DE102020215322A1 - Device and method for antenna power supply for a vehicle and antenna device - Google Patents

Abstract

The invention relates to a device (104) for supplying power to an antenna for a vehicle (100). The device (104) is designed to provide an intermediate current using an input current and an input voltage signal representing a magnitude of the input current, a supply current for phantom powering for an antenna amplifier (110) controlled by a switching signal using the intermediate current and an output voltage signal representing a magnitude of the supply current provide, provide a reset signal using the input voltage signal and the output voltage signal, and provide the switching signal using a control signal and the reset signal.

Description

State of the art

The invention is based on a device or a method according to the species of the independent claims.

For phantom powering for an antenna amplifier of an antenna for a vehicle, simple linear regulators with a PNP main transistor or a P-channel FET can be used, which contain additional circuits for current measurement and switch-off mechanisms for short circuit to ground, short circuit to vehicle voltage and overtemperature. However, these regulators require at least a voltage swing of IV. Standard "high side switches" typically cannot be used because they contain "charge pumps" with high frequencies.

Disclosure of Invention

Against this background, a device and a method for antenna power supply for a vehicle and an antenna device according to the main claims are presented with the approach presented here. Advantageous developments and improvements of the device specified in the independent claim are possible as a result of the measures listed in the dependent claims.

The approach described enables an antenna power supply for applications in which simple linear regulators cannot be used, for example when the voltage swing required by the linear regulators is not available.

• einen Antennenanschluss für eine Antennenleitung zu einem Antennenverstärker einer Antenne;
• einen Tuner für ein über die Antennenleitung übertragenes Antennensignal, wobei der Tuner mit dem Antennenanschluss gekoppelt ist;
• eine Energieversorgungseinrichtung zum Bereitstellen einer ungeschützten Versorgungsspannung;
• eine Steuereinrichtung zum Bereitstellen eines Steuersignals; und
• eine mit dem Antennenanschluss gekoppelte Schaltung zum Bereitstellen einer geschützten Antennenspannung zur Phantomspeisung für den Antennenverstärker.

An antenna power supply device for a vehicle has the following features:

• an antenna connection for an antenna line to an antenna amplifier of an antenna;
• a tuner for an antenna signal transmitted via the antenna line, the tuner being coupled to the antenna connection;
• an energy supply device for providing an unprotected supply voltage;
• a controller for providing a control signal; and
• circuitry coupled to the antenna connector for providing a protected antenna voltage for phantom powering the antenna amplifier.

• eine Strommesseinrichtung mit einem mit der Energieversorgungseinrichtung gekoppelten Eingangsanschluss zum Empfangen eines Eingangsstroms, einem Ausgangsanschluss und einem Eingangsmessanschluss, wobei die Strommesseinrichtung ausgebildet ist, um unter Verwendung des Eingangsstroms einen Zwischenstrom an dem Ausgangsanschluss bereitzustellen und ein eine Größe des Eingangsstroms repräsentierendes Eingangsspannungssignal an dem Eingangsmessanschluss bereitzustellen;
• eine Schalteinrichtung mit einem Zwischenanschluss zum Empfangen des Zwischenstroms, einem mit dem Antennenanschluss gekoppelten Versorgungsanschluss, einem Schalteingangsanschluss zum Empfangen eines Schaltsignals und einem Ausgangsmessanschluss, wobei die Schalteinrichtung ausgebildet ist, um gesteuert von dem Schaltsignal unter Verwendung des Zwischenstroms einen Versorgungsstrom zum Generieren einer geschützten Antennenspannung an dem Versorgungsanschluss bereitzustellen und ein eine Größe des Versorgungsstroms repräsentierendes Ausgangsspannungssignal an dem Ausgangsmessanschluss bereitzustellen;
• einer Überwachungseinrichtung mit einem ersten Messanschluss zum Empfangen des Eingangsspannungssignals und einem zweiten Messanschluss zum Empfangen des Ausgangsspannungssignals und einem Rücksetzanschluss, wobei die Überwachungseinrichtung ausgebildet ist, um unter Verwendung des Eingangsspannungssignals und des Ausgangsspannungssignals ein Rücksetzsignal an dem Rücksetzanschluss bereitzustellen; und
• eine Einschalteinrichtung mit einem Steueranschluss zum Empfangen des Steuersignals, einem Resetanschluss zum Empfangen des Rücksetzsignals und einem Signalanschluss, wobei die Einschalteinrichtung ausgebildet ist, um unter Verwendung des Steuersignals und des Rücksetzsignals das Schaltsignal an dem Signalanschluss bereitzustellen.

The circuit has the following features:

• a current measuring device with an input connection coupled to the energy supply device for receiving an input current, an output connection and an input measuring connection, the current measuring device being designed to provide an intermediate current at the output connection using the input current and to provide an input voltage signal representing a magnitude of the input current at the input measuring connection;
• a switching device with an intermediate connection for receiving the intermediate current, a supply connection coupled to the antenna connection, a switching input connection for receiving a switching signal and an output measuring connection, the switching device being designed to, controlled by the switching signal using the intermediate current, supply a supply current for generating a protected antenna voltage to provide the supply connection and to provide an output voltage signal representing a magnitude of the supply current at the output measuring connection;
• a monitoring device with a first measurement connection for receiving the input voltage signal and a second measurement connection for receiving the output voltage signal and a reset connection, wherein the monitoring device is designed to provide a reset signal at the reset connection using the input voltage signal and the output voltage signal; and
• a switch-on device with a control connection for receiving the control signal, a reset connection for receiving the reset signal and a signal connection, the switch-on device being designed to provide the switching signal at the signal connection using the control signal and the reset signal.

The vehicle can be a vehicle for passenger transport or a truck, for example. The antenna can be part of a radio interface of the vehicle. For example, the antenna can be used to receive signals for position determination. The antenna can be attached to a vehicle board be connected to the vehicle network. The supply current can be used for so-called phantom power. The phantom power can represent the power supply of the antenna amplifier in the form of a low-noise amplifier LNA (Low Noise Amplifier) at the antenna base of the antenna. The phantom power can form the DC voltage on the antenna line. The same rules in the vehicle electrical system apply to phantom power as to all other external control unit connections. They must be short-circuit-proof and current-limited. The filter requirements apply even more to an antenna feed, since the antenna feed must be filtered as strongly as possible, in addition to the EMC (electromagnetic compatibility) requirements, especially for the sensitive area of the antenna. Under no circumstances should additional interference, eg from a charge pump or a switching regulator, be passed on.

According to one embodiment, the described approach makes it possible to generate an antenna voltage of 5V+-0.5V from an available voltage of 5V+-3% with protective measures for short circuits to ground, short circuits to the vehicle electrical system voltage and overtemperature. In addition, a current measurement can be made possible.

The current measuring device can have a measuring resistor which is connected between the input connection and the output connection. The current measuring device can be designed to determine the input voltage signal using a measuring voltage dropping across the measuring resistor. In this way, the current can be passed through the current measuring device and measured at the same time.

For this purpose, the current measuring device can have an operational amplifier and an input voltage divider for determining the input voltage signal. Thus, standard components can be used.

The switching device can have a transistor device that can be switched by the switching signal and is connected between the intermediate connection and the supply connection. Depending on the switching state of the transistor device, the intermediate current may or may not be provided as a supply current. The transistor circuit may include one or more suitable transistors.

For example, the transistor device can comprise two field effect transistors connected in opposite directions. A so-called back-to-back circuit of two transistors can thus advantageously be used to pass or block the flow of current through the switching device.

The switching device can have an output voltage divider for determining the output voltage signal. This makes it easy to determine the output voltage.

The monitoring device can be designed to provide the reset signal when the input voltage signal exceeds a first threshold value and/or the output voltage signal exceeds a second threshold value. The threshold values can be chosen to be the same or different. In this way, if the voltage is exceeded, further provision of the supply current can be interrupted.

The switch-on device can have a bistable multivibrator and a transistor for providing the switching signal using the control signal and the reset signal. Advantageously, in this way not only current states of the input signals of the flip-flop but also chronologically preceding states of the input signals can be taken into account when the switching signal is provided.

The flip-flop can have a reset input, a set input, a non-negated output and a negated output. In this case, the reset input can be connected to the non-negated output and the reset connection. The set input can be connected to the control connection. The negated output can be connected to the transistor to switch the transistor. This enables the switching signal to be provided based on the principle of an RS flip-flop.

The switch-on device can have a capacitor which is connected to the reset connection. A defined start-up of the device can be set by a suitable choice of a capacitance of the capacitor.

By way of example only, the energy supply device can be in the form of a 5V voltage source. Other voltage values are correspondingly possible.

The device can have a coupling device which is designed to couple the protected antenna voltage into the antenna connection using the supply current. Known coupling circuits can be used here.

The device can advantageously be used in connection with an antenna device.

In addition to the device mentioned, a corresponding antenna device has an antenna, an antenna amplifier and an antenna line.

The antenna amplifier can be designed separately from the antenna or integrated into the antenna. The antenna can be an antenna typically installed in the vehicle area, for example a rod antenna or a planar antenna.

• Bereitstellen eines Zwischenstroms um unter Verwendung eines Eingangsstroms;
• Bereitstellen eines eine Größe des Eingangsstroms repräsentierenden Eingangsspannungssignals;
• Bereitstellen eines Versorgungsstroms zur Phantomspeisung für einen Antennenverstärker unter Verwendung des Zwischenstroms gesteuert von einem Schaltsignal;
• Bereitstellen eines eine Größe des Versorgungsstroms repräsentierenden Ausgangsspannungssignals;
• Bereitstellen eines Rücksetzsignals unter Verwendung des Eingangsspannungssignals und des Ausgangsspannungssignals; und
• Bereitstellen des Schaltsignals unter Verwendung eines Steuersignals und des Rücksetzsignals.

A corresponding method for antenna power supply for a vehicle includes the following steps:

• providing an intermediate current um using an input current;
• providing an input voltage signal representing a magnitude of the input current;
• providing a supply current for phantom power for an antenna amplifier using the intermediate current controlled by a switching signal;
• providing an output voltage signal representing a magnitude of the supply current;
• providing a reset signal using the input voltage signal and the output voltage signal; and
• providing the switching signal using a control signal and the reset signal.

This method can be implemented, for example, in software or hardware or in a mixed form of software and hardware. The steps of the method can be carried out, for example, using means of said apparatus.

In the present case, a device can be understood to mean an electrical device. The device can have an interface that can be configured as hardware and/or software. In the case of a hardware design, the interfaces can be part of a so-called system ASIC, for example, which contains a wide variety of functions of the device. However, it is also possible for the interfaces to be separate integrated circuits or to consist at least in part of discrete components. In the case of a software design, the interfaces can be software modules which are present, for example, on a microcontroller alongside other software modules.

• 1 eine schematische Darstellung eines Fahrzeugs mit einer Antennenvorrichtung gemäß einem Ausführungsbeispiel;
• 2 ein Schaltbild einer Schaltung zur Phantomspeisung gemäß einem Ausführungsbeispiel; und
• 3 ein Ablaufdiagramm eines Verfahrens zur Antennenstromversorgung gemäß einem Ausführungsbeispiel.

Exemplary embodiments of the approach presented here are shown in the drawings and explained in more detail in the following description. It shows:

• 1 a schematic representation of a vehicle with an antenna device according to an embodiment;
• 2 a circuit diagram of a circuit for phantom power according to an embodiment; and
• 3 a flow chart of a method for antenna power supply according to an embodiment.

In the following description of favorable exemplary embodiments of the present invention, the same or similar reference symbols are used for the elements which are shown in the various figures and have a similar effect, with a repeated description of these elements being dispensed with.

1 FIG. 1 shows a schematic representation of a vehicle 100 with an antenna 102 according to an exemplary embodiment. For example, the vehicle 100 is a passenger car. For example only, the antenna 102 is the antenna of a positioning system.

The antenna 102 may be part of an antenna device or connected to an antenna device. According to this exemplary embodiment, the antenna device has, by way of example, a device 104 for supplying antenna power, an antenna line 108 and an antenna amplifier 110 . The antenna amplifier 110 is connected between the antenna 102 and the device 104 . The antenna amplifier 110 is optionally integrated into the antenna 102. For example, the antenna amplifier 110 is designed as a low-noise amplifier, as a so-called low-noise amplifier.

The antenna line 108 is designed to route an antenna signal from the antenna amplifier 110 to the device 104 and to provide a protected antenna voltage 111 provided by the device 104 for supplying the antenna amplifier 110 as so-called phantom power to the antenna amplifier 110 .

The device 104 has an antenna connection 112 via which the device 104 is connected to the antenna line 108 .

For example, the device 104 is supplied with a battery voltage via an interface to a battery 114 of the vehicle.

According to one exemplary embodiment, device 104 comprises an energy supply device 120 for providing a supply voltage, a control device 122 for providing a control signal, a tuner 124 for the antenna signal received via antenna line 108, and a circuit 126.

By way of example, the energy supply device 120 represents an energy supply module that is supplied with the battery voltage via the battery 114 . The energy supply device 120 serves to supply energy to the control device 122, the tuner 124 and the circuit 126. The energy supply device 120 provides an antenna voltage without a switching mechanism as an unprotected supply voltage 129 to the circuit 126 via a connecting line.

The circuit 126 is designed to generate a supply current from the unprotected supply voltage 129 provided by the energy supply device 120 and to couple the switched, protected antenna voltage 111 into the antenna connection 112 using the supply current. The switched, protected antenna voltage 111 is suitable for phantom powering for the antenna amplifier 110. For example, the circuit 126 includes a suitable coupling device 128 for coupling the protected antenna voltage 111 into the antenna connection 112.

The control device 122 is connected to the energy supply device 120, the tuner 124 and the circuit 126 via control lines. The control lines include, for example, monitor and control lines, via which, for example, log on/off and analog/digital converter monitoring are possible, if this is additionally provided.

According to one embodiment, a control signal provided by the controller 122 to the circuit 126 is used by the circuit 126 to protect the antenna voltage to be coupled into the antenna port 112 .

According to one exemplary embodiment, the tuner 124 is part of a receiver module, a so-called receiver module. The tuner 124 is coupled to the antenna port 112 via the circuit 126 according to one embodiment. For example, the circuit 124 is designed to couple the antenna connection 112 to the tuner 124 using the coupling device 128 or a further coupling device.

According to one embodiment, the device 104 is designed as a device, with the energy supply device 120 being integrated as a 5V supply in the device. The antenna amplifier 110, which is located either in the antenna 102 or in an additional device, is supplied via the antenna line 108, which also requires a voltage of 5V.

2 FIG. 12 shows a circuit diagram of a circuit 126 for phantom powering for an antenna amplifier for an antenna according to an exemplary embodiment. It can be an embodiment of the basis of 1 shown circuit act.

The circuit 126 comprises a current measuring device 200, a switching device 202, a monitoring device 204, a switch-on device 206 and optionally an energy supply device 120 and/or a control device 122.

The current measuring device 200 has an input connection 220 , an output connection 222 and an input measurement connection 224 . The current measuring device 200 is designed to receive an input current 226 via the input connection 220 which, according to this exemplary embodiment, is caused by the supply voltage 129 provided by the energy supply device 120 . The current measuring device 200 is designed to provide an intermediate current 228 at the output connection 222 using the input current 226 . Furthermore, the current measuring device 200 is designed to provide an input voltage signal 230 at the input measuring connection 224 which represents a magnitude of the input current 226 .

The switching device 202 has an intermediate connection 232 , a supply connection 234 , a switching input connection 236 and an output measurement connection 238 . The switching device 202 is designed to receive the intermediate current 228 via the intermediate connection 232 . For this purpose, the intermediate connection 232 is connected to the output connection 222 of the current measuring device 200 . The switching device 202 is designed to provide the supply current 106 at the supply connection 234 . The supply current 106 can be coupled into the antenna line 108 directly or, for example, after smoothing, for example using a coupling device 128. According to one exemplary embodiment, the coupling device 128 is embodied det to couple the protected antenna voltage 111 to the antenna line 108 or an antenna connection using the supply current 106 for phantom powering of the antenna amplifier. The switching device 202 is designed to receive a switching signal 240 via the switching input connection 236 and to use it to provide the supply current 106 . According to this exemplary embodiment, a connection between the intermediate connection 232 and the supply connection 234 is interrupted or released under the control of the switching signal 240 . Furthermore, the switching device 202 is designed to provide an output voltage signal 242 at the output measurement connection 238 that represents a magnitude of the supply current 106 .

The monitoring device 204 has a first measuring connection 244 , a second measuring connection 246 and a reset connection 248 . The monitoring device 204 is designed to receive the input voltage signal 230 via the first measurement connection 244 and the output voltage signal 238 via the second measurement connection 246 . For this purpose, the first measuring connection 244 is connected, for example, to the input connection 220 of the current measuring device 200 and the second measuring connection 246 is connected to the output measuring connection 238 of the switching device 202 . The monitoring device 204 is designed to provide a reset signal 250 at the reset connection 248 using the input voltage signal 230 and the output voltage signal 238 .

The switch-on device 206 has a control connection 252 , a reset connection 254 and a signal connection 256 . The switch-on device 206 is designed to receive a control signal 258 via the control connection 252 , to receive the reset signal 250 via the reset connection 254 and to provide the switching signal 240 via the signal connection 256 . For this purpose, the reset connection 254 is connected to the reset connection 248 of the monitoring device 204, for example, and the signal connection 256 is connected to the switching input connection 236 of the switching device 202, for example. By way of example, control signal 258 is provided by control device 122 . Switch-on device 206 is designed to determine switching signal 240 using control signal 258 and reset signal 250 and to provide it at signal connection 256 .

Depending on the technical design of the devices 200, 202, 204, 206, the connections 220, 222, 224, 232, 234, 236, 244, 246, 248, 252, 254, 256 can be external contacts or internal interfaces . Devices 200, 202, 204, 206 may be implemented, for example, using discrete components or one or more integrated circuits.

According to one exemplary embodiment, the current measuring device 200 has a measuring resistor 260 , an operational amplifier 262 and a voltage divider 264 for measuring the input current 226 , which corresponds at least approximately to the intermediate current 228 . The sense resistor 260 is connected between the input port 220 and the output port 222 . The voltage drop across measuring resistor 260 is amplified by operational amplifier 262 and fed to voltage divider 264 . The voltage divider comprises a series connection of two resistors, with a connection point of the two resistors being connected to the input measurement terminal 224 .

The current measurement arrangement shown is only an example. Correspondingly, other known circuits for current measurement can be used.

According to an embodiment, the current measuring device 200 is suitable for current-to-voltage conversion. The input voltage signal 230 is also referred to as the 12V signal.

According to one embodiment, the switching device 202 has a transistor device 266 . The transistor device 266 is connected between the intermediate connection 232 and the supply connection 234 and is switched by the switching signal 240 . For this purpose, a control input of the transistor device 266 is connected to the switching input connection 236 . The switching signal 240 can assume different states, which are set using the switch-on device 206 . If the transistor device 266 is switched on, the intermediate current 228 is conducted through the transistor device 266 to the supply connection 234 and is provided there as the supply current 106 . When the transistor device 266 is switched off, the supply current 106 is not provided.

By way of example, the transistor device 266 has two field effect transistors connected in opposite directions.

The switching device 202 has a further voltage divider 268 for determining the output voltage signal 242 . The further voltage divider 268 has a series connection of two resistors and is between the Versor supply terminal 234 and ground connected. The output measuring connection 238 is connected to a connection point of the resistors of the further voltage divider 268 . The output voltage signal 242 is also referred to as signal Vdiv.

The monitoring device 204 is designed to monitor the currents 226, 228, 234 and/or the voltages present at the terminals 220, 222, 232, 234 using the signals 230, 238. For example, monitoring device 204 is designed to detect a short circuit to a battery voltage of the vehicle or to ground that affects the current path between terminals 220, 234 and to display it as an error state. When an error state is detected, the monitoring device 204 is designed to provide the reset signal 250 .

According to one exemplary embodiment, the monitoring device 204 is designed to provide the reset signal 250 when the input voltage signal 230 exceeds a threshold value in terms of absolute value. Additionally or alternatively, the monitoring device 204 is designed to provide the reset signal 250 when the output voltage signal 238 exceeds the same or a further threshold value in terms of absolute value.

According to one exemplary embodiment, the monitoring device 204 has a comparator 270 for this purpose, which can represent a double overvoltage monitor.

According to one exemplary embodiment, the monitoring device 204 has a connection 272 for receiving an input voltage and a transistor 274 in addition to the comparator 270 . The input voltage is used to operate the comparator 270 according to one embodiment. A first input of the comparator 270 is connected to the first measurement connection 244 and a second input of the comparator 270 is connected to the second measurement connection 246 . A first output of the comparator 270 is connected to the terminal 272 and a control terminal of the transistor 274 via a resistor. A second output of the comparator 270 is connected to the reset terminal 248 . Transistor 274 is connected between the second output of comparator 270 and ground. Thus, using transistor 274, reset terminal 248 can be pulled to ground potential controlled by the first output of the comparator.

According to one exemplary embodiment, switch-on device 204 is designed to provide switching signal 240 with a first state that switches transistor circuit 266 on when control signal 258 indicates a desired operation of circuit 126 and reset signal 250 indicates no error state. Accordingly, the switch-on device 204 is designed according to one embodiment to provide the switching signal 240 with a second state that switches the transistor circuit 266 off when the control signal 258 does not indicate a desired operation of the circuit 126 and/or the reset signal 250 indicates an error state.

According to one exemplary embodiment, the switch-on device 206 includes a bistable multivibrator 270, also referred to as a flip-flop, and a transistor 278. The transistor 278 is switched by the bistable multivibrator 270. When the transistor 278 is turned on, the transistor 278 is configured to pull the signal terminal 256 and thus the switching signal 240 to ground. The signal port 256 is connected to the control port 252 according to one embodiment.

According to the exemplary embodiment shown, the flip-flop 270 has a reset input (INA+), a set input (INB-), a non-negated output (OUTB) and a negated output (OUTA). The reset input (INA+) is connected to the non-negated output (OUTAB) and to the reset terminal 254. The set input (INB-) is connected to the control terminal 252. The negated output (OUTA) is connected to a control input of transistor 278.

According to one embodiment, the switch-on device 206 has a connection 282 for receiving an input voltage and the control connection 252, the set input (INB-) and the signal connection 256 are connected to the connection 282 via a resistor, the reset input (INA+) is connected via a further resistor to terminal 282 and the output (OUTA) is connected to terminal 282 via a third resistor.

According to one embodiment, the enabling device 206 includes a capacitor 280 connected between the reset terminal 254 and ground.

The energy supply device 120 is in the form of a 5V voltage source purely by way of example. Optionally, the energy supply device 120 is designed to provide a further voltage, for example a 3.3V voltage. which is used, for example, to operate the operational amplifier 262.

In 2 1, one embodiment of antenna power supply circuit 126 is shown in several blocks.

The circuit 126 makes it possible, for example from 5V+-3% provided by the energy supply device 120, to generate the antenna voltage 111 of for example 5V+-0.5V with protective measures for a short circuit to ground, a short circuit to the vehicle electrical system voltage and overtemperature. In addition, a current measurement is made possible.

The circuit 126 meets these requirements by exploiting the different tolerance ranges of input and output. The 3% of 5V is 150mV, leaving 350mV for conduction loss and the circuit. In the event of a short circuit to ground or to on-board voltage, the system is switched off directly, according to one exemplary embodiment by reset signal 250. All parameters of these shutdowns, such as shutdown current and shutdown voltage and the respective response times, can be set by selecting discrete components of the circuit. An over-temperature shutdown is no longer necessary because no more heat is generated. The resistances in the direct path between the input connection 220 and the supply connection 234 are the measuring resistor 260 for the current measurement and the internal resistance of the transistor circuit 266, ie for example the RDS on two p-channel FETs. Since the FETs only operate in forward or reverse mode, no significant heat is generated. The measuring resistor 260 corresponds to the desired current and/or the set current cut-off. In the case of a design as a MELF (Metal Electrode Leadless Faces) resistor, there is the additional advantage of a fuse, since in the event of an overload only the conductive layer would evaporate and the measuring resistor 260 ultimately acts as a safeguard against greater damage.

In the circuit 126 no regulations take place. This means that no additional frequencies can arise.

According to one exemplary embodiment, the current measurement with the measuring resistor 260 and a suitable operational amplifier 262 is connected downstream of the power supply, which is shown by way of example in the form of the energy supply device 120 . The output of the current measurement is a current path and the voltage equivalent to the measured current, which is provided, for example, in the form of the input voltage signal 230 .

The current path leads to the switching device 202 with a switch, which is designed in the form of the transistor device 266 as a “back-to-back p-channel FET” structure, for example. In this case, the transistor device 266 includes two FETs whose parasitic diodes are in opposite directions.

A further smoothing and coupling into the antenna signal then optionally follows after the switching device 202 . This includes, for example, a choke on the antenna line 108 and a capacitor to ground. This LC element advantageously has a zero at the desired antenna frequency. In addition, the voltage divider 268 is contained in the output of the switching device 202, which makes a voltage signal, here in the form of the output voltage signal 242, available.

The voltage equivalent to the current measured in the measuring device 200 and the output voltage go into the monitoring device 204, for example into the comparator 270, which can be designed as a double comparator block. As soon as the current or voltage becomes too high, the comparator 270 generates the reset signal 250, also referred to as the reset signal.

According to one exemplary embodiment, this reset signal 250 goes to the bidirectional flip-flop 270 in the form of an RS flip-flop signal. According to one embodiment, the comparator 270 and the bidirectional flip-flop 270 are formed together in an integrated circuit, for example in the form of a comparator ASIC. According to one exemplary embodiment, control signal 258 represents a set signal that is provided by control device 122, which is embodied, for example, as a controller of a control unit (ECU). The capacitor 280 ensures a defined start-up of the circuit in the desired state of the bidirectional flip-flop 270. According to one embodiment, the negated Q output (OutA) of the bidirectional flip-flop 270 goes to the gate of the switch blocks, which include, for example, the transistor 278 and the transistor device 266 . The supply is started with a 0 signal. This can correspond to the first state of switching signal 240 mentioned.

Circuit 126 is used, for example, on a built-in circuit board for an ASIL B-capable position device.

3 shows a flowchart of a method for providing an antenna power supply according to an embodiment. The method can be used, for example be implemented in the circuit described with reference to the previous figures.

In a step 301 an intermediate stream is provided using an input stream. In a step 303, an input voltage signal representing a magnitude of the input current is provided. In a step 305, the supply current for phantom powering for an antenna amplifier is provided under the control of a switching signal using the intermediate current. In a step 307, an output voltage signal representing a magnitude of the supply current is provided. In a step 309, a reset signal is provided using the input voltage signal and the output voltage signal. In a step 311, the switching signal is provided using a control signal and the reset signal.

Steps 301, 303, 305, 307, 309, 311 can be continuously repeated.

Claims (13)

Device (104) for antenna power supply for a vehicle (100), the device (104) an antenna connection (112) for an antenna line (108) to an antenna amplifier (110) of an antenna (102), a tuner (124) for an over antenna signal transmitted by the antenna line (108), the tuner (124) being coupled to the antenna connection (112), an energy supply device (120) for providing an unprotected supply voltage (129), a control device (122) for providing a control signal (258), and a circuit (126) coupled to the antenna connection (112) for providing a protected antenna voltage (111) for phantom powering for the antenna amplifier (110), characterized in that the circuit (126) has the following features: a current measuring device (200) having an input terminal (220) coupled to the energy supply device (120) for receiving an input current (226), an output a Connection (222) and an input measuring connection (224), wherein the current measuring device (200) is designed to use the input current (226) to provide an intermediate current (228) at the output connection (222) and a magnitude of the input current (226) representing providing an input voltage signal (230) at the input measurement port (224); a switching device (202) having an intermediate connection (232) for receiving the intermediate current (228), a supply connection (234) coupled to the antenna connection (112), a switching input connection (236) for receiving a switching signal (240) and an output measurement connection (238) , wherein the switching device (202) is designed to provide a supply current (106) for generating the protected antenna voltage (111) at the supply connection (234), controlled by the switching signal (240) using the intermediate current (228), and a magnitude of the provide an output voltage signal (242) representing the supply current (106) at the output measurement terminal (238); a monitoring device (204) with a first measurement connection (244) for receiving the input voltage signal (230) and a second measurement connection (246) for receiving the output voltage signal (242) and a reset connection (248), wherein the monitoring device (204) is designed to providing a reset signal (250) at the reset terminal (248) using the input voltage signal (230) and the output voltage signal (242); and a switch-on device (206) with a control connection (252) for receiving the control signal (258), a reset connection (254) for receiving the reset signal (250) and a signal connection (256), wherein the switch-on device (206) is designed to using the control signal (258) and the reset signal (250) to provide the switching signal (240) at the signal terminal. Device (104) according to claim 1 , in which the current measuring device (200) has a measuring resistor (260) which is connected between the input connection (220) and the output connection (222) and wherein the current measuring device (200) is designed to measure the input voltage signal (230) using a to to determine the measuring voltage dropping across the measuring resistor (260). Device (104) according to claim 2 , wherein the current measuring device (200) has an operational amplifier (262) and an input voltage divider (264) for determining the input voltage signal (230). Device (104) according to one of the preceding claims, in which the switching device (202) comprises a transistor device (266) which can be switched by the switching signal (240) and which is connected between the intermediate connection (232) and the supply connection (234). Device (104) according to claim 4 , wherein the transistor device (266) comprises two field effect transistors connected in opposite directions. Device (104) according to one of the preceding claims, in which the monitoring device (204) is designed to provide the reset signal (250) if the input voltage signal (230) exceeds a first threshold value and/or the output voltage signal (242) exceeds a second threshold value . Device (104) according to one of the preceding claims, in which the switch-on device (206) has a bistable multivibrator (270) and a transistor (278) for providing the switching signal (240) using the control signal (258) and the reset signal (250). . Device (104) according to claim 7 , in which the flip-flop (270) has a reset input INA+, a set input INB-, a non-negated output OUTB and a negated output OUTA, the reset input INA+ being connected to the non-negated output OUTB and the reset connection (254), the set input INB - is connected to the control terminal (252), and the negated output OUTA is connected to the transistor (278) for switching the transistor (278). Apparatus (104) according to any one of the preceding claims, wherein the enabling means (206) comprises a capacitor (280) connected to the reset terminal (254). Apparatus (104) according to any one of the preceding claims, wherein the power supply means (120) is in the form of a 5V voltage source. Device (104) according to one of the preceding claims, with a coupling device (112) which is designed to couple the protected antenna voltage (111) into the antenna connection (112) using the supply current (106). Antenna device with the following features: an antenna (102); an antenna amplifier (110); a device (104) according to any one of the preceding claims, wherein the antenna connection (112) of the device (104) is connected to the antenna amplifier (110) via an antenna line (108). A method of powering an antenna for a vehicle (100), the method comprising the steps of: providing (301) an intermediate stream (228) using an input stream (226); providing (303) an input voltage signal (230) representing a magnitude of the input current (226); providing (305) a supply current (106) for phantom power for an antenna amplifier (110) controlled by a switching signal (240) using the intermediate current (228); providing (307) an output voltage signal (242) representing a magnitude of the supply current (106); providing (309) a reset signal (250) using the input voltage signal (230) and the output voltage signal (242); and Providing (311) the switching signal (240) using a control signal (258) and the reset signal (250).

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