEI4, ..., SEI7, the multiplexer MUXc the inputs SEI8, ..., SEIH and the multiplexer MUXd the Inputs SEI12, ..., SEI15 includes.

FIG. 3 shows a matrix in which the result values for the possible triggering situations of the selection unit SE are shown. In the matrix, the signal values for yy possible for the control signal CTRL_MUX_I are indicated in columns and those for the control signal CTRL_MUX_II for the values xx in rows. The matrix values Va and Vb identify the voltage values Vsns at the output SEO of the selection unit SEO. The voltage values Va and Vb result as a function of the resistance values Ra, Rb of the series resistances R0,..., R15 assigned to the respective input SEI0,..., SEI15. It can be seen from this matrix that the value of the series resistor R3 at the input SEI3 of the multiplexer MUXa has the value Rb, while the values of the series resistances of the other inputs SEI0, SEI1 and SEI2 of the multiplexer MUXa have the value Ra.

Likewise, the value of the series resistor R6 connected to the input SEI6 of the multiplexer MUXb is Rb, while the values of the other series resistors of the multiplexer MUXb are Ra. For the multiplexers MUXc and MUXd, the value of the series resistor R9 and the value of the series resistor R12 connected to the inputs SEI9 of the multiplexer MUXc and SEI12, respectively, of the multiplexer MUXd are Rb, while all other values of the series resistors are Ra. The positions at which the voltage value Vb results at the output SEO of the selection unit SE due to a different voltage value Vsns can be referred to as marker bit MB. The tag bits are indicated by an ellipse in the matrix of FIG. When an error occurs and the diagnostic circuit is activated, deviating voltage values Vsns (Vc, Vd, Ve or Vg, see above) result at the output SEO of the selection unit SE. By comparing the result values of the matrix for a functioning antenna system from an antenna system that has an error, an error can be concluded.

FIG. 4 shows a further result matrix which limits errors in the occurrence of a triggering error of the selection unit SE (first four columns in FIG. 4, so-called "stuck at" error) and in the event of a short circuit in the control lines for triggering the Selection unit SE (last four columns, so-called "control lines shorted" error). 4 shows the result table if there is a control error of the line for the multiplexer MUXb of the second cascade stage MUX II.

In contrast, FIG. 5 shows an expanded error matrix when there is an error in the activation of the selection unit SE with respect to the high or low bit for the multiplexer MUX of the first cascade stage MUX II.

Claims

claims

A device for functional testing of an antenna system, comprising:

 - An antenna system with a plurality of antenna units (AEO, ..., AE15), wherein each of the one antenna (A0, ..., A15) and at least one connected in series to the first Wi resistance (R0, ..., R15 ) comprehensive antenna units (AEO, ..., AE15) in each case between a, with a bias voltage (Vofst) acted upon node (K) and an associated input of a selection unit (SE) is connected;

 - Wherein the selection unit (SE) comprises a number of multiplexers and wherein the first resistors of the coupled to the inputs of a respective multiplexer (MUXa, ..., MUXd) antenna units (A0, ..., A15) have at least two different resistance values ;

 a computing unit (CU) designed to

 at a first output (CUOl) provide a control signal (CTRL_MUX_I, CTRL_MUX_II) for the selection unit (SE), which is determined by the control signal, which input of the selection unit (SE) to be connected to an output (SEO) of the selection unit (SE) , and

 at an input (CUIl) of the arithmetic unit (CU) to receive the antenna signal applied to the output (SEO) of the selection unit (SE);

 - Connected between the output (SEO) of the selection unit (SE) and a diagnostic voltage connection and by the arithmetic unit (CU) controllable diagnostic circuit (DC), wherein at the diagnostic voltage terminal a diagnostic voltage (Vaux) is applied;

- Wherein the arithmetic unit (CU) is adapted to close from the comparison of detected at activated and not activated Di agnoseschaltung antenna signals at the output (SEO) of the selection unit (SE) on an error of the antenna system.

2. Device according to claim 1, characterized in that the diagnostic circuit (DC) comprises a series circuit of a by the arithmetic unit (CU) controllable switching element (Sl) and a diagnostic resistor (DR).

3. Device according to claim 2, characterized in that the controllable switching element (Sl) by a at a second output (CU02) of the arithmetic unit (CU) applied control signal

 (CTRL_DIAG) for activating or deactivating the diagnostic circuit (DC) is conductive or blocking switchable.

4. Device according to one of the preceding claims, characterized in that the multiplexers are connected in a cascade.

5. Device according to one of the preceding claims, characterized in that each antenna unit (AE0, ..., AE15) comprises a second resistor (RP0, .., RP15), which connects in parallel to the series circuit of the first resistor and the antenna is.

6. Device according to one of the preceding claims, characterized in that the arithmetic unit (CU) is adapted for a complete test of the antenna system

 each antenna unit (AE0, ..., AE15) by a suitable control signal (CTRL_MUX_I, CTRL_MUX_II) for the selection unit (SE) with deactivated diagnostic circuit (DC) to the output (SEO) of the selection unit (SE) to connect and all detected signals to capture in a first result table, each antenna unit (AE0, ..., AE15) by a suitable control signal (CTRL_MUX_I, CTRL_MUX_II) for the selection unit (SE) with activated diagnostic circuit (DC) with the output (SEO) of the selection unit (SE ) and to record all the signals obtained in a second result table,

from a comparison of the first and the second result table on an error in the antenna system.

Device according to claim 6, characterized in that, from the comparison of the first and the second result table, the location of an error in the antenna system is deduced, the location of the error being from the group

 the antenna associated with an antenna unit (AE0, ..., AE15),

 the antenna connection associated with an antenna unit (AE0, ..., AE15),

 the selection unit (SE),

 a signal conditioning unit (SPU) which is interconnected between the output (SEO) of the selection unit (SE) and the input (CUI) of the arithmetic unit (CU),

is.

8. A method for functional testing of an antenna system comprising a plurality of antenna units (AE0, ..., AE15), wherein each of the one antenna (A0, ..., A15) and at least one series-connected first resistor (R0, ..., R15) comprehensive antenna units (AE0, ..., AE15) in each case between a, with a bias voltage (Vofst) acted upon node (K) and an associated input of a selection unit (SE) is connected, wherein the selection unit (SE) a plurality of multiplexers and wherein the first resistors of the antenna units (A0, ..., A15) coupled to the inputs of a respective multiplexer (MUXa, ..., MUXd) have at least two different resistance values,

 in which by a computing unit (CU)

 at a first output (CUOl) a control signal (CTRL_MUX_I, CTRL_MUX_I I) for the selection unit (SE) is provided, which is determined by the control signal, which input of the selection unit (SE) with an output (SEO) of the selection unit (SE) to connect, and

 at an input (CUIl) of the arithmetic unit (CU) the antenna signal present at the output (SEO) of the selection unit (SE) is received;

- a diagnostic circuit (DC) is selectively controlled; - Is concluded from the comparison of detected at activated and not activated diagnostic circuit antenna signals at the output (SEO) of the selection unit (SE) on an error of the antenna system.

9. The method of claim 8, wherein for a complete test of the antenna system

 each antenna unit (AE0, ..., AE15) is connected by a suitable control signal (CTRL_MUX_I, CTRL_MUX_II) for the selection unit (SE) with deactivated diagnostic circuit (DC) to the output (SEO) of the selection unit (SE) and all detected signals be captured in a first result table,

 each antenna unit (AE0, ..., AE15) by a suitable control signal (CTRL_MUX_I, CTRL_MUX_II) for the selection unit (SE) with activated diagnostic circuit (DC) to the output (SEO) of the selection unit (SE) is connected and all detected signals be recorded in a second result table,

 is concluded from a comparison of the first with the second results nistabelle on an error in the antenna system.

10. The method of claim 8 or 9, wherein from the comparison of the first with the second result table on the location of an error in the antenna system is concluded, wherein the location of the error from the group

 the antenna associated with an antenna unit (AE0, ..., AE15),

 the antenna connection associated with an antenna unit (AE0, ..., AE15),

 the selection unit (SE),

 a signal conditioning unit (SPU) which is interconnected between the output (SEO) of the selection unit (SE) and the input (CUI) of the arithmetic unit (CU),

is.