DE102018133546A1 - Combined Hall sensor / coding interface with integrated protection function - Google Patents

Abstract

Device for coding several similar components in a system, the device comprising a control unit; a first functional unit for providing a first voltage for reading out a coding, the first functional unit comprising: a first switch which is coupled to a first input and can be controlled by this, by the control unit, with the second switch using the first switch via a first Resistance with an electrically conductive connection is conductively connectable; and a third input for detecting short circuits to ground, which is coupled to the control unit; a second functional unit for reading a coding bridge or an external sensor by means of the voltage provided by the first functional unit, the electrically conductive connection conductively connecting the first functional unit and the second functional unit, the second functional unit comprising a second switch which is coupled to a fourth input and by this, by the control unit, is controllable, the second switch, when activated by the control unit, via the fourth input, electrically connecting the electrically conductive connection to ground via a second resistor; and a fifth input which is coupled to the coding bridge or the external sensor.

Description

Field of the Invention

The invention relates to a combined Hall sensor / coding interface comprising a first and a second functional unit, the first functional unit being designed to provide a voltage for coding and the second functional unit being designed to read a coding bridge.

background

In many areas, especially in automotive applications, several identical components are used within one system. However, the components often differ in their operating mode. For example, two identical motors are used in a vehicle to fold up the exterior mirrors. The two motors have to turn in opposite directions. However, both motors receive the same control signal. In order to keep the manufacturing effort low, it is desirable to use the same control software in all components. To this end, it is known to determine the behavior of the components via electrical bridges between the ground connection and signal connections provided specifically in the components. For this purpose, the control software of the components measures the voltage applied to the signal connection. This voltage is the measure for the control command to be executed. It can be read out either once or cyclically. The interface between the components and, for example, the wiring harness of a car is conventionally designed so that the components in a certain direction, i.e. must be installed with a certain plug connection direction. This increases the assembly effort. The invention therefore makes it its task to provide an interface by means of which the assembly effort can be reduced. Another object of the invention is to provide an interface that can be used flexibly, i.e. that cannot only be used to connect a specific component.

Brief description of the invention

This object is achieved by the invention specified in the independent claims. Advantageous configurations can be found in the subclaims.

According to the invention, a device for coding a plurality of similar components in a system is provided, the device comprising: a control unit;
a first functional unit for providing a first voltage for reading a coding, the first functional unit comprising: a first switch which
coupled to a first input and controllable by this, by the control unit, with the second switch being able to be conductively connected to an electrically conductive connection via a first resistor by means of the first switch; and
a third input for detecting short circuits to ground, which is coupled to the control unit; a second functional unit for reading a coding bridge or an external sensor by means of the voltage provided by the first functional unit, the electrically conductive connection conductively connecting the first functional unit and the second functional unit. The second functional unit comprises: a second switch, which is coupled to a fourth input and can be controlled by this, by the control unit, the second switch, when activated by the control unit, via the fourth input to conduct the electrically conductive connection via a second resistor Earth connects; and
a fifth input, which is coupled to the coding bridge or the external sensor.

The first switch preferably comprises a first transistor and a second transistor, the first transistor being coupled to the first input. The first switch can be controlled by the control unit via the serious input. Furthermore, the second transistor can be controlled by the first transistor. By means of the second transistor, the second input can be conductively connected to the electrically conductive connection via the first resistor.

Furthermore, in some configurations it is preferred that the second switch comprises a third transistor or is formed by the third transistor.

In some advantageous configurations, it is provided that the electrically conductive connection comprises a jumper.

In some configurations, the device particularly preferably thus comprises: a control unit, in particular a microcontroller; a first functional unit for providing a first voltage for reading out a coding, the first functional unit comprising: a first transistor which is coupled to a first input and can be controlled thereby by the control unit; and a second transistor which can be controlled by the first transistor and by means of which a second input can be conductively connected to a jumper via a first resistor; and a third input for detecting short circuits against Ground coupled to the control unit; a second functional unit for reading a coding bridge or an external sensor by means of the voltage provided by the first functional unit, the jumper connecting the first and the second functional unit in a conductive manner, the second functional unit comprising: a third transistor coupled to and through a fourth input , can be controlled by the control unit, the third transistor, when activated by the control unit, via the fourth input, connecting the jumper via a second resistor to ground; and a fifth input, which is coupled to the coding bridge or the external sensor.

The implementation of the coding interface as two separate functional units ensures that each functional unit, and therefore the entire coding interface, is protected against short circuits that can occur as a result of improper installation. The first functional unit provides the readout voltage and is able to detect a short circuit between the second input in the jumper through the third input and, if necessary, to switch off the current via the first and second transistor. The size of the first resistor, through which the short-circuit power is delivered, can thus be kept low. The first resistor can also be designed to have a relatively low resistance. In conventional arrangements, the resistance must namely be able to dissipate high powers in the event of a short circuit, i.e. its design must be appropriately robust and therefore large. In addition to the large design, this is also associated with higher costs. The advantage of the first functional unit is therefore to be able to detect short circuits through the control unit and to switch off currents. The first resistor can therefore be designed to be relatively small. It only has to be large enough to withstand a short-circuit peak, i.e. a current peak that occurs in the event of a short-circuit.

In one embodiment of the invention, the second functional unit comprises a sixth input for reading back the voltage, by the control unit, which drops over the second resistor. A voltage falling across the second resistor is read back through the sixth input by the control unit. As a result, short circuits between the supply voltage and ground can be detected.

In one embodiment of the invention, the first functional unit and / or the second functional unit each have a circuit for protecting the control unit against transient overvoltages, the third and sixth inputs in particular being protected against overvoltages by means of the circuits.

The second functional unit is thus protected against short circuits by the sixth input in the same way as the first functional unit, the short circuits occurring between a supply voltage and ground. The fifth input can be used to read coding bridges or external sensors. The coding interface can thus be used flexibly.

In one embodiment of the invention, the control unit is designed to switch conductive via the first input, the second transistor, by providing a high level; and / or read back a supply voltage via the second input; and / or to detect short-circuits of the supply voltage against a ground connection of the first functional unit via the third analog input, the detection comprising measuring the voltage drop across the first resistor, a critical value of the voltage being stored in the control unit and the control unit being designed for this purpose is to provide a low level at the first input when the critical value is undershot in order to switch off the first transistor; and / or to switch off the device via the fourth input. The shutdown can take place in particular by applying a low level, through a digital output of the control unit, to the fourth input.

In one embodiment of the invention, the first resistor is designed to have a low resistance, in particular the resistor being an SMD 1206 Resistance is. The low-resistance design guarantees a small design. SMD resistors are also very inexpensive.

In one embodiment of the invention, all inputs are high-impedance and peak-capable. This increases intrinsic safety.

In one embodiment of the invention, the second functional unit either has a third resistor for reading out a coding bridge, or an external sensor, in particular a Hall sensor, can be connected via the fifth input, the third resistor being dispensed with. The third resistor acts as a pull-up if the first and the second functional unit are connected via the jumper and a coding bridge is connected to the fifth input. If an external sensor, e.g. if a Hall sensor is to be read, the third resistor is not equipped.

In one embodiment of the invention, the sixth input is connected to the control unit via an analog-digital converter, and if none external sensor is connected, the additional voltage drop across the third resistor can be measured at the sixth input. This serves for short-circuit detection.

In one embodiment of the invention, the coding interface comprises at least one parasitic dirt shunt resistor, in particular wherein the at least one dirt shunt resistor has a minimum value of 5 kQ. The dirt shunt resistors are used to model conductive dirt in the coding interface and the associated change in the conductance values. In order to prevent signal levels from being falsified by the parasitic resistances, the impedance of the measuring device is significantly lower than that of the dirt shunt resistors.

According to a further aspect of the invention, a method for operating a combined coding interface, in particular in an automotive system with several identical components, is provided, the method comprising: providing, by a first functional unit, a readout voltage to a second functional unit, reading out, by the second functional unit , a coding bridge or an external sensor. The separation of the two functional units increases the intrinsic safety of the coding interface by means of a separate short-circuit control. An interface operated in this way therefore has an integrated protective function.

In some embodiments of the method, providing comprises: outputting, by a control unit, a high-level signal at a first input, which is connected to a first switch, switching the first switch by a current flow from a second input to an electrically conductive one Enable connection; measuring, by the control unit, a voltage dropping across a first resistor, the first resistor being arranged between the second input and the electrically conductive connection; and the recognition, by the control unit, of a critical value of the voltage, a low-level signal being output to the first switch by the control unit when the voltage falls below the critical value; and the first switch switching off the first functional unit as a result of the low-level signal.

The first switch preferably comprises a first transistor and a second transistor, the first input being connected to the first transistor; and wherein the low level signal is output to the first transistor of the first switch; and wherein the first transistor switches off the first functional unit as a result of the low-level signal. The method particularly preferably further comprises: switching the first switch by switching the second transistor, by means of the first transistor, in order to enable the current to flow from the second input to the electrically conductive connection.

In some advantageous refinements of the method, the electrically conductive connection comprises a jumper.

In one embodiment of the method according to the invention, the provision thus comprises the output, by a control unit, of a high level at a first input which is connected to a first transistor, the switching of a second transistor by means of the first transistor to a current flow from a second input to a jumper to enable, by the control unit, measuring a voltage drop across a first resistor, the first resistor being arranged between the second input and the jumper, and recognizing, by the control unit, a critical value of the voltage, whereby at If the control unit drops below the critical value of the voltage, a low-level signal is output to the first transistor; and switching off the first functional unit by the first transistor as a result of the low-level signal. As a result, the control unit can detect short circuits and interrupt the corresponding current flow.

In one embodiment of the method according to the invention, the reading comprises the provision of a third resistor for reading the coding bridge and the measurement by the control unit of the voltage dropping across the third resistor, the measurement being carried out via a sixth input connected to an analog-digital converter of the control unit connected is.

In one embodiment of the method according to the invention, switching off the coding interface comprises providing a high level at a fourth input, as a result of which, by switching a third transistor, a fifth input is connected to ground. As a result, the coding interface can be switched off completely and does not load a voltage source, in particular a battery in an automobile.

Figure list

• Die Zeichnung 1 eine beispielhafte Ausführungsform einer Schaltung eines Codierinterfaces gemäß der Erfindung.

An exemplary embodiment of the invention is described in more detail below with reference to the accompanying drawings. It shows:

• The drawing 1 an exemplary embodiment of a circuit of a coding interface according to the invention.

Figure description

The 1 shows an exemplary embodiment of a circuit of a coding interface 1 . The coding interface 1 comprises a first functional unit 2nd and a second functional unit 3rd . The first functional unit 2nd has a first transistor 4th and a second transistor 5 on. The first transistor 4th is through a first entrance 6 controlled. To limit the base current on the first transistor 4th is a limiter resistor in the example 19th between the base of the first transistor 5 and the first entrance 6 intended. The first entrance 6 is connected to a control unit (not shown), preferably a microcontroller, and can be controlled by the control unit. The first transistor 4th serves as a level shifter for controlling the second transistor 5 . The second transistor 5 is on the emitter side with a second entrance 7 connected. The second entrance 7 is connected to the control unit. The second transistor 5 is on the collector side with a first resistance 8th connected across the when the second transistor 5 through the first transistor 4th is turned on, a current flow through the first resistor 8th to a jumper 9 is made possible. The one above the first resistance 8th the voltage drops through the control unit via a third input 10 measured. The first functional unit 2nd has other wiring elements 11 to protect the inputs against transient overvoltages. For example, the wiring elements 11 a suppressor diode D4 (English: Transient Voltage Suppressor Diode, TVS Diode for short). The second functional unit 3rd is over the jumper 9 with the first functional unit 2nd connected and comprises a third transistor 12th . The third transistor 12th is on its base side through a fourth entrance 13 controllable by the control unit, the fourth input 13 is connected to a digital output of the control unit. To limit the base current at the third transistor 12th is again a limiter resistor in the example 19th between the base of the third transistor 12th and the fourth entrance 13 intended. The second functional unit 3rd includes a fifth entrance 14 , which is used to connect a coding bridge or an external sensor (both not shown). Between the jumper 9 and the collector side of the third transistor 12th is a second resistance 15 arranged. This has an order of magnitude of approx. 100Q. The second functional unit 3rd also includes a sixth input 16 and a third resistance 17th . The third resistance 17th is optional and only to be provided if at the fifth entrance 14 a coding bridge is connected. If at the fifth entrance 14 If an external sensor is connected, the third resistor is omitted 17th . The sixth entrance 16 is connected to the control unit and is used to read back the voltage across the second resistor 15 falls off. The second functional unit in turn has circuit elements 11 to prevent transient overvoltages like the first functional unit 2nd on. The wiring elements 11 can be the same components as those of the wiring elements 11 the first functional unit 2nd include. For example, a suppressor diode can be used, as in the example D6 be provided. There is also a resistor in the example R15 , a zener diode D7 , as well as a capacitor C9 intended. Between the first functional unit 2nd and the second functional unit 3rd are dirt shunt resistors 18th intended.

When operating the coding interface 1 , in particular in an automotive environment, by the first functional unit 2nd the voltage required to read the coding bridge is made available. To do this, the control unit applies a high-level signal to the first input 7 on. The first transistor acting as a level converter 4th This turns on (npn). The current that flows through the first transistor as a result of the switch-on becomes that at the base of the second transistor 5 applied potential is smaller than that at the emitter of the second transistor 5 applied potential. The second transistor 5 is switched on. About the first resistance 8th is that at the second entrance 7 potential present at the jumper 9 or there can be a current from the second input 7 to the jumper 9 flow. The first transistor 4th is needed because that at the first entrance 6 applied output signal of the control unit has too low a voltage to the at the second transistor 5 applied higher voltage between the second input 7 and the jumper 9 to switch directly. To the first functional unit 2nd In the event of a short circuit between the jumper and ground to protect against damage, the first resistor 8th be selected so that the flowing current is limited to a level that can be tolerated indefinitely. At the same time, the voltages and currents required for normal operation must not be undercut. The first resistance 8th is therefore to be interpreted with low resistance. In the event of a short circuit, this results in a high power loss at the first resistor 8th . As a result, the large designs of the first resistor required 8th to avoid, the current flowing in the event of a short circuit may only be brief. Therefore, the short circuit between the jumper 9 and ground recognized by the control unit and that on the jumper 9 applied voltage can be switched off. To do this, the control unit is connected via the analog third input 10 with the first functional unit 2nd connected and measures the voltage there. In the event of a short circuit, the first resistor drops 8th a significantly higher voltage than in normal operation. Falls below that at the third entrance 10 The control unit outputs a voltage defined by the control unit and a value stored in the control unit via the first input 6 a low level signal and switches over the first transistor 4th , by means of the second transistor 5 the current through the first resistor 8th from.

When operating the coding interface 1 is from the second functional unit 3rd , by means of the first functional unit 2nd provided voltage, the fifth input 14 , the coding bridge, or alternatively the external sensor. The readout voltage is above the third resistor 17th at the sixth exit 16 on. The sixth exit 16 is connected to an analog-digital converter of the control unit. The control unit uses the analog-digital converter to measure the sixth output 16 applied voltage. This can cause short circuits from a supply voltage VBat to the jumper 9 can be detected. Is by applying a high level signal to the fourth input 13 the third transistor 12th switched on, this can be done at the fifth input 14 applied potential across the second resistor 15 be connected to ground. One by the dirt shunt resistors 18th Generated potential is after switching on the third transistor 12th collapse heavily, whereby the control unit is able to recognize this state. Is the potential through a 0Ω coding bridge at the fifth input 14 determined, the potential also changes by switching on the third transistor 12th Not. If an external sensor is to be connected and read, the third resistor is used 17th not equipped and the external sensor to the fifth input 14 connected. On the other hand, is at the fourth entrance 13 a low level signal is applied, so we the third transistor 12th switched non-conductive. This shuts down the device. In particular, it can be provided that for switching off at the first input 6 and the fourth entrance 13 a low-level signal is applied in each case. To switch off the device, it can further be provided that a low level is applied to all inputs of the circuit which are fed by the control unit, for example a microcontroller. Thus, for example, when used in an automobile, the vehicle battery can be relieved by switching off the device after reading out the coding.

Reference list

1

Coding interface

2nd

first functional unit

3rd

second functional unit

4th

first transistor

5

second transistor

6

first entrance

7

second entrance

8th

first resistance

9

electrically conductive connection / jumper

10th

third entrance

11

Wiring elements

12th

third transistor

13

fourth entrance

14

fifth entrance

15

second resistance

16

sixth entrance

17th

third resistance

18th

Dirt shunt resistors

19th

Limiter resistors

D2, D4

Wiring elements (TVS diodes)

GND

Dimensions

Claims (19)

Device for coding several similar components in a system, the device comprising: a control unit; a first functional unit (2) for providing a first voltage for reading a coding, the first functional unit (2) comprising: a first switch, which is coupled to a first input (6) and through this, by the control unit, is controllable, with the first switch being able to conductively connect a second input (7) via a first resistor (8) to an electrically conductive connection (9); and a third input (10) for detecting short circuits to ground (GND), which is coupled to the control unit; a second functional unit (3) for reading a coding bridge or an external sensor by means of the voltage provided by the first functional unit (2), the electrically conductive connection (9) conductively connecting the first functional unit (2) and the second functional unit (3), the second functional unit (3) comprising: a second switch, which is coupled to a fourth input (13) and can be controlled by this, by the control unit, the second switch, when activated by the control unit, via the fourth input (13), the electrically conductive connection (9) via a second Resistor (15) connects to ground (GND); and a fifth input (14), which is coupled to the coding bridge or the external sensor. Device after Claim 1 , wherein the first switch comprises a first transistor (4) and a second transistor (5), and wherein the first transistor (4) is coupled to the first input (6) and can be controlled thereby by the control unit; and wherein the second transistor (5) can be controlled by the first transistor (4) and by means of which the second input (7) can be conductively connected to the electrically conductive connection (9) via the first resistor (8). Device after Claim 1 or 2nd , wherein the second switch is a third transistor (12). Device after Claim 2 or 3rd , wherein the electrically conductive connection (9) comprises a jumper. Device according to one of the Claims 1 to 4th , wherein the second functional unit (3) comprises a sixth (16) input for reading back the voltage that drops across the second resistor (15) by the control unit. Device according to one of the preceding claims, wherein the first functional unit (2) and / or the second functional unit (3) each have a circuit (11) for protecting the control unit against transient overvoltages, in particular the third input (10) and the sixth input ( 16) are protected against overvoltages by means of the circuits (11). Device according to one of the Claims 2 to 6 The control unit is designed to: switch the second transistor (5) to conductive via the first input (6) by providing a high-level signal; and / or read back a supply voltage via the second input (7); and / or to detect short circuits of the supply voltage to a ground connection of the first functional unit (2) via the third analog input (10), the detection comprising measuring the voltage drop across the first resistor (8), a critical value in the control unit the voltage is stored and the control unit is designed to provide a low-level signal at the first input (6) when the critical value is undershot in order to switch off the first transistor (4); and / or to switch off the device via the fourth (13) input. Device after Claim 7 , wherein the device is switched off via the application of a low-level signal by a digital output of the control unit at the fourth (13) input. Device according to one of the preceding claims, wherein the first resistor (8) is designed with low resistance. Device according to one of the preceding claims, wherein all inputs are high-impedance. Device according to one of the preceding claims, wherein the second functional unit (3) either has a third resistor (17) for reading a coding bridge, or an external sensor can be connected via the fifth input (14), in which case the third resistor (17) is waived. Device after Claim 5 , wherein the sixth input (16) is connected to the control unit via an analog-digital converter, and if no external sensor is connected, the voltage drop across the third resistor (17) can also be measured at the sixth input (16). Device according to one of the preceding claims, comprising at least one parasitic dirt shunt resistor (Rs1, Rs2), in particular wherein the at least one dirt shunt resistor (Rs1, Rs2) has a minimum value of 5kQ. Method for operating a combined coding interface, in particular in an automotive system with several identical components, the method comprising: Providing, by a first functional unit (2), a readout voltage to a second functional unit (3); Read out by the second functional unit (3), a coding bridge or an external sensor. Procedure according to Claim 14 , the providing comprising: outputting, by a control unit, a high-level signal at a first input, which is connected to a first switch, switching the first switch to a current flow from a second input (7) to an electrically conductive connection to enable; Measuring, by the control unit, a voltage dropping across a first resistor (8), the first resistor (8) being arranged between the second input (7) and the electrically conductive connection (9); and recognizing, by the control unit, a critical value of the voltage, a low-level signal being output to the first switch by the control unit when the critical value of the voltage is undershot; and switching off the first functional unit by the first switch as a result of the low-level signal. Procedure according to Claim 15 , wherein the first switch comprises a first transistor (4) and a second transistor (5), the first input (6) being connected to the first transistor (4); and wherein the low level signal is output to the first transistor (4) of the first switch; and wherein the first transistor (4) switches off the first functional unit (2) as a result of the low-level signal; and the method further comprises: switching the first switch by switching the second transistor (5), by means of the first transistor (4), to allow the current to flow from the second input (7) to the electrically conductive connection (9); Procedure according to one of the Claims 15 or 16 , wherein the electrically conductive connection comprises a jumper. Procedure according to one of the Claims 14 to 17th , wherein the reading comprises: providing a third resistor for reading a coding bridge; Measuring the voltage drop across the third resistor by the control unit, the measurement taking place via a sixth input (16) which is connected to an analog-digital converter of the control unit. Procedure according to Claim 18 comprising switching off the coding interface by the control unit, the switching off comprising providing a high-level signal at a fourth (13) input, whereby a fifth (14) input is connected to ground by switching a third transistor.

Images