DE19644339C1 - Device for transforming an antenna impedance - Google Patents

Abstract

The invention concerns a device (1) used for transforming an impedance. The device (1) comprises an input (5) and an output (10). One network is provided in each case for different impedances and adapts the latter to a predetermined impedance. At least one, preferably digital, control signal can be fed to the device (1) as a function of the impedance present at the input (5) at a precise moment. On the basis of this at least one control signal, the network associated with this impedance can be switched between the input (5) and the output (10).

Description

State of the art

The invention relates to a device for transformation an antenna impedance according to the type of the main claim out.

From DE-OS 2 106 647 is an antenna for a motor vehicle known stuff where the antenna impedance to the impedance the supply line of a vehicle radio receiver by means of of a reactance element.

A radio transmission system is already known from US 4,486,722 known that includes a transceiver that ver with others comparable transmission systems via electromagnetic Waves and an antenna communicate. The antenna impedance must for maximum power transmission to the off be adjusted impedance of the transceiver. To do this, a PIN-diode-switched network depending on the Be drive frequency of the transceiver tuned so that a ma ximal power transmission at the tuned frequency between the antenna and the transceiver. The Tran sceiver is used for quick tuning by a mic processor controlled, the automatic tuning of the Transceivers. By means of the PIN diodes is inside the PIN diode-switched network a vote of Network by adding series inductances. A selected capacity can also be added the.  

Advantages of the invention

The inventive device with the features of Main claim has the advantage that ver different antenna impedances each provided a network is an adaptation of the antenna impedances to the Input impedance of the receiving stage takes place. In this way the losses occurring during the adjustment are reduced.  

It is also advantageous that the device has at least one preferably digital control signal depending on the just at the entrance to the connection of the receiving antenna existing antenna impedance can be supplied and that due to of the at least one control signal Antenna impedance associated network between the input to connect the receiving antenna and the output to Connection of the reception stage is switchable. In this way the respective antenna impedance can be automatically connected to the Input impedance of the receiving stage can be adjusted. Furthermore can match any antenna impedance relatively well conjugates complex input impedance through the receive stage Transformation to be approximated. Furthermore, the Switching by means of control signals is particularly simple and Effortless, especially when it comes to digital Control signals that involve the use of software enable.

By the measures listed in the subclaims advantageous developments and improvements in Main claim specified device possible.

It is particularly advantageous that the device at least one control signal depending on at least a specifiable, especially narrow-band Receiving frequency range can be supplied. That way a frequency-selective adaptation of the antenna impedance to the Input impedance of the receiving stage possible. An advantage of narrow-band adjustment also consists of a preselection that apart from the at least one definable Receiving frequency range lying frequency components that are mismatched. This results in a higher one Intermodulation resistance.  

It is also advantageous that the device at least one control signal depending on at least a specifiable and connectable to the device Antenna type can be fed. In this way, the Impedances of any antennas to the input impedance of the Adjust reception level. It is also, for example, at the combination of the device with a Antenna switching diversity arrangement possible, a single Use matching network for all antennas.

It is advantageous that the network by means of at least one Diode, preferably a PIN diode, between the input to connect the receiving antenna and the output to Connection of the reception stage is switchable and that at least one control signal the at least one diode controls. This is a particularly simple and Possibility to switch the desired Transformation network between the entrance to the connection the receiving antenna and the output for connecting the Reception level possible.

It is also advantageous that an adaptation circuit is provided, which includes the individual networks and between the input for connecting the receiving antenna and the output is connected to connect the receiving stage. In this way, the individual networks are space-saving integrated a single matching circuit.

It is also advantageous that the adaptation circuit comprises at least one impedance, preferably by the at least one diode can be bridged or switched on. On in this way the scope of the networks can be reduced Impedance adaptation to the connection or bridging of Reduce impedances in the matching circuit so that the Scope of the matching circuit is further reduced.  

It is particularly advantageous that a memory is provided is in which the at least one specifiable Reception frequency range and / or antenna type is stored and that the memory depending on the choice of at least a reception frequency range stored in the memory and / or antenna type the at least one control signal generated. This is a particularly simple one Assignment of the predefinable reception frequency range and / or Antenna type to that for the assigned network necessary control signal possible.

It is also advantageous that the at least one in Memory stored reception frequency range and / or Antenna type is assigned to the network at which at the output the adaptation circuit has the highest reception level, and that because of the memory when choosing this Reception frequency range and / or antenna type generated Control signal a circuit of this network between the Input for connecting the receiving antenna and the output for The reception stage is connected. That way gets one when using a read-write memory adaptive circuit that can be learned, even when the Reception conditions the connection of an optimal Network enabling the impedance matching between the Input for connecting the receiving antenna and the output for Connection of the reception stage enables.

It is also advantageous that the assignment of the at least a reception frequency range stored in the memory and / or antenna type to a network using a Initialization process takes place. That way is one quick assignment, for example after assembly or after a replacement of an antenna system on one Motor vehicle possible.  

It is also advantageous that the assignment of the at least one reception frequency range stored in the memory and / or Antenna type to a network when choosing at least one Receive frequency range takes place. This way several possible reception frequency ranges for each each assignment process takes less time taken so that the individual mapping process by the user is perceived less clearly.

drawing

Embodiments of the invention are in the drawing shown and in the following description explained. Show it

Fig. 1 is a representation of adjustment losses in a Smith chart,

Fig. 2 shows a frequency spectrum of the matching loss of multiple receiving frequency bands,

Fig. 3 shows a matching circuit,

FIGS. 4 to 7 are each a block diagram of a receiving device with the matching circuit,

Fig. 8 is a flow chart for the initialization of an association table, and

Fig. 9 is a mapping table.

Description of the embodiments

Through a matching circuit 40 of FIG. 4 is adapted to the impedance of a first reception antenna 15 to the input impedance of a receiving stage 20. In the case of error-free matching, the matching circuit 40 transforms the input impedance of the receiving stage 20 to the complex impedance conjugated to the impedance of the first receiving antenna 15 . Since the impedance of the first receiving antenna 15 depends on the received frequency and the antenna type, an error-free adaptation is generally not possible, so that losses result from mismatches. This can be problematic in particular in the case of mobile reception, for example in the case of a car radio, since antennas with unfavorable impedance properties are often used there, such as so-called hidden on-glass antennas.

To minimize these mismatch losses, in the design of the adaptation circuit 40 , based on a first approximation constant input resistance of the receiving stage 20 of 50 Ω, for example, in a Smith chart according to FIG. 1, the adaptation losses by circles of constant mismatch losses, which are also referred to as input power circuits, are described. A group of such input power circuits is identified by way of example in FIG. 1 with the reference symbol 60 . The matching circuit 40 contains impedances which are also frequency-dependent, so that the input power circuits are also frequency-dependent, which can be seen in a cylindrical displacement of the input power circuit 60 in FIG. 1. The representation in FIG. 1 is based on a frequency range from 76 to 108 MHz. The center point 65 of the input power circuit 60 is subjected to a corresponding shift. The Smith chart is traversed by the antenna impedance depending on the antenna type and the reception frequency. If the antenna impedance corresponds to the center 65 of the input power circuit 60 , the adaptation of the antenna impedance to the input impedance of the receiving stage 20 via the matching circuit 40 is error-free. The radius of the input power circuit 60 , which is depicted in FIG. 1, is determined by the maximum permissible adaptation losses, so that in the exemplary embodiment according to FIG. 1, there is a loss of 1 dB as the maximum permissible adaptation loss for antenna impedances lying on the input power circuit 60 . The adaptation losses increase with increasing distance from the center 65 of the input power circuit 60 . Therefore, input power circuits with high adaptation losses cover larger areas than those with smaller ones. The optimization goal is now to cover at least the part of the Smith chart traversed by the antenna impedances with the input power circuits which can be implemented by the adaptation circuit 40 and which allow the maximum permissible adaptation losses, the radius of the input power circuits should be as small as possible.

The frequency spectrum that can be received by the first receiving antenna 15 is divided in the exemplary embodiment according to FIG. 2 into six receiving frequency ranges 25 ,..., 30 . In the extreme case, the reception frequency ranges 25 , ..., 30 can be so small that they only cover a single reception frequency. With a narrow-band adaptation, lower adaptation losses can be realized than with an adaptation over a broader frequency range. For each reception frequency range 25 ,..., 30 , the antenna impedance is matched to the input impedance of the reception stage 20 . The adaptation takes place in each case via a network which, according to FIG. 3, is connected between an input 5 for connecting the receiving antenna 15 and an output 10 for connecting the receiving stage 20 . All of the networks required to adapt the antenna impedance to the input impedance of the receiving stage 20 are integrated in the matching circuit 40 , with a switchover between the different receiving frequency ranges 25 ,... 30 or the associated networks via PIN diodes 35 , 36 , 37 , 38 he follows. This results in different input power circuits for the different networks in the Smith chart according to FIG. 1, each with a 1 dB adaptation loss.

In Fig. 2, in which the damping A is received by the first receiving antenna 15 signals plotted over the frequency f, is obtained for each network as a function of the assigned reception frequency range 25, ..., 30, a separate frequency response. Again, the frequency range from 76 MHz to 108 MHz is shown. Thus, based on the frequency responses according to FIG. 2, the network can be selected for a desired reception frequency in which the adaptation losses, that is to say the attenuation A, are minimal.

An exemplary embodiment of an adaptation circuit 40 is given in FIG. 3. The input 5 is for connection of the first receiving antenna 15 via a DC isolation capacitor 70 , a first PIN diode 35 in the direction of flow and a parallel connection of an RF blocking inductance 75 and a first capacitor 50 with a predeterminable DC voltage potential

 connected.

The input 5 for connecting the first receiving antenna 15 is via a further DC isolation capacitor 70 , a second PIN diode 36 in the direction of flow and a first inductor 45 also with the DC voltage potential

connected. The DC potential

is connected to a reference potential via a third capacitor 52 . The input 5 for connecting the first receiving antenna 15 is connected via a second inductor 46 and a second capacitor 51 to the output 10 for connecting the receiving stage 20 . Furthermore, the input 5 for connecting the first receiving antenna 15 is connected via a further DC isolation capacitor 70 , a third PIN diode 37 in the forward direction, a fourth PIN diode 38 in the blocking direction and a further DC isolation capacitor 70 to the output 10 for connecting the receiving stage 20 . The DC potential

is connected via a further RF blocking inductance 75 to the cathode of the third PIN diode 37 , which is connected via a further direct current separation capacitor 70 between the second inductor 46 and the second capacitor 51 . The anode of the first PIN diode 35 is connected to a first control signal input U1 via a further RF blocking inductance 75 and a resistor 80 . The anode of the second PIN diode 36 is connected to a second control signal input U2 via a further RF blocking inductance 75 and a further resistor 80 . The anode of the third PIN diode 37 is connected to a third control signal input U3 via a further RF blocking inductance 75 and a further resistor 80 . The anode of the fourth PIN diode 38 is connected to a fourth control signal input U4 via a further RF blocking inductance 75 and a further resistor 80 .

The impedance transformation is determined by the first capacitor 50 , the first inductor 45 , the second inductor 46 and the second capacitor 51 . The first capacitor 50 and the first inductance 45 can optionally be connected via the first PIN diode 35 or the second PIN diode 36 . The second inductance 46 and the second capacitor 51 can be bridged by the third PIN diode 37 and the fourth PIN diode 38 , respectively. The control of the PIN diodes 35 , ..., 38 takes place via the control signal inputs U1, U2, U3 and U4. The DC potential

can be specified as desired. As a result, the PIN diodes 35 ,..., 38 can also be biased in the reverse direction, thereby increasing their blocking resistance and reducing their junction capacitance. The logic level required for switching the PIN diodes 35 , ..., 38 is generated by a digital circuit.

According to Fig. 4 of the matching circuit 40 is connected, the first receiving antenna 15 and to the output 10 of the matching circuit 40, the receiver stage 20 is connected to the input 5. FIG. 4 also shows a device 1 which comprises a memory 55 and the matching circuit 40 connected to the memory 55 . The receiving stage 20 is also connected to the memory 55 . Between the receiving section 20 and the memory 55, a reception frequency block 85 in FIG. 4 is arranged, is of no component but only the in the receiving section 20, for example a car radio reception frequency known as the input information for the memory 55. The user sets the reception frequency on a tuning circuit of the radio receiver mentioned as an example, which can advantageously be arranged in the vicinity of the first reception antenna 15 . The reception frequency ranges 25 ,..., 30 are stored in the memory 55 and assigned to corresponding networks or switching states of the PIN diodes 35 ,..., 38 , so that when a reception frequency and a corresponding input information of the memory 55 are selected , this reception frequency in the memory 55, the control signals required to achieve the assigned switching states of the PIN diodes 35 ,..., 38 are output to the control signal inputs U1, U2, U3, U4 of the adaptation circuit 40 .

If several antennas are to be adapted alternatively to the input impedance of the receiving stage 20 , preferably coded information about the respective antenna type is required as input data of the memory 55 in addition to the selected receiving frequency. Starting from FIG. 4, FIG. 5 shows a block diagram in which the same elements are identified with the same reference symbols. In addition, however, an antenna information unit 90 is shown, which indicates to the memory 55 the type of the first receiving antenna 15 currently connected to the matching circuit 40 . For this purpose, 30 different can be connected to the matching circuit 40 receiving antenna types are in the memory 55 in addition to the reception frequency ranges 25, ... stored, so that in the memory 55 combinations of reception frequency ranges 25, ..., 30 and antenna types corresponding switching states of the PIN diodes 35, ..., 38 are assigned. Corresponding control signals are then output from the memory 55 to the adaptation circuit 40 as a function of the selected antenna type and the selected reception frequency. The information about the antenna type can be input into the antenna information unit 90 , for example, via an input unit (not shown in FIG. 5).

Starting from FIG. 5, FIG. 6 shows the block diagram of a further exemplary embodiment, the same elements being identified with the same reference symbols. Referring to FIG. 6 in addition to the first receiving antenna 15 a second reception antenna 16 and a third receiving antenna 17 is provided, which are connected through an antenna selection circuit 100 to the input 5 of the matching circuit 40. The antenna selection circuit 100 is also connected to the memory 55 . An antenna selection unit 95 is also connected to the memory 55 . In this way, the device 1 according to the invention can also be used to operate an antenna switching diversity system, in which only the one matching circuit 40 is required for all three receiving antennas 15 , 16 , 17 which can alternatively be connected by the antenna selection circuit 100 . Such an antenna switching diversity system is used, for example, in motor vehicles. At any point in time, only one receiving antenna currently selected by the antenna selection unit 95 is connected to the receiving stage 20 , while the remaining receiving antennas are unused. Therefore, only one matching circuit 40 is required, which, however, must be suitable for matching all receiving antennas 15 , 16 , 17 . However, this has the advantage that a separate matching circuit 40 is not required for each receiving antenna 15 , 16 , 17 . The selection of the switching state of the PIN diodes 35 ,..., 38 or the control signals of the memory 55 required for this is carried out as described in the exemplary embodiment according to FIG. 5. In the exemplary embodiment according to FIG. 6, the memory 55 additionally has the function of switching the antenna selection circuit 100 as a function of the reception antenna 15 , 16 , 17 selected in the antenna selection unit 95 such that the selected reception antenna 15 , 16 , 17 is connected to the matching circuit 40 .

The data for the reception frequency ranges 25 , ..., 30 , the antenna types and the switching states of the PIN diodes 35 , ..., 38 are stored in the memory 55 in the form of an assignment table. This allocation table can be determined during the manufacturing process of the device 1 . The memory 55 is designed, for example, as an EPROM or PROM. The optimal switching states of the PIN diodes 35 , ..., 38 are stored in the allocation table of the memory 55 for each of the antennas and each reception frequency range 25 ,..., 30 that are suitable for connection to the matching circuit 40 . If the device 1 is required for a vehicle antenna system, for example, the information about which antenna or which antennas in an antenna switching diversity system are actually located on the vehicle in question is transmitted to the antenna information unit 90 during vehicle assembly via an input unit. With this information and the assignment table stored in the memory 55 , a selection of the optimal switching state of the PIN diodes 35 ,..., 38 in the adaptation circuit 40 is possible. In the event that the antenna arrangement is an antenna switching diversity system, the corresponding antenna type is stored in the antenna information unit 90 for each receiving antenna 15 , 16 , 17 that can be connected to the matching circuit 40 . Via the antenna selection unit 95 to the memory 55 is notified, which is currently connected to the three receiving antennas 15, 16, 17 to the matching circuit 40 so that the currently connected to the matching circuit 40 receiving antenna 15, 16, 17 of the associated antenna type associated with one of the antenna information unit 90 can be selected and so the optimal switching state of the PIN diodes 35 , ..., 38 for this antenna type at the selected reception frequency can be selected.

The allocation table of the memory 55 can alternatively also be determined during an initialization phase independently of the manufacturing process. This initialization is computer-controlled and can take place in four different variants, for example.

In a first variant, initialization takes place over the entire reception frequency spectrum. The receiver comprising the receiving stage 20 is tuned to any transmitter within the first receiving frequency range 25 by means of a tuning circuit. The switching states for the PIN diodes 35 ,... 38 are found in the adaptation circuit 40 by an automatic search process, in which the highest reception level is present at the input of the reception stage 20 . These switching states consequently provide the lowest mismatch losses and are stored in the allocation table of the memory 55 , which is then designed as a read-write memory. The process is repeated, in particular in the case of antenna switching diversity systems, for each of the antennas present and for each reception frequency range 25 ,... 30 . A computer control provided for this process must be able to set the reception frequencies and the switching state of the antenna switching diversity system for the reception antennas 15 , 16 , 17 to be connected to the adaptation circuit 40 for the initialization process. With this procedure, separate information about the current antenna type is not required, so that in FIG. 7, which shows the block diagram of a further exemplary embodiment based on FIG. 6, the antenna information unit 90 is no longer provided, since an optimization of the switching states of the PIN Diodes 35 , ..., 38 takes place in accordance with the reception level at the input of reception stage 20 . In FIG. 7, the computer control is identified by reference number 105 . It is connected to the antenna selection unit 95 in order to control the selection of the receiving antenna 15 , 16 , 17 to be connected to the matching circuit 40 . Furthermore, the computer controller 105 is connected to the reception stage 20 and the reception frequency block 85 for setting a reception frequency. Furthermore, the computer controller 105 is connected to the memory 55 in order to assign an optimal switching state of the PIN diodes 35 ,..., 38 in the assignment table to a reception frequency and an antenna type.

No initialization can take place in the reception frequency ranges 25 ,... 30 , within which no transmitter is received. The initialization within these reception frequency ranges 25 , ..., 30 can be made up at a later point in time, in which a transmitter is then received in the reception frequency range 25 , ..., 30 concerned. As a result, gaps within the allocation table of the memory 55 are gradually filled.

If all the table positions in the allocation table of the memory 55 are filled with sensible switching states of the PIN diodes 35 ,... 38 found during the initialization process, an acknowledgment message is sent to the computer control 105 . Those memory locations in the allocation table of the memory 55 which do not yet contain any useful switching states, since no transmitter was received in the corresponding reception frequency range 25 ,... 30 , can be filled with previously defined codes. Fig. 8 shows a flow chart for the initialization by the computer controller 105. The aim of the initialization process is, as described, to find the optimal switching state of the adaptation circuit 40 for each reception frequency or reception frequency range 25 ,... 30 and each reception antenna 15 , 16 , 17 attached to the vehicle, for example via an antenna switching diversity system to store the allocation table of the memory 55 under a corresponding address.

After calling the initialization process, an index variable for the reception frequency is initialized at program point 200 , so that it refers to the smallest adjustable reception frequency of the reception frequency spectrum. At program point 205 , the reception frequency to which the index variable for the reception frequency refers is set at reception stage 20 . At program point 210 it is checked whether there is a transmitter for this reception frequency. If this is the case, the program branches to program point 215 , otherwise the program branches to program point 285 . At program point 215 , an index variable for a switchable reception antenna 15 , 16 , 17 is initialized and refers to the first switchable reception antenna 15 . At program point 220 , the receiving antenna 15 , 16 , 17 is connected to the matching circuit 40 , to which the index variable for the receiving antenna 15 , 16 , 17 currently refers. At program point 225 , the memory location allocated for the currently set receiving frequency and the currently connected receiving antenna 15 , 16 , 17 is addressed for the optimal switching states of the PIN diodes 35 , ..., 38 . At program point 230 , an index variable for the switching states of the PIN diodes 35 , ..., 38 is initialized and refers to a first possible combination of switching states for the PIN diodes 35 , ..., 38 . A variable for the optimal switching states is then initialized with the first set switching states. At program point 235 , the addressed memory location of the memory 55 is occupied with the current switching states of the PIN diodes 35 , ..., 38 . At program point 240 it is checked whether the currently set switching states of the PIN diodes 35 , ..., 38 lead to a better reception result at the receiving stage 20 than the switching states stored under the variable for the optimal switching states. If this is the case, the program branches to program point 245 , otherwise the program branches to program point 250 . At program point 245 , the variable for the optimal switching states is set to the currently set switching states. At program point 250 , the index variable for the switching states of the PIN diodes 35 , ..., 38 is incremented and possibly refers to the next possible combination of switching states for the PIN diodes 35 , ..., 38 . At program point 255 it is checked whether all switching states of the PIN diodes 35 , ..., 38 have already been set. If this is the case, the program branches to program point 260 , otherwise the program branches back to program point 235 and the addressed memory location of memory 55 is occupied with the current switching states of PIN diodes 35 ,..., 38 . At program point 260 , the addressed memory location of the memory 55 is occupied with the optimal switching states of the PIN diodes 35 ,..., 38 determined . At program point 265 , the index variable for the receiving antennas 15 , 16 , 17 is incremented and possibly refers to the next connectable receiving antenna. At program point 270 , it is checked whether all of the receiving antennas 15 , 16 , 17 that can be connected to the matching circuit 40 have already been set. If this is the case, the program branches to program point 275 , otherwise the program branches back to program point 220 and the receiving antenna 15 , 16 , 17 is connected to the matching circuit 40 , to which the index variable for the receiving antennas 15 , 16 , 17 currently refers. At program point 275 , the index variable for the reception frequency is incremented and possibly refers to the next adjustable reception frequency of the reception frequency spectrum. At program point 280 , it is checked whether all reception frequencies of the reception frequency spectrum have already been set. If this is the case, the program is ended, otherwise the program branches back to program point 205 and a new reception frequency is set, to which the current index variable for the reception frequency refers. At program point 285 , the index variable for the receiving antennas 15 , 16 , 17 is initialized and refers to the first switchable receiving antenna 15 . At program point 290 , the receiving antenna 15 , 16 , 17 is connected to the matching circuit 40 , to which the index variable for the receiving antennas 15 , 16 , 17 just refers. The memory location in the allocation table of the memory 55 is then addressed, which belongs to the currently set reception frequency and the currently connected reception antenna 15 , 16 , 17 . This memory location is then occupied with an agreed code word which signals that initialization has not yet taken place. If a transmitter is set to the reception frequency in question at a later point in time, the initialization must be made up for this reception frequency. Alternatively, the reception frequencies, at which initialization has not yet taken place, could be stored in a special table by the computer controller 105 , so that when the corresponding reception frequency is set, it can be determined immediately by comparison with the reception frequencies stored in the special table that this reception frequency No initialization has yet taken place and this will then be made up if there is a corresponding transmitter for this reception frequency. At program point 295 , the index variable for the receiving antennas 15 , 16 , 17 is incremented and possibly refers to the next connectable receiving antenna. At program point 300 it is checked whether all receiving antennas 15 , 16 , 17 have already been connected to the matching circuit 40 . If this is the case, the program branches to program point 275 and the index variable for the reception frequency is incremented, so that it possibly refers to the next adjustable reception frequency of the reception frequency spectrum. Otherwise, the program branches back to program point 290 and a new receiving antenna 15 , 16 , 17 is connected to the matching circuit 40 , to which the index variable for the receiving antennas 15 , 16 , 17 just refers.

In a second variant, an initialization process does not take place over the entire reception frequency spectrum, but only for the frequency currently to be received. Each time a reception frequency is set, a check is carried out to determine whether an initialization has already taken place for this reception frequency. If this is not the case, an initialization is carried out only for this one reception frequency and the correspondingly determined switching states of the PIN diodes 35 , ..., 38 are shown in the assignment table of the memory 55 at the currently set reception frequency and at the currently Adaptation circuit 40 connected receiving antenna 15 , 16 , 17 assigned memory location. As a result, the allocation of the allocation table of the memory 55 is distributed over a longer period. In this way, each individual initialization process takes less time and is perceived less clearly by the user. According to the flowchart according to FIG. 8, the second variant can also be initialized for the currently set reception frequency for each reception antenna 15 , 16 , 17 that can be connected to the adaptation circuit 40 , the parts of the flowchart for changing the reception frequency not being run through.

In a third variant, an initialization process takes place only for the receiving antenna 15 , 16 , 17 currently connected to the matching circuit 40 . This is useful, for example, when exchanging the receiving antenna 15 , 16 , 17 . In this case, 8 of the part of the flow chart as shown in FIG. Traversed, in which the optimum switching states of the PIN diodes 35, 38 are determined and stored at the appropriate location in memory 55 .... This part is run through for all adjustable reception frequencies.

In a fourth variant, an initialization process takes place only for the frequency currently to be received and the receiving antenna 15 , 16 , 17 currently connected to the matching circuit 40 , so that in this fourth variant according to FIG. 8 only that part of the flowchart is run through in which the optimal switching states for the PIN diodes 35 , ..., 38 are determined and stored in a corresponding location in the memory 55 .

It is also possible to repeat the initialization process at certain intervals. This ensures that an optimal adaptation takes place even if the antenna impedance is changed, for example by modifications to the vehicle. An example of an assignment table is shown in FIG. 9. Here n reception frequency ranges 25 ,..., 30 are provided, which are identified by FB _i , where i represents the number of the reception frequency range 25 ,..., 30 . The reception frequency ranges 25 , ..., 30 are arranged row by row in a first column of the assignment table. In a second column of the assignment table, the receive frequency ranges 25 , ..., 30 are the switching states optimal for SZ _j for the PIN diodes 35 , ..., 38 for the first receive antenna 15 , which in the assignment table according to FIG. Antenna 1 "is marked. With four PIN diodes 35 , ..., 38 , sixteen combinations of switching states are possible, so that j can assume a number between 1 and 16, inclusive. The switching states assigned to the reception frequency ranges 25 ,..., 30 for the second and third reception antennas 16 and 17 are then stored in the third and fourth columns. The memory locations assigned to the individual receive frequency ranges 25 ,..., 30 and receive antennas 15 , 16 , 17 of the assignment table according to FIG. 9 can be addressed, for example, by means of a 12-bit address, with an 8-bit word then being in each location, for example, of the individual bits, the control voltage inputs U1, U2, U3, U4 of the adaptation circuit 40 can be controlled. In an antenna system in which the allocation table is established during the manufacturing process, the switching states of the PIN diodes 35 ,..., 38 are not optimized in accordance with the optimal reception at the reception stage 20 . The storage locations of the allocation table are thus occupied during the manufacturing process, the allocation table being able to have storage locations for a large number of usable antenna types. In this way, the assignment table can be created independently of the type of antenna used in the individual case or of the type of antenna used in an antenna switching diversity system, so that effort is saved. If, for example, a certain antenna type is mounted on the vehicle during vehicle manufacture or certain antenna types are mounted on the vehicle in an antenna switching diversity system, the corresponding information about the antenna types used is passed on to the allocation table of the memory 55 via the antenna information unit 90 according to FIG. 5 or FIG. 6 , so that only the switching states stored in the assignment table for these antenna types can be set on the matching circuit 40 . For addressing the corresponding memory locations of the allocation table of the memory 55 can be set to the required for addressing the corresponding memory locations values 55 then in vehicle manufacture corresponding address lines between the antenna information unit 90 and the memory. The described computer-controlled initialization processes for automatic allocation of the assignment table are particularly advantageous in the case of radio receivers which are arranged close to the antenna and which already have a computer control 105 . Since the reception properties can also change as a result of changes to the vehicle, the optimal switching state can be found and stored again in the adaptation circuit 40 by repeating the initialization process. A new initialization process can also be started if one or individual antennas are subsequently exchanged for more powerful antenna types, for example. The reception properties of the new antenna or antennas are then optimally used by the renewed initialization process.

Claims (11)

1. Device ( 1 ) for transforming an antenna impedance with an input ( 5 ) for connecting a receiving antenna ( 15 , 16 , 17 ) and an output ( 10 ) for connecting an input stage ( 20 ), a network being provided for different antenna impedances is over which an adaptation of the antenna impedances to the input impedance of the receiving stage ( 20 ) takes place, the device ( 1 ) at least one preferably digital control signal depending on the ge straight at the input ( 5 ) for connecting the receiving antenna ( 15 , 16 , 17th ) available antenna impedance and where, due to the at least one control signal, the network associated with this antenna impedance can be switched between the input ( 5 ) for connecting the receiving antenna ( 15 , 16 , 17 ) and the output for connecting the receiving stage ( 20 ), characterized that the networks describe input power circuits in a Smith chart, the radius of which is as small as possible is and that a predetermined range of the Smith chart is covered by the input power circuits. 2. Device ( 1 ) according to claim 1, characterized in that the device ( 1 ) the at least one control signal depending on at least one predeterminable, in particular narrow-band reception frequency range ( 25 , ..., 30 ) can be supplied. 3. Device ( 1 ) according to claim 1 or 2, characterized in that the device ( 1 ) the at least one control signal depending on at least one predeterminable and connectable to the device antenna type can be supplied. 4. The device ( 1 ) according to claim 1, 2 or 3, characterized in that the network by means of at least one diode ( 35 , ..., 38 ), preferably a PIN diode, between the input ( 5 ) for connecting the receiving antenna ( 15 , 16 , 17 ) and the output ( 10 ) for connecting the receiving stage ( 20 ) can be switched and that the at least one control signal controls the at least one diode ( 35 , ..., 38 ). 5. Device ( 1 ) according to one of the preceding claims, characterized in that an adaptation circuit ( 40 ) is provided which comprises the individual networks and between the input ( 5 ) for connecting the receiving antenna ( 15 , 16 , 17 ) and the output ( 10 ) is connected to the connection of the receiving stage ( 20 ). 6. The device ( 1 ) according to claim 5, characterized in that the matching circuit ( 40 ) comprises at least a first impedance ( 46 , 51 ), which can preferably be bridged by the at least one diode ( 37 , 38 ). 7. The device ( 1 ) according to claim 5 or 6, characterized in that the matching circuit ( 40 ) comprises at least a second impedance ( 45 , 50 ), which can preferably be switched on by the at least one diode ( 35 , 36 ). 8. Device ( 1 ) according to one of the preceding claims, characterized in that a memory ( 55 ), preferably a read-write memory or an EPROM or PROM is provided in which the at least one predefinable reception frequency range ( 25 , ... , 30 ) and / or antenna type and that the memory ( 55 ) generates the at least one control signal depending on the selection of the at least one reception frequency range ( 25 , ..., 30 ) and / or antenna type stored in the memory ( 55 ). 9. The device ( 1 ) according to claim 8, characterized in that the at least one in the memory ( 55 ) stored frequency range ( 25 , ..., 30 ) and / or antenna type is assigned to the network, in which at the output ( 10 ) Adaptation circuit ( 40 ) of the highest reception level, and that due to the control signal generated by the memory ( 55 ) when selecting this reception frequency range ( 25 , ..., 30 ) and / or antenna type, a circuit of this network between the input ( 5 ) for connecting the Receiving antenna ( 15 , 16 , 17 ) and the output ( 10 ) for connecting the receiving stage ( 20 ). 10. The device ( 1 ) according to claim 9, characterized in that the assignment of the at least one in the memory ( 55 ) stored frequency range ( 25 , ..., 30 ) and / or antenna type to a network is carried out by means of an initialization process. 11. The device ( 1 ) according to claim 9 or 10, characterized in that the assignment of the at least one in the memory ( 55 ) stored reception frequency range ( 25 , ..., 30 ) and / or antenna type to a network when selecting the at least one reception frequency range ( 25 , ..., 30 ).