DE102013102701A1 - Door handle assembly for a motor vehicle with capacitive proximity sensor and NFC transmitter / receiver unit - Google Patents

Abstract

An outside door handle for a motor vehicle has at least one capacitive proximity sensor with at least one sensor electrode (20) and a drive and evaluation circuit (60) and a control circuit (50). The outside door handle comprises at least one NFC module (40) which can be coupled to an NFC antenna coil (20). A sensor electrode (20) is designed as an NFC antenna coil. The connections (21, 22) of the NFC antenna coil (20) can be coupled to the NFC module (40) via a coupling circuit (30). The coupling circuit (30), the drive and evaluation circuit (60) and the NFC module (40) are coupled to the control circuit (50; 55). The control circuit (50) controls the coupling circuit (30) such that the terminals (21, 22) of the NFC antenna coil (20) depending on an operating state of the control circuit (50) selectively connected to the NFC module (40) or from the NFC module (40) can be separated such that the NFC antenna coil (20) acts as a sensor electrode (60) of the capacitive proximity sensor.

Description

The invention relates to an outside door handle for a motor vehicle, wherein the outside door handle has at least one capacitive proximity sensor with at least one sensor electrode and a drive and evaluation circuit and a control circuit.

Outside door handles with integrated capacitive sensors are well known. In the published patent application DE 196 17 038 A1 For example, Applicants use capacitive sensors to detect proximity of a potential operator. A capacitive proximity sensor comprises a sensor electrode and a control and evaluation circuit. The drive and evaluation circuit measures the capacitance of the electrode with respect to ground. By approaching a hand of the operator, the capacitance of the electrode is changed, and the capacitance change is detected by the drive and evaluation circuit. Once the sensor has detected an approximation, z. B. a 125 kHz wake-up signal. If a corresponding ID transmitter is within the reception range, it reacts by transmitting an RF radio signal which comprises a unique identifier (ID). An RF receiver unit in the vehicle receives this signal and checks the access authorization based on the identifier. If the access authorization exists, an operation of the vehicle is released via the outside door handle.

Basically, the desire is also known that users of motor vehicles in everyday life as little as possible to be charged by entrained devices and keys for motor vehicles. There is therefore the desire to legitimize individual functions of the motor vehicle by using devices that are already carried by the user anyway. These may be, for example, mobile phones.

Increasingly more devices of daily life, in particular mobile phones, include functions for a so-called Near Field Communication (NFC = Near Field Communication).

The object of the invention is to accommodate components for NFC communication to save space in an outside door handle to use this example, for communication in the context of the recognition of an access authorization.

This object is achieved by an outside door handle with the features of claim 1.

The outside door handle according to the invention for a motor vehicle has at least one capacitive proximity sensor and a control circuit. The proximity sensor comprises at least one sensor electrode and a control and evaluation circuit which serves, for example, both the control of the sensor electrode with certain voltage curves and the evaluation in the sense of measuring capacitance changes. Preferably, the capacitive proximity sensor has a sensor electrode in the form of a metal plate or layer, which is connected via a (preferably short) supply line to the drive and evaluation circuit. The outside door handle comprises at least one NFC module that can be coupled to an NFC antenna coil. For example, the NFC device is an integrated circuit having the transmit, encode, receive and decode circuits required for bidirectional near field communication. One of the at least one sensor electrode is designed as an NFC antenna coil, and the terminals of the NFC antenna coil can be coupled to the NFC module via a coupling circuit. The coupling circuit comprises, for example, a plurality of electronic switching components, optionally with associated control and evaluation circuits. The coupling circuit, the drive and evaluation circuit and the NFC module are coupled to the control circuit, which controls the coupling circuit such that the terminals of the NFC antenna coil depending on an operating state of the control circuit selectively connected to the NFC device or from the NFC Block can be separated so that the NFC antenna coil acts as a sensor electrode of the capacitive proximity sensor. An operating state of the control circuit here is, for example, a state of the capacitance measurement or of an imminent NFC communication (eg transmission request or readiness for reception).

A space-saving housing of NFC components in the outside door handle additional comfort functions can be realized. In addition, the use of a designed as NFC antenna coil sensor electrode reduces the number of components used for the outside door handle and thus the cost. The control of the control circuit controlled separation of the NFC module from the designed as NFC antenna coil sensor electrode capacitance measurement by the NFC module is not or only minimally affected.

The functions of the outside door handle are controlled by the control circuit. The control circuit has information on how to use each of the sensor electrode designed as an NFC antenna coil. The information is formed as the operating state of the control circuit. Depending on the information, the control circuit controls the coupling circuit, the drive and evaluation circuit and the NFC module. Between the functions of measuring the capacity and the NFC communication may be switched at fixed time intervals, for example, or a function may have priority.

In one embodiment of the invention, one of the terminals of the sensor electrode designed as an NFC antenna coil is permanently connected to the drive and evaluation circuit of the capacitive proximity sensor. In this case, the drive and evaluation circuit can be designed so that their influence on the NFC antenna coil designed as a sensor electrode when used as an NFC antenna coil is low. The permanent connection reduces the number of required components and parasitic effects.

In another embodiment of the invention, the coupling circuit has a switching device for coupling one of the terminals of the NFC antenna coil to the drive and evaluation circuit. This is advantageous if the input circuits of the drive and evaluation circuit coupled to the sensor electrode would disturb the function of the NFC antenna coil.

In other embodiments, it may be advantageous to couple more than one terminal of the NFC antenna coil via the switching device with the drive and evaluation circuit.

In a preferred embodiment, the switching device is contained in a component which also contains the drive and evaluation circuit. For example, the switching device may be part of a connection circuit of an integrated circuit. This circuit also includes the drive and evaluation circuit which connects the connected to the sensor electrode terminal either with internal circuit parts of the drive and evaluation circuit or switches this high impedance.

In a further advantageous development of the invention, the drive and evaluation circuit, the switching device of the coupling circuit and the control circuit are contained in a microcontroller. One terminal of the sensor electrode designed as an NFC antenna coil is connected to a port of the microcontroller, and the terminal is disconnected from the drive and evaluation circuit by the port is switched to high impedance. In a further development of this embodiment, the entire coupling circuit is contained in the microcontroller.

A microcontroller may also contain other circuit parts or components for NFC communication. As a result, the entire coupling circuit or even a part of the NFC module can be integrated into the microcontroller. The number of components and the influence of parasitic effects can be reduced.

In a preferred embodiment of the invention, the control circuit on a arranged in an interior of the outside door handle microcontroller. A microcontroller is a programmable device. By adapting the programming, new functions can be realized or, for example, the behavior of the outside door handle can be adapted to changing conditions.

In one embodiment, at least one further capacitive proximity sensor, which in each case comprises at least one drive and evaluation circuit and one sensor electrode, is coupled to the control circuit. Other capacitive proximity sensors can be used for comfort functions or for the separate detection of a frontal approach of an operator's hand on the one hand and a gripping behind the outside door handle on the other hand.

In a development of this embodiment, the sensor electrode designed as an NFC antenna coil and at least one of the sensor electrodes of the at least one further capacitive proximity sensor are coupled to a common control and evaluation circuit. Due to this multiple use for different sensor electrodes, the number of required components can be reduced.

In a preferred embodiment of the invention, the coupling circuit has analog switches. The advantages of analog switches are that they are realized on the one hand without mechanical switching components and on the other hand have a comparatively small capacity with relatively low internal resistance.

In a preferred embodiment, the control circuit, the drive and evaluation circuit, the NFC module and the coupling circuit are mounted on a common circuit board. The circuit board can be rigid or flexible. In particular, coupling capacitances and RF signal routings are strongly dependent on the exact placement of the components relative to one another. When placing and mounting the NFC module, the coupling circuit, the control and evaluation circuit and the control circuit on a common circuit board components are fixed to each other spatially. Also, this type of assembly reduces costs.

In a further embodiment of the invention, the configured as NFC antenna coil sensor electrode is formed by a Leiterzug on the board. This design as a conductor has the advantage that no discrete component is needed.

In a preferred development of the invention, at least the coupling circuit and the drive and evaluation circuit are arranged on the printed circuit board which is designed as an NFC antenna coil. As a result, the parasitic capacitances and inductances of the supply lines can be reduced and adjusted more precisely.

In an advantageous embodiment, all in the state of disconnecting the NFC module from the formed as NFC antenna coil sensor electrode to the terminals of the formed as an NFC antenna coil sensor electrode still coupled components of the coupling circuit are arranged immediately adjacent to the designed as NFC antenna coil sensor electrode. When the sensor electrode designed as an NFC antenna coil is separated from the NFC module, it is used as the sensor electrode of the capacitive proximity sensor. The interconnects between the terminals of the sensor electrode designed as an NFC antenna coil to the coupling circuit then form a spatial extent of the sensor electrode. By the components of the coupling circuit, which are still connected when disconnected from the NFC module with the sensor electrode as close as possible to the sensor electrode, results in a small extent.

Advantageous and / or preferred embodiments and further developments of the invention are characterized in the subclaims. In the following the invention will be described in more detail with reference to preferred embodiments illustrated in the drawings. In the drawings shows:

1 a schematic view of a printed circuit board of a door outer handle according to the invention,

2 a block diagram of circuit components of an outside door handle according to the invention, and

3 a block diagram of circuit components of an alternative embodiment of an outside door handle according to the invention.

1 shows a schematic representation of a circuit board 10 , which is housed in an interior of an embodiment of an outside door handle according to the invention, wherein the printed circuit board shown in such a longitudinal direction in the outside door handle is arranged that formed as an NFC antenna coil sensor electrode 20 in a metallization layer of the printed circuit board 10 is arranged adjacent to a lock cylinder. This sensor electrode 20 should preferably serve as a sensor electrode of a capacitive sensor for detecting an approach of an operator's body part, for example a finger, with which a closing or locking of the door lock is to be initiated. In the metallization layer of the circuit board 10 is further formed as a plate sensor electrode 73 arranged a second capacitive proximity sensor, for example, for detecting the approach of an operator body part, for. As the hand of the operator, serves to trigger a radio dialogue with an ID transmitter for authorizing access to the vehicle and a corresponding unlocking the door lock.

The sensor electrode designed as an NFC antenna coil 20 has two connections 21 . 22 on. The connections 21 . 22 are with a coupling circuit 30 connected. The coupling circuit 30 is in turn with an NFC building block 40 and a microcontroller 55 connected. The microcontroller 55 contains a drive and evaluation circuit for the sensor electrode 20 and a drive and evaluation circuit for a further sensor electrode 73 , A connection 71 the sensor electrode 73 is with the microcontroller 55 connected. The coupling circuit 30 couples the connections 21 and 22 the sensor electrode formed as an NFC antenna coil 20 either with the NFC module 40 or with the in the microcontroller 55 contained control and evaluation circuit.

In the embodiment according to 1 is the sensor electrode 73 of the second capacitive proximity sensor longitudinally spaced from the sensor electrode formed as an NFC antenna coil 20 arranged to reduce mutual interference. The components, like the microcontroller 55 , the NFC building block 40 and the coupling circuit 30 are on the circuit board 10 between the two electrodes 20 and 73 arranged. At the in 1 shown schematic representation of the components appear 55 . 40 . 30 and the electrodes formed in the PCB metallization layer 20 and 73 on a circuit board side.

In another preferred embodiment, the components 55 . 40 and 30 also be mounted on the other side of the PCB. In yet other embodiments, the circuit board may include two or more metallization levels and may be the sensor electrode 20 and the sensor electrode 73 in different planes or on different sides of the circuit board 10 be educated. Finally, it is also conceivable that the sensor electrode 73 and optionally further sensor electrodes as separate components (metal plates or foils or metallization layers of other circuit boards) formed and spaced from the circuit board 10 are arranged.

2 shows the on the circuit board 10 according to 1 placed components in one Block diagram. The connections 21 and 22 the sensor electrode formed as an NFC antenna coil 20 are with the coupling circuit 30 connected. The coupling circuit 30 includes several switching elements 31a . 31b and 31c , For example, semiconductor switching devices, such as MOS or bipolar switching transistors or the like. In the in 2 illustrated state of the coupling circuit 30 are the connections 21 and 22 with the NFC module 40 connected, but not with the control and evaluation circuit 60 , In another, not in 2 shown state is the connection 22 the sensor electrode formed as an NFC antenna coil 20 over the coupling circuit 30 with the control and evaluation circuit 60 connected and are the two connectors 21 and 22 from the NFC device 40 separated. The coupling circuit 30 , the NFC building block 40 and the control and evaluation circuit 60 are with ports 51 a microcontroller 50 connected. The sensor electrode 73 of the second capacitive proximity sensor is also with an associated control and evaluation 70 connected, in turn, also with the microcontroller 50 is coupled.

The microcontroller 50 controls the drive and evaluation circuits 60 and 70 , the NFC building block 40 and the coupling circuit 30 , Depending on an operating state of the microcontroller 50 is for example the NFC antenna coil 20 over the switching components 31b and 31c with the NFC module 40 connected. The sensor electrode 20 acts as an NFC antenna coil of the NFC device 40 , In this operating state, the sensor electrode designed as an NFC antenna coil is 20 through the opened switching device 31a separated from the control and evaluation circuit, whereby an influence on the NFC communication by the control and evaluation circuit 60 can be avoided. After completion of the NFC communication can be changed to another operating state, for example, to trigger a locking of the outer doors of a motor vehicle. In this further operating state of the microcontroller 50 is a connection 22 the sensor electrode 20 over the switching device 31a the coupling circuit 30 with the control and evaluation circuit 60 connected. In order not to influence the capacitance measurement, the NFC block becomes 40 by means of the switching components 31b and 31c from the terminals 21 and 22 separated. The switching devices may be, for example, analog switches that affect capacitance measurement and NFC communication only to a small, tolerable extent. Preferably, the analog switch has a low internal resistance and low parasitic capacitances. The microcontroller 50 can in a preferred embodiment of this embodiment drive and evaluation circuits 60 and or 70 contain.

3 shows an alternative embodiment of the outside door handle according to the invention, wherein like elements with the same reference numerals as in 2 Marked are. The microcontroller 50 is again via ports 51 with the first control and evaluation circuit 60 , the second control and evaluation circuit 70 , the NFC building block 40 and a coupling circuit 35 connected. The second control and evaluation circuit 70 forms with the sensor electrode 73 the second capacitive proximity sensor. The NFC building block 40 is in turn via the coupling circuit 35 that have two switching elements 36b . 36c includes, with connections 21 and 22 the sensor electrode formed as an NFC antenna coil 20 connected. In this embodiment, connection is 22 the NFC antenna coil 20 permanently with the first control and evaluation circuit 60 connected. The number of required switching elements 31 is thus lower than in the 2 illustrated embodiment of the invention.

The mode of operation is essentially the same as in 2 illustrated embodiment. Deviating in the operating state of the NFC communication designed as NFC antenna coil sensor electrode 20 not from the control and evaluation circuit 60 separated. In an operating state of the control and evaluation circuit 60 that of the microcontroller 50 is controlled, the NFC communication is not or not significantly by the control and evaluation circuit 60 disturbed. In the operating state of the microcontroller in which the capacitance measurement is carried out, the sensor electrode formed as an NFC antenna coil by the switching devices 36b and 36c the coupling circuit 35 from the NFC device 40 separated. The operating state of the control and evaluation circuit 60 is changed so that a capacitance measurement is performed. The control and evaluation circuit 60 can be a part of the microcontroller 50 be.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 19617038 A1 [0002]

Claims (14)

Outside door handle for a motor vehicle, wherein the outside door handle at least one capacitive proximity sensor with at least one sensor electrode ( 20 ) and a control and evaluation circuit ( 60 ) and a control circuit ( 50 ; 55 ), characterized in that the outside door handle at least one with an NFC antenna coil ( 20 ) couplable NFC device ( 40 ), one of the at least one sensor electrode ( 20 ) is designed as an NFC antenna coil and the connections ( 21 . 22 ) of the NFC antenna coil ( 20 ) via a coupling circuit ( 30 ; 35 ) with the NFC module ( 40 ), the coupling circuit ( 30 ; 35 ), the control and evaluation circuit ( 60 ) and the NFC building block ( 40 ) with the control circuit ( 50 ; 55 ), the control circuit ( 50 ; 55 ) the coupling circuit ( 30 ; 35 ) such that the connections ( 21 . 22 ) of the NFC antenna coil ( 20 ) in dependence on an operating state of the control circuit ( 50 ; 55 ) selectively with the NFC building block ( 40 ) or from the NFC building block ( 40 ) can be separated such that the NFC antenna coil ( 20 ) as a sensor electrode ( 60 ) of the capacitive proximity sensor acts. Outside door handle according to claim 1, characterized in that one of the connections ( 22 ) of the NFC antenna coil ( 20 ) always with the control and evaluation circuit ( 60 ) is coupled. Outside door handle according to claim 1, characterized in that the coupling circuit ( 30 ; 35 ) a switching device ( 31a ) for coupling one of the connections ( 22 ) of the NFC antenna coil ( 20 ) with the control and evaluation circuit ( 60 ) having. Outside door handle according to claim 3, characterized in that the switching device ( 31a ) is contained in a component that controls the drive and evaluation circuit ( 60 ) contains. Outside door handle according to claim 4, characterized in that the drive and evaluation circuit ( 60 ), the switching device ( 31a ) of the coupling circuit ( 30 ; 35 ) and the control circuit ( 50 ; 55 ) are contained in a microcontroller, a connector ( 22 ) of the NFC antenna coil with a port ( 51 ; 56 ) of the microcontroller and the connection ( 22 ) from the control and evaluation circuit ( 60 ) is disconnected by the port ( 51 ; 56 ) is switched high impedance. Outside door handle according to claim 5, characterized in that the entire coupling circuit ( 30 ; 35 ) is contained in the microcontroller. Outside door handle according to one of claims 1 to 3, characterized in that the control circuit ( 50 ; 55 ) has a arranged in an interior of the outside door handle microcontroller. Outside door handle according to one of the preceding claims, characterized by at least one further each a drive and evaluation circuit ( 70 ) and at least one sensor electrode ( 73 ) and with the control circuit ( 50 ; 55 ) coupled capacitive proximity sensor. Outside door handle according to claim 8, characterized in that the NFC antenna coil formed as a sensor electrode ( 20 ) and at least one of the sensor electrodes ( 73 ) of the at least one further capacitive proximity sensor with a common control and evaluation circuit ( 60 . 70 ) are coupled. Outside door handle according to one of the preceding claims, characterized in that the coupling circuit ( 30 ; 35 ) Has analog switch. Outside door handle according to one of the preceding claims, characterized in that the control circuit ( 50 ; 55 ), the control and evaluation circuit ( 60 ), the NFC building block ( 40 ) and the coupling circuit ( 30 ; 35 ) on a printed circuit board ( 10 ) are mounted. Outside door handle according to one of the preceding claims, characterized in that the NFC antenna coil designed as a sensor electrode ( 20 ) of a conductor on a printed circuit board ( 10 ) is formed. Outside door handle according to claim 12, characterized in that on which the NFC antenna coil designed as a sensor electrode ( 20 ) comprehensive circuit board ( 10 ) at least the coupling circuit ( 30 ; 35 ) and the control and evaluation circuit ( 60 ) are arranged. Outside door handle according to claim 13, characterized in that all in the state of disconnecting the NFC module ( 40 ) of the NFC antenna coil designed as a sensor electrode ( 20 ) with the connections ( 21 . 22 ) of the NFC antenna coil formed as a sensor electrode ( 20 ) coupled components of the coupling circuit ( 30 ; 35 ) immediately adjacent to the NFC antenna coil ( 20 ) are arranged.

Images