DE10059179C1 - Circuit device for automobile access control system antenna has current supply paths for different antenna elements supplied with in-phase or phase offset antenna signals - Google Patents

Abstract

The circuit device has switches (K2) for each pair of antenna elements (1,2) connecting the latter to respective supply paths (A,B), with further switches (K0,K1) allowing both supply paths to receive in-phase antenna signals in one switch position and antenna signals with a phase offset in the second switch position. An independent claim for a switching method for an antenna of an automobile access control system is also included.

Description

The present invention relates to a circuit arrangement for connecting and switching an antenna arrangement, in particular an antenna arrangement of an access control systems of a vehicle, and a method for switching such an antenna arrangement.

There are access control systems for vehicles with so-called called "Passive Access" work. Such an access con trollsystem works with an access authorization system, where the access authorization is contactless via a so-called named ID transmitter is checked. Such is an ID transmitter z. B. a contactless IC card, the contactless via an tennenanordnung the vehicle is queried. To do this are on various locations in the vehicle antennas arranged receive a predetermined antenna signal. The antennas radiate in accordance with the predetermined antenna signal electromagnetic field and receive an electromagnetic field that is used by the ID provider for the purpose of data transfer has been changed. The technique of such a Zu gait authorization system is well known and will not be here described in more detail.

It becomes an antenna arrangement of such a conventional one Access control system described as when logging on rin was developed. The access control system has several Antenna pairs at different locations in the vehicle. The access control system requires the provision of antennas in pairs for various reasons. For example it is for reasons of recognition security and sensitivity increase in speed desirable that one of the two antennas alternatively can be operated with an antenna signal opposite  the antenna signal of the other antenna by 180 ° in the Phase is shifted.

A conventional circuit arrangement enables the the antennas with voltages of the same phase and different phase. Such an access control system should regularly, e.g. B. when activating the system, in right regular time intervals when servicing the vehicle, etc., undergo a diagnosis. From DE 197 18 764 C1 is an anti-theft system for a motor vehicle with an access control system known in which a Diagnostic device is used. From DE 198 23 237 A1 is a radio system for telecontrol functions in stationary vehicles as an access control system for a vehicle switchable antennas known.

The object of the invention is therefore a circuit arrangement for connecting and switching an antenna arrangement, in particular an access control system, with a power supply supply source and a method for switching such To improve the circuit arrangement so that diagnosis is possible speed of the antenna arrangement with the least possible effort will be realized.

This object is achieved by a circuit arrangement according to Claim 1 or a method according to claim 10. Further training gene of the invention are specified in the subclaims.

Further advantages and features result from the description Exercise of embodiments with reference to the figures. Of the Figures show:

Fig. 1 shows a first embodiment of the circuit arrangement, and

Fig. 2-5 a second embodiment of the circuit arrangement in four different switching states.

A circuit arrangement for connecting and switching an antenna arrangement of an access control system with so-called "passive access", in particular an access control system of a vehicle, and a voltage source according to a first embodiment of the invention and the voltage source are shown in FIG. 1. The voltage source provides an antenna signal that is an AC signal, and it can therefore also be referred to as an antenna signal source. The access control system has several pairs of antennas at different locations in the vehicle. In Fig. 1, the connections 1 a, 1 b, 2 a, 2 b are shown for the leads in the wiring harness for a pair of antennas, which has a first antenna 1 and a second antenna 2 . The access control system requires the provision of antennas in pairs for the reasons given in the description instructions.

In the circuit arrangement are a first supply path A, which delivers the antenna signal with a fixed phase position, and a second supply path B which carries the antenna signal a variable, i.e. H. reversible phase position provides, pre see. The first supply path A has a first line Aa and a second line Ab up and the second supply path B has a third line Ba and a fourth line Bb on.

Furthermore, the access control system requires that the individual antenna pairs can be switched on and off. For this purpose, a double switch is provided, which switches the two antennas of a pair of antennas on or off. In the embodiment shown in Fig. 1, the double switch is designed as a commercially available double relay. The double relay KB has a first connection COM1, which is connected via a first switch to a second connection NC1 or a third connection NO1. The double relay also has a fourth connection COM2, which is connected via a second switch to a fifth connection NC2 or a sixth connection NO2. The double switch or the double relay is designed such that the first and the second switch are always switched simultaneously in such a way that the first connection is connected to the second connection and the fourth connection to the fifth connection (first switching state) or the first connection are connected to the third connector and the fourth connector to the sixth connector (second switching status).

In the embodiment shown in FIG. 1, the first antenna 1 , the second antenna 2 , the first supply path A, the second supply path B and the double relay are connected in such a way that the first and second antennas 1 , 2 each have the double relay in the first switching state are short-circuited, and that in the second switching state of the double relay, the first antenna 1 is connected to the second supply path B and the second antenna 2 is connected to the first supply path A. These connections are achieved in that a connection 1 b of the first antenna is connected to the first connection COM1 of the double relay, the other connection 1 a of the first antenna 1 to the one (third) line Ba of the second supply path B and the second Connection NC1 of the double relay is connected, the other (fourth) line Bb of the second supply path B is connected to the third connection NO1 of the double relay, which is a connection 2 a of the second antenna 2 to the fourth connection COM2 of the double relay, the other Connection 2 b of the second antenna 2 is connected to the (second) line Ab of the first supply path A and to the fifth connection NC2 of the double relay, and the other (first) line Aa of the first supply path A to the sixth connection NO2 of the Dop pel relay is connected.

Shorting the two antennas is one way turn off the antennas. Another option is that an antenna is idle. It is obvious,  that even switching to idle with the Double relay is possible.

It is further evident that further antenna pairs with associated double switches can be connected to the two supply paths A, B in the same way as is shown for antennas 1 , 2 and the double relay KB in FIG. 1.

With the circuit arrangement shown in FIG. 1, the antenna arrangement is connected to the voltage source (antenna signal source) 3 , which supplies a predetermined antenna signal U _ind to two poles 31 , 32 .

In the circuit arrangement shown in FIG. 1, a line connects the first line Aa of the first supply path A directly to the first pole 31 of the voltage source 3 and a further line connects the second line Ab of the first supply path A directly to the other pole 32 of the span source 3 . Thus, in the second switching state of the double relay KB, the second antenna 2 is connected to the first supply path A with the fixed phase position, which is predetermined by the phase position of the antenna signal U _ind .

The circuit arrangement of FIG. 1 also has a double switch KA of the same type as the double relay KB. The double relay KA is connected to the lines Aa, Ab, Ba, Bb in such a way that in one switching state the double relay KA applies the antenna signal U _ind with the same phase to the second antenna 2 as to the first antenna 1 , while in the other Switching state this voltage to the second antenna 2 with a phase that is shifted from the polarity on the first antenna 1 by 180 °, is applied. This is achieved in that the first connection COM1 is connected to the fourth line Bb and the fourth connection COM2 is connected to the third line Ba of the second supply path B. The connecting line of the first line Aa to the pole 31 of the voltage source 3 is connected to the second connection NC1 and the sixth connection NO2 and the connecting line of the second line from the first supply path A to the pole 32 of the voltage source 3 is connected to the third connection NO1 and the fifth connection NC2 of the double relay KA connected.

The circuit arrangement shown in FIG. 1 enables the two antennas 1 and 2 to be supplied with voltages of the same phase and with voltages of different phase, depending on the switching state of the double relay KA.

The access control system with the circuit arrangement of FIG. 1 can therefore regularly, for. B. when activating the system, at regular time intervals, during maintenance of the vehicle, etc., undergo a diagnosis.

Such a diagnosis serves to keep the antennas functioning ability to examine. If an antenna has a short circuit or has a cable break (disconnection), then the Functionality of the system impaired or destroyed. A short circuit may show up. a. in that in comparison normally between the two antenna connections very large current flows and the potential difference decreases sharply takes, while a cable break compared to the normal case The effect is that there is no o between the two antenna connections that almost no electricity flows.

The diagnosis is made so that e.g. B. the current or a correlated size is measured and from the measured value to the Normal condition or malfunction (short conclusion, cable break) is closed. This can be done through a corresponding measuring device with a corresponding Control device is connected to be realized. If If there is a malfunction, the corresponding antennas can couple (by switching the corresponding double relay) of the Control device can be switched off.  

In the circuit arrangement shown in FIG. 1, it is possible to jointly examine the antennas of a pair of antennas for short circuits or cable breaks. It is particularly advantageous that n pairs of antennas can be controlled with (n + 1) double switches and (n + 1) control lines.

In FIGS. 2-5, the connections between the circuits are on the antennas, the leads of the supply paths of the voltage source and the double switches partially gestri smiles or shown in phantom. This dashed or dash-dotted representation is only for the purpose of illustrating the active compounds. The corre sponding lines are in the mer as in the illustration of Fig. 1. With the circuit arrangement from FIG. 1, diagnosis of the antennas is only possible in pairs. However, it would also be desirable to examine the antennas of a pair of antennas individually.

In Fig. 2, the circuit arrangement according to a second embodiment of the invention is shown. The circuit arrangement serves to connect and switch an antenna arrangement of an access control system, in particular an access control system of a vehicle such as a motor vehicle, and a voltage supply source. The antenna arrangement in FIGS. 2-5 is identical to the antenna arrangement from FIG. 1, the double switch KB being designated as a double switch K2. The description of the antenna arrangement is therefore not repeated.

The voltage source 3 with the poles 31 and 32 corresponds to the voltage source 3 from FIG. 1. Its description is therefore not repeated.

As can be seen in FIG. 2, the first line Aa of the first supply path A is connected directly to one of the two poles 31 , 32 of the voltage source 3 , in the present case to the second pole 32 , by a connecting line.

There are a first double switch in the circuit arrangement K0 and a second double switch K1 are provided, each as a double relay of the same type as the double switch K2 are trained. The description of the corresponding double relay type is not repeated.

The two double relays K0 and K1 each have two switches ter on, regardless of the two switches of each other double relays can be switched. So are by a clever connection of the individual connections of the Double relays K0 and K1 four switching states available. with By means of these four switching states, the three remaining Lines Ab, Ba and Bb of the first supply path A and of the second supply path B so with the supply chip voltage that supply path A either the antenna signal (AC voltage) without phase shift or the same voltage potential is present on both lines and that on the second supply path B the antenna signal with or without phase shift or on both lines same voltage potential is present. If the connections now still be switched so that in the case where the Ver care path A the same voltage po on both lines potential is present, on the second supply path B the supplier voltage with or without phase shift, then both antennas can independently short circuit or cable break are examined and the two antennas with Antenna signals of the same phase or different Phase position are operated.

This connection of the four switching states with the four desirable connections of antennas 1 and 2 is achieved in that each of the lines Ab, Ba and Bb is connected to a different first or fourth connection of one of the double switches K0 or K1. The two lines Ba and Bb of the second supply path B are connected to a first or fourth connection of different double switches. The last remaining first. o The fourth connection of the two double switches K0 or K1 is connected to the second, third, fifth or sixth connection of the other double switch. The remaining second, third, fifth and sixth connections of the two double switches K0, K1 are now connected to the two poles 31 , 32 of the voltage source 3 and the four lines Aa, Ab, Ba, Bb of the two supply paths A, B accordingly, that the four possible switching states of the two double switches K0, K1 result in the four connection states of the antennas described above.

A corresponding possibility of connecting the lines is shown in Fig. 2-5. The second connection NC1 of the first double switch K0 is connected to the first line Aa, the third connection NO1 of the first double switch K0 is connected to the first pole 31 , the fifth connection NC2 of the first double switch K0 is connected to the first pole 31 and the sixth connection NO2 of the first double switch K0 is connected to the second pole 32 . The second connection NC1 of the second double switch K1 is connected to the fourth connection COM2 of the first double switch K0, the third connection NO1 of the second double switch K1 is connected to the first pole 31 . The fifth connection NC2 of the second double switch K1 is connected to the first pole 31 and the sixth connection NO2 of the second double switch K1 is connected to the third line Ba. This United connections of the connections of the double switch K0, K1 with the lines of the supply paths A, B and the poles of the voltage source 3 is exemplary. However, other connections are also conceivable. It is important that by connecting the three lines of the supply paths A, B, which are not directly connected to one of the poles of the voltage source 3 , with the first and fourth inputs of the double switch, the two lines of the pair of antennas, which is the reversal of the Should have phase, are connected to first and fourth inputs of different double switches, the assignment of the four desired connections to the four circuit combinations is possible.

In the following, the attainment of the desired compound four states and their assignment is cussed to the four switching state combinations dis with reference to FIGS. 2-5. In FIGS. 2-5 of the double switch K2 (K2 = 1) is respectively activated, that is turned on so that the two at antennas 1, 2 to the two supply paths A, B are connected, as shown in the illustration in Fig. 2 -5 is obvious.

In FIG. 2, the double switch K0, K1 are both turned off (K0 = 0, K1 = 0), that is disabled. Therefore, the first are connected to the second and the fourth to the fifth terminals as shown. Therefore, the connections 1 a and 2 a of the antennas 1 , 2 are each connected to the pole 32 of the voltage source 3 , while the connections 1 b and 2 b of the antennas 1 , 2 are each connected to the pole 31 of the voltage source 3 . The two antennas each receive the antenna signal with the same phase position.

In Fig. 3 the case is shown in which the first double switch K0 is deactivated, while the second double switch ter K1 is activated (K0 = 0, K1 = 1). Accordingly, in the first double switch K0, the first and the second connection and the fourth and the fifth connection are connected, while in the second double switch K1 the first and the third connection and the fourth and the sixth connection are connected. Therefore, the first antenna 1 is supplied with the antenna signal with the same phase position as in FIG. 2, while the antenna 2 is connected to the pole 32 at both connections and is therefore deactivated.

In FIG. 4, the case is shown in which the first double switch K0 is activated and the second double switch tivated Deak K1 is (K0 = 1, K1 = 0). Therefore, the connections 1 a and 2 b of the antennas 1 , 2 are connected to the pole 31 of the voltage source 3 , while the connections 1 b, 2 a of the antennas 1 , 2 are connected to the pole 32 of the voltage source 3 . It follows that antennas 1 , 2 are supplied with the same antenna signal, but with different phase positions.

In Fig. 5 shows the case in which the double-scarf ter K0, K1 are both activated (K0 = 1, K1 = 1). As is evident from the illustration in Fig. 5, both connections 1 a, 1 b of the antenna 1 are connected to the pole 31 of the voltage source 3 and the antenna 1 is therefore deactivated, while the antenna 2 senlage the antenna signal with the same Pha as received in Figs. 2 and 4.

In summary, it can be stated that the two antennas 1 , 2 can be supplied with the antenna signal with the same phase position ( FIG. 2) or with a different (essentially reverse) phase position ( FIG. 4), and that the first antenna 1 ( FIG. 3) or the second antenna 2 ( FIG. 5) can be supplied with the antenna signal, while the other antenna (antenna 2 in FIG. 3; antenna 1 in FIG. 5) is switched off.

The same applies to any other pair of antennas, the analog is connected to the supply paths A, B. The antennas Pairs can be switched on individually by switching the double switch K2 to be controlled.

Therefore, it is with the circuit arrangement of the second embodiment form described above compared to the first Embodiment possible by providing a single one additional double switch and the corresponding modification the connection of the voltage source, the operating options of the two antennas with antenna signals of the same or different  Maintain phase position and still both on test separately for cable break or short circuit.

In both embodiments, it is very advantageous that i Dental double relays can be used for all switches can and the circuit design for any number of Antenna pairs except for the addition of further switches KB or K2 is the same.

Claims (13)

1. Circuit arrangement for connecting and switching
an antenna arrangement, in particular for an access control system of a vehicle, the antenna arrangement having at least one pair of antennas with a first and a second antenna ( 1 , 2 ) each having two connections ( 1 a, 1 b; 2 a, 2 b), and
a voltage source ( 3 ) which supplies an antenna signal (U _ind ) with a specific phase position at two poles ( 31 , 32 )
a first supply path (A),
a second supply path (B), a first switch (KB; K2) per pair of antennas ( 1 , 2 ), which switches the antennas off in a first switching state and in a second switching state the first antenna ( 1 ) with the second supply path (B ) and the second antenna ( 2 ) connects to the first supply path (A), and
a second switch (KA; K0, K1) which is arranged such that in a first switching state the first and second supply paths are supplied with the antenna signal with the same phase position and a second switching state of the second switch is supplied with the antenna signal with different phase positions. 2. Circuit arrangement according to claim 1, in which
the first supply path (A) has first and second lines (Aa, Ab) and the second supply path (B) have third and fourth lines (Ba, Bb),
the second switch (KA) is a double switch (KA) with six connections and two switching states, which is designed such that in a first switching state a first is connected to a second and a fourth to a fifth input and in a second switching state the first is connected to a third and the fourth to a sixth connection,
wherein a first of the two poles ( 31 , 32 ) of the voltage source ( 3 ) is connected directly to the first line (Aa) and the other of the two poles of the voltage source is connected directly to the second line (Ab),
the fourth line (Bb) being connected to the first connection (COM1) and the third line being connected to the fourth connection of the double switch (KA),
the remaining connections of the double switch (KA) are connected to the two poles ( 31 , 32 ) of the voltage source ( 3 ) in such a way that the first antenna ( 1 ) and the second antenna ( 2 ) were in phase with the antenna signal at the same time or different phase positions depending on the switching states of the double switch, and the first switch (KB) is identical in construction to the double switch (KA). 3. Circuit arrangement according to claim 2, wherein the second Connection (NC1) with the first line (Aa), the third line End (NO1) with the second line (Ab), the fifth line end (NC2) with the second line (Ab) and the sixth Connection (NO2) of the double switch (KA) with the first Lei device (Aa) are connected. 4. Circuit arrangement according to claim 1, wherein the second Switch has four switching states, wherein the second switch is arranged so that in one third switching state the second supply path with the on Tennensignal is supplied and the first supply path is switched, and in a fourth switching state the second Supply path is switched off and the first supply path is supplied with the antenna signal. 5. Circuit arrangement according to claim 4, in which to connect and switch
the first supply path (A) has a first and a second line (Aa, Ab) and the second supply path (B) has a third and a fourth line (Ba, Bb),
the second switch
a first double switch (K0) with six connections and two switching states, which is designed such that in a first switching state a first is connected to a second and a fourth to a fifth input and in a second switching state the first to a third and the fourth is connected to a sixth connector, and
a second double switch (K1) of the same type as the first double switch, which can be switched independently of the first double switch ter in the first or second switching state, and
a fifth line, which connects a first of the two poles ( 31 , 32 ) of the voltage source ( 3 ) directly to the first line (Aa), is provided,
wherein the second, third and fourth lines are each connected to another of the first and fourth connections of the first and second double switches (K0, K1) and the third and fourth lines are connected to different double switches,
wherein the remaining connections of the first and second double switches (K0, K1) are connected to the two poles ( 31 , 32 ) of the voltage source ( 3 ) and the first to fourth lines such that the first antenna ( 1 ) and the second An antenna ( 2 ) is supplied simultaneously with the antenna voltage with the same or different polarity or individually with the antenna voltage, while the other antenna is deactivated, depending on the switching states of the first and second double switches,
wherein the first switch (K2) is identical in construction to the first and second double switches (K0, K1). 6. Circuit arrangement according to claim 5, in which the remaining first or fourth connection (COM1, COM2) of the first and second double switches (K0, K1) that are not connected one of the first to fourth lines is connected to the second, third, fifth or sixth connection (NC1, NO1,  NC2, NO2) of the corresponding other double switch (K1, K0) connected is. 7. Circuit arrangement according to claim 5 or 6, wherein the first and second double switches each a double relay are, which has six connections, three each conclude by a switch who switched at the same time that one of the three connections between the other two connections of the three connections is switched. 8. Circuit arrangement according to one of claims 1-7, at one measuring device for measuring the current and / or the Voltage flowing between the two poles is provided. 9. The device according to claim 8, wherein a control device device is provided depending on a measurement signal the measuring device determines whether the antennas are functional are. 10. A method for switching an antenna arrangement, in particular for an access control system of a vehicle, the antenna arrangement comprising at least one pair of antennas with a first and a second antenna ( 1 , 2 ), each with two connections ( 1 a, 1 b; 2 a, 2 b), and a voltage source ( 3 ), which delivers an antenna signal (U _ind ) with a specific phase position at two poles ( 31 , 32 ), with the steps:
Switching a first switch per pair of antennas such that the antennas are switched off in a first switching state of the switch and in a second switching state of the switch the first antenna is connected to a second supply path and the second antenna is connected to a first supply path, and
Switching a second switch in such a way that, in a first switching state of the second switch, the first and second supply paths are supplied with the antenna signal with the same phase position and in a second switching state of the second switch, the first and the second supply path with the antenna signal with different phase positions become. 11. The method according to claim 10, wherein the switching of the second switch switching to a third switch stood in which the second supply path with the antenna sig nal is supplied and the first supply path is switched off and switching to a fourth switching state in which the first supply path is supplied with the antenna voltage and the second supply path is switched off has. 12. The method according to claim 10 or 11, the additional the step of measuring the current and / or the voltage, that flows between the two poles. 13. The method of claim 12, the additional the step of determining whether the antennas are functional are dependent on a measurement result of the measurement step having.