DE102016204806A1 - Circuit arrangement for detecting a circuit state at a circuit point - Google Patents

Abstract

The invention relates to a circuit arrangement (100) for detecting a circuit state at a circuit point (110), wherein the circuit point (110) is connected via a current source (120) to a ground terminal for connecting the circuit arrangement (100, 100 ') to ground A circuit point (110) is connected via a circuit part (130) to a potential terminal (133) for connecting the circuit arrangement (100) to a voltage source, and the circuit point (110) is connected to a first input (141) of a comparator (140), wherein a second input (142) of the comparator (140) is connected to a reference voltage source (143).

Description

The present invention relates to a circuit arrangement for detecting a circuit state at a circuit point and a method for detecting a circuit state at a circuit point by means of such a circuit arrangement as well as a computing unit and a computer program for its implementation.

State of the art

For example, loads can be provided in motor vehicles which can be controlled by low-side switches in output stages of control units. For example, such loads may be used for vehicle functions such as heating, front window heating, ventilation, air conditioning, interior lighting, etc. of the motor vehicle. In the event of a fault, however, such a load may be directly connected to ground, for example because of a short circuit, or the load may be defective, or a line to the load may be interrupted.

Disclosure of the invention

According to the invention, a circuit arrangement for detecting a circuit state at a circuit point and a method for detecting a circuit state at a circuit point by means of such a circuit arrangement as well as a computing unit and a computer program for carrying it out with the features of the independent claims are proposed. Advantageous embodiments are the subject of the dependent claims and the following description.

Advantages and preferred embodiments of the circuit arrangement according to the invention and the method according to the invention will become apparent from the following description in an analogous manner.

The circuit arrangement comprises a current source, a circuit part and a comparator. The circuit point is connected to a ground terminal via the current source and via the circuit part to a potential terminal for connecting the circuit arrangement to a voltage source. The circuit part may comprise one or more expedient elements, to which in particular a voltage drops. The circuit point is connected to a first input of the comparator, and a reference voltage source is connected to a second input of the comparator.

The current source of the circuit arrangement in particular delivers a current with a comparatively low current intensity, in particular below 1 mA, e.g. between 100 μA and 500 μA. A current source is generally to be understood as an active dipole which supplies an electrical current at its connecting points, the current strength of which, in particular, is independent of connected consumers. In particular, the current or its current does not depend, or at least scarcely, on the electrical voltage at the connection points. A current source has in particular opposite properties such as a voltage source which supplies an electrical voltage at its connection points, which is independent of connected consumers and does not or at least hardly depends on an electric current which is taken off at the connection points.

The circuit arrangement is particularly suitable for detecting whether a faulty switching state is present at the circuit point. Appropriately, by means of the circuit arrangement can be further distinguished between different faulty switching states, so it can be specifically recognized the specific error. For this purpose, the circuit arrangement can be connected to an element or a circuit which is to be checked for errors. The potential connection is for this purpose in particular connected to a voltage source.

Within the scope of the method, the circuit state at the circuit point is detected as a function of a voltage value applied to the first input of the comparator when the current source is switched on and / or when the current source is switched off. The error detection and error discrimination are thus performed in particular in dependence on the voltage value of the circuit point. In the comparator, this voltage value is compared with a reference voltage value of the reference voltage source. In particular, an error detection can be carried out when the power source is switched on and, when the power source is switched off, expediently an error distinction.

The invention provides a possibility to be able to carry out a fault detection as well as an error distinction with a structurally low-cost and cost-effective circuit arrangement. The circuit arrangement can be realized with comparatively few electrical elements and builds small. For the circuit arrangement, only one current source is expediently used; in particular, no regulation or control of voltage values or voltage sources is necessary. The circuit can easily existing in existing Diagnostic circuits are integrated to improve them and, where appropriate, to extend an error distinction.

Particularly advantageous is the circuit arrangement for an application in the automotive field. The circuit arrangement can advantageously be integrated into a control unit (or an end stage therein) of a motor vehicle. In particular, it can thus be recognized whether there is a fault of a load or a consumer in a motor vehicle electrical system. Due to the comparatively simple design of the circuit arrangement, the corresponding output stage for error detection / error discrimination can be kept simple and small. For example, as a load, a heater, front or rear window heating, ventilation, air conditioning, interior lighting, etc. of the motor vehicle can be monitored.

Advantageously, when the current source is switched on, it is checked in dependence on the voltage value applied to the first input of the comparator whether there is a first circuit state, which in particular corresponds to a fault-free circuit state. In the fault-free case, a voltage value which is expediently greater than the reference voltage value is applied to the circuit point. The comparator thus expediently outputs a high level at its output in this case. In the case of a high level at the comparator output when the current source is switched on, it is therefore expediently possible to unambiguously deduce a faultless circuit state.

Preferably, in the first, faultless circuit state, the circuit arrangement is connected to the circuit point via a load or via a load to a supply voltage source. The potential connection of the circuit arrangement can, for example, likewise be connected to this supply voltage source or else to another supply voltage source.

Since the load can be assumed to be comparatively low-impedance, in particular, and the (switched-on) current source expediently supplies a comparatively low current flow (for example below 1 mA), a comparatively high voltage value is present at the circuit point, in particular close to the operating voltage of the supply voltage source. This voltage value is expediently greater than the reference voltage value, so that when the current source is switched on and the voltage value at the circuit point is greater than the reference voltage value (ie at a high level at the output of the comparator), preferably the first faultless circuit state is concluded.

In the event of a faulty circuit state, however, the voltage value drops below the reference voltage value, so that the presence of an error can be detected. In particular, a low level is output at the comparator output.

When the current source is switched off, different faulty circuit states lead either to a comparatively high or to a comparatively low voltage value, which is correspondingly greater or smaller than the reference voltage value. Thus, when the current source is turned off, depending on the voltage value present at the first input of the comparator, it is preferably checked whether there is a second circuit state (corresponds in particular to a first faulty state) or a third circuit state (in particular a second faulty state).

When the current source is switched on and a voltage value at the circuit point below the reference voltage value, ie at a low level at the comparator output, it is advantageously recognized that the first circuit state is not present. In this case, the power source is preferably turned off and it is checked in the course of fault discrimination, whether the second circuit state or the third circuit state is present. The second and third circuit states each represent, in particular, a different error case.

Advantageously, by the circuit arrangement, a short circuit to ground and an open load (for example, because a load or a consumer is defective or because a line to the load or from the load to the supply voltage is interrupted) can be detected as a fault and distinguished from each other.

In the second circuit state, the circuit arrangement is preferably connected to ground at the node. In particular, there is a ground short circuit. In this case, a potential of 0 V or near 0 V is present at the circuit point, both when the current source is switched on and off. If the voltage value at the first comparator input is below the reference voltage value when the current source is switched off (low level at the comparator output), it is preferable to deduce a ground short circuit and thus the second circuit state.

In the case of a low level at the comparator output when the current source is switched off, it is thus possible in particular to unambiguously deduce a ground short circuit. In particular, a Such short circuit can thus also be detected without the voltage value of the circuit point is monitored when the power source is turned on.

In the third circuit state, the circuit point is preferably open. In particular, this represents the fault of the open load ("open load"), e.g. because the load is broken. The voltage value at the first comparator input is determined in this case expediently by current flow through or voltage drop at the voltage part when the power source is turned off. By appropriate choice of the components of the voltage part, a voltage value at the circuit point can be achieved in this case, which is above the reference voltage value.

However, a corresponding high level at the comparator output with the power source switched off does not necessarily indicate clearly such an error case. A high level when the current source is switched off can also occur, in particular, in the fault-free case, since in this case too, a voltage value in the vicinity of the battery voltage can be tapped off at the circuit point when the current source is switched off.

However, if the voltage value is less than the reference voltage value when the current source is switched on and if the voltage value is above the reference voltage value when the current source is switched off, it can advantageously be clearly recognized that the third circuit state exists. Preferably, it is thus checked in dependence on the voltage value with the current source switched on and in dependence on the voltage value with the current source switched off, whether the third circuit state is present.

According to a particularly preferred embodiment, the circuit part has at least one resistance element. The electrical resistance value of the at least one resistance element is expediently selected such that in the case of the third circuit state the voltage value at the circuit point is greater than the reference voltage value. Preferably, a comparatively high resistance value is selected, for example between 1 kΩ and 100 kΩ.

In particular, the values for this electrical resistance value, for the current intensity of the current supplied by the current source, and for the reference voltage are selected in dependence on one another in order to clearly distinguish between the first, second and third circuit states in the cases described above.

Advantageously, the circuit part alternatively or additionally have at least one diode to allow in particular in case of failure, a current flow from the voltage source connected to the potential terminal.

Alternatively or additionally, the circuit part may have a second current source. In particular, the potential connection in this case is not necessarily connected to a constant supply voltage source since a constant current can be provided by the second current source.

Preferably, the node is connected via at least one switching element to a ground terminal. For example, an electronic switch, in particular a transistor, may be used as such a switching element, e.g. a MOSFET or IGBT transistor. This switching element can be suitably provided for driving the load, in particular as a low-side switch. In the application in a motor vehicle, this switching element may be suitably integrated together with the circuit arrangement in a control unit of the motor vehicle.

Advantageously, the node is connected via a semiconductor element to a second potential terminal, e.g. via a diode or freewheeling diode. This second potential connection can also be connected, for example, to the supply voltage source or else to another supply voltage source. In particular, if the load connected to the supply voltage source is formed as an inductive load, the second potential terminal may be connected to the supply voltage source to enable free-wheeling by the diode after the inductive load has been switched off.

Preferably, the circuit point is also connected via a capacitor to a ground terminal, in particular for protection against electrostatic discharges (ESD).

An arithmetic unit according to the invention, e.g. a control device of a motor vehicle is, in particular programmatically, configured to perform a method according to the invention.

Also, the implementation of the method in the form of a computer program is advantageous because this causes very low costs, especially if an executive controller is still used for other tasks and therefore already exists. Suitable data carriers for providing the computer program are in particular magnetic, optical and electrical memories, such as e.g. Hard drives, flash memory, EEPROMs, DVDs, etc. It is also possible to download a program via computer networks (Internet, intranet, etc.).

Further advantages and embodiments of the invention will become apparent from the description and the accompanying drawings.

The invention is illustrated schematically by means of embodiments in the drawing and will be described below with reference to the drawing.

Brief description of the drawings

1 schematically shows a preferred embodiment of a circuit arrangement according to the invention, by means of which in the course of a preferred embodiment of a method according to the invention circuit states can be detected at a circuit point.

2 to 4 each show schematically a preferred embodiment of a circuit arrangement according to the invention in various circuit states, which can be detected by means of a preferred embodiment of a method according to the invention.

5 schematically shows a preferred embodiment of a method according to the invention as a block diagram.

6 schematically shows a preferred embodiment of another method according to the invention as a block diagram.

7 schematically shows a preferred embodiment of a circuit arrangement according to the invention, by means of which in the course of a preferred embodiment of a method according to the invention circuit states can be detected at a circuit point.

8th schematically shows a preferred embodiment of a circuit arrangement according to the invention, by means of which in the course of a preferred embodiment of a method according to the invention circuit states can be detected at a circuit point.

Embodiment (s) of the invention

In 1 a preferred embodiment of a circuit arrangement according to the invention is shown schematically and with 100 designated.

The circuit arrangement 100 is in the example shown in a control unit 101 a motor vehicle integrated. The control unit 101 is intended, inter alia, for controlling a rear window heating. For this purpose is a burden 111 provided, which via a potential connection 112 is connected to a supply voltage source, for example to a motor vehicle battery. Weight 111 For example, it may be formed as an inductive load. In particular, the load 111 comparatively low impedance and has a comparatively low electrical resistance of, for example, 1 Ω. Weight 111 is about a circuit point 110 with the control unit 101 and with the circuitry 100 connected.

The circuit arrangement 100 is preferably provided to detect if the load 111 is faultless or if there is a short circuit to ground or if the load 111 for example, due to a defect is open. For this purpose, the circuit arrangement 100 for detecting circuit states at the node 101 intended.

The circuit arrangement 100 has a power source 120 on, over which the circuit point 110 connected to ground via a ground connection. Furthermore, the circuit arrangement comprises 100 a circuit part 130 over which the circuit point 110 with a potential connection 133 connected is. At the potential connection 133 is the circuit arrangement 100 preferably connected to a supply voltage source. The circuit part 130 has a diode 132 as well as a high resistance element 131 with a comparatively high electrical resistance of, for example, 10 kΩ.

The circuit point 110 is still with a first entrance 141 a comparator 140 connected. This first entrance 141 is thus in particular at the circuit point 110 tapped voltage value supplied. A second entrance 142 of the comparator 140 is with a reference voltage source 143 connected. The comparator 140 thus compares the voltage value at the circuit point 110 with the reference voltage value of the reference voltage source 143 , Is the voltage value at the circuit point 110 greater than the reference voltage value is at an output 144 of the comparator to a high level. When the voltage value at the node 110 less than the reference voltage value is at the output 144 a low level. The comparator 140 and the power source 120 are realized, for example, as an ASIC (application specific integrated circuit).

The circuit point 110 is about a semiconductor element 151 in the form of a diode with a potential connection 152 connected to a freewheeling inductive load 111 to enable. The potential connection 152 is in particular also connected to the supply voltage source.

About a switching element 160 in the form of a MOSFET transistor is the circuit point 110 Connected to ground via a ground connection. The MOSFET transistor 160 is as a low-side switch for driving the load 111 intended. For protection against electrostatic discharges is the point of the circuit 110 over a capacitor 170 Connected to ground via a ground connection.

The control unit 101 is, in particular programmatically, set up to carry out a preferred embodiment of a method according to the invention and in the course of which circuit states at the circuit point 110 by means of the circuit arrangement 100 to recognize.

Such a preferred embodiment of the method according to the invention is in 5 schematically illustrated as a block diagram and will be described below with reference to the 2 to 3 explains in which the circuit arrangement 100 each analogous to 1 at different circuit states at the node 110 is shown. Identical reference numerals in the figures indicate the same or equivalent elements.

First, in the course of the procedure, an error detection 301 in order to know in general whether there is an error at all. For this purpose, the power source 120 in step 300 switched on.

In step 310 is the power source 120 turned on and in response to the at the first input 141 of the comparator 140 applied voltage value is checked whether a first circuit state is present or not.

If the voltage value is above the reference voltage value, it is at the output 144 the comparator goes high and it gets in step 311 recognized that the first circuit state and thus no error exists.

In 2 this first, faultless circuit state is shown schematically. The circuit point 110 is about the faultless load 111 with the potential connection 112 and thus connected to the supply voltage source.

A current flow in this circuit state is indicated by the arrow 201 indicated. Because the load 111 is comparatively low impedance, falls at the load 111 only a comparatively very low voltage and the tapped off at the circuit point voltage value substantially corresponds to the voltage value of the supply voltage source, which is greater than the reference voltage value of the reference voltage source 143 ,

If in the course of review in step 310 of the method according to 5 with the power source switched on 120 at the entrance 141 however, a voltage value lower than the reference voltage value is applied in step 312 the presence of an error detected.

In this case, there could be a second circuit state in which a short circuit to ground occurs, or there may be a third circuit state in which the load 111 defective or open.

In 3a this second circuit state is shown schematically. Weight 111 is due to a short circuit 220 connected directly to ground. A current flow in this case is indicated by the arrow 202 shown. In this case, it is at the circuit point 110 a voltage value near 0 V, which is lower than the reference voltage value.

In 3b the third circuit state is shown schematically. Weight 111 has a defect in this case, for example 230 on. The current flow in this case is indicated by the arrow 203 indicated. Due to the comparatively high electrical resistance of the resistive element 131 falls a relatively high voltage at the voltage part 130 off, leaving at the first entrance 141 a comparatively low voltage value is applied, which lies below the reference voltage value.

In order to be able to recognize which of these two error cases is present, in the course of the method according to 5 an error distinction 302 carried out. For this purpose, in step 313 the power source 120 switched off.

In step 320 is the power source 120 turned off and depending on the at the first input 141 of the comparator 140 applied voltage value is checked whether the second circuit state or the third circuit state is present.

If the at the entrance 141 applied voltage value is below the reference voltage value, in step 322 recognized that the second circuit state is present.

This case is in 4a shown. The switched off power source 120 is by reference numerals 240 represented and the current flow in this case by the arrow 204 , As already in relation to 3a explained in this case lies at the circuit point 110 a voltage value near 0 V, which is lower than the reference voltage value.

If in the course of review in step 320 of the method according to 5 with the power source switched off 120 at the entrance 141 a voltage value which is greater than the reference voltage value, is in step 321 the third circuit state detected.

This case is in 4b shown, the current flow in this case by the arrow 205 is shown. In this case, only leakage currents flow 205 over the diode 151 and on the circuit part 130 , The leakage currents 205 continue to flow through the MOSFET 160 to mass. At the entrance 141 In this case, a voltage value which essentially corresponds to the value of the supply voltage at the potential connection is present 133 corresponds to and is greater than the reference voltage value.

According to a preferred embodiment of the method according to the invention, the checks 310 and 320 also be inverted. Such a preferred embodiment is shown schematically in FIG 6 shown as a block diagram.

This will be the power source 120 according to step 313 ' analogous to step 313 first off and in step 320 ' becomes analogous to step 320 the voltage value at the input 141 compared with the reference voltage value.

If the voltage value is less than the reference voltage value, in step 322 ' analogous to step 322 the second circuit state, that is, the short circuit detected to ground. With the power source switched off 120 and low level at the comparator output 144 can be clearly deduced to the second circuit state.

If the voltage value is higher than the reference voltage value, however, it can be switched off with the power source switched off 120 can not be clearly deduced to the third circuit state, as well as the error-free, first circuit state with switched off power source 120 a high level at the output 144 can rest against the comparator.

Therefore, the power source becomes 120 in this case in step 300 ' switched on and with the power source switched on 120 will be in step 310 ' analogous to step 310 the one at the entrance 141 applied voltage value checked.

If the voltage value is lower than the reference voltage value, in step 321 ' analogous to step 321 the third circuit state (open load) detected. However, if the voltage value is higher than the reference voltage value, in step 311 ' analogous to step 311 the first, faultless circuit state detected.

In 7 is a further preferred embodiment of the circuit arrangement according to the invention analogous to the 1 to 4 shown schematically and with 100 ' designated.

According to a preferred embodiment, the circuit part 130 ' in this case no resistance element and no diode, but a second current source 134 over which the circuit point 110 with the potential connection 133 is connected to which in particular also the supply voltage source is connected. The second power source 134 is together with the first power source 120 and the comparator on the ASIC 102 integrated.

It is also possible, for example, to operate a plurality of circuit arrangements by means of such a second current source integrated in the ASIC, by means of which a load of the motor vehicle can be checked for faults in each case.

Such a case is schematically shown in FIG 8th shown. By means of in the ASIC 102 ' integrated power source 134 becomes a first circuit arrangement 100A and a second circuit arrangement 100B operated, by means of which a load 111A respectively. 111B of the motor vehicle can be checked for errors. The circuit arrangements 100A . 100B are each formed as preferred embodiments of the circuit arrangement according to the invention and on the respective load 111A . 111B with a potential connection 112A . 112B or connected to the supply voltage source.

Analogous to that in the 1 to 4 The circuit arrangements also each have a circuit point 110A . 110B , a power source 120A . 120B , a diode 151A . 151B a potential connection 152A . 152B , a transistor 160A . 160B and a comparator 140A . 140B with inputs 141A . 141B . 142A . 142B , a reference voltage source 143A . 143B and an exit 144A . 144B on.

A circuit part of the first circuit arrangement 100A is through the potential connection 133 and the power source 134 as well as through a diode 132A and a resistive element 131A educated. Analogously, a circuit part of the second circuit arrangement 100B through the potential connection 133 and the power source 134 as well as through a diode 132B and a resistive element 131B educated.

Claims (18)

Circuit arrangement ( 100 . 100 ' ) for detecting a circuit state at a node ( 110 ), in which the circuit point ( 110 ) via a power source ( 120 ) having a ground connection for connecting the circuit arrangement ( 100 . 100 ' ) is connected to ground, the circuit point ( 110 ) via a circuit part ( 130 ) with a potential connection ( 133 ) for connecting the circuit arrangement ( 100 . 100 ' ) is connected to a voltage source, and the circuit point ( 110 ) with a first input ( 141 ) of a comparator ( 140 ), a second input ( 142 ) of the comparator ( 140 ) with a reference voltage source ( 143 ) connected is. Circuit arrangement ( 100 . 100 ' ) according to claim 1, wherein the circuit part ( 130 ) at least one resistance element ( 131 ) and / or at least one diode ( 132 ) and / or a second power source ( 134 ) having. Circuit arrangement ( 100 . 100 ' ) according to claim 1 or 2, wherein the node ( 110 ) via at least one switching element ( 160 ) having a ground connection for connecting the circuit arrangement ( 100 . 100 ' ) is connected to ground. Circuit arrangement ( 100 . 100 ' ) according to one of the preceding claims, wherein the circuit point ( 110 ) via a capacitor ( 170 ) having a ground connection for connecting the circuit arrangement ( 100 . 100 ' ) is connected to ground. Circuit arrangement ( 100 . 100 ' ) according to one of the preceding claims, wherein the circuit point ( 110 ) via a semiconductor element ( 151 ) with a second potential connection ( 152 ) connected is. Circuit arrangement ( 100 . 100 ' ) according to one of the preceding claims, which is incorporated in a control unit ( 101 ), in particular integrated in a control unit of a motor vehicle. Circuit arrangement ( 100 . 100 ' ) according to one of the preceding claims, which is connected to the circuit point ( 110 ) via a load ( 111 ) with a supply voltage source ( 112 ) connected is. Method for detecting a circuit state at a node ( 110 ) by means of a circuit arrangement ( 100 . 100 ' ) according to one of the preceding claims, wherein, depending on one at the first input ( 141 ) of the comparator ( 140 ) voltage level when the power source is switched on and / or switched off ( 120 ) the circuit state at the node ( 110 ) is recognized. Method according to Claim 8, in which, depending on the first input ( 141 ) of the comparator ( 140 ) voltage level when the power source is switched on ( 120 ) is checked, whether a first circuit state exists ( 310 ). The method of claim 9, wherein when the voltage value is greater than a reference voltage value when the power source is turned on, it is detected that the first circuit state exists ( 311 ). Method according to one of claims 8 to 10, wherein, depending on the at the first input ( 141 ) of the comparator ( 140 ) voltage level when the power source is switched off ( 120 ) is checked to see if there is a second circuit state ( 320 ). The method of claim 11, wherein when the voltage level is OFF when the power source is turned off ( 120 ) is below a reference voltage value, it is detected that the second circuit state is present ( 321 ). Method according to one of claims 8 to 12, wherein, depending on the at the first input ( 141 ) of the comparator ( 140 ) voltage level when the power source is switched on ( 120 ) and depending on the at the first input ( 141 ) of the comparator voltage value with switched off power source ( 120 ) is checked, whether a third circuit state exists ( 320 . 310 ). The method of claim 13, wherein when the voltage level is switched on ( 120 ) is below a reference voltage value and if the voltage value is 120 ) is above the reference voltage value, it is detected that the third circuit state is present ( 322 ). Method according to one of claims 8 to 14, wherein in the first circuit state, the circuit arrangement ( 100 . 100 ' ) at the node ( 110 ) via a load ( 111 ) with a supply voltage source ( 112 ) and / or in the second circuit state, the circuit arrangement ( 100 . 100 ' ) at the circuit point ( 110 ) is connected to ground ( 220 ) and / or in the third circuit state, the circuit point ( 110 ) is open. Arithmetic unit ( 101 ), which is adapted to perform a method according to any one of claims 8 to 15. Computer program comprising a computing unit ( 101 ) to perform a method according to any one of claims 8 to 15, when it on the arithmetic unit ( 101 ) is performed. Machine-readable storage medium with a computer program stored thereon according to claim 17.

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