DE19917819A1 - Switch query with wake-up circuit - Google Patents

Abstract

The invention relates to a circuit arrangement for detecting switching states of at least one actuating means (S1, S2, S3), in particular switches for activating motor vehicle electronics, the circuit arrangement generating a wake-up signal (Y, 2a3) when at least one actuating means (S1 , S2, S3) changes from a first defined switching state to a second defined switching state, the circuit arrangement being designed such that it generates the wake-up signal (Y, 2a3) even when the second switching state changes to the first switching state. The invention further relates to a method for this, wherein the at least one actuating means (S1, S2, S3) with at least two switching states is assigned a different value (0, + 12V) to each switching state, and each change in the values (0-12V, 12- 0V) into a wake-up signal (Y, 2a3).

Description

The invention relates to a circuit arrangement for detection switching states of at least one actuating means, in particular switches for activating a motor vehicle electronics.

Such circuit arrangements are used in the motor vehicle technology used to depend on different Switches or locks, such as a door contact, trunk lock, ignition lock, fuel filler cap etc., and their respective switching states, depending to control functions of the vehicle electrics.

Such circuit arrangements have green energy saving the one active mode, in which the respective Switching states of the individual switches or locks can be detected, and a sleep mode (Sleep Mo de) in which the energy supply versus active mode is mostly reduced. In this sleep mode only the on occurs when a certain action is monitored and, in the case of on occurs, a wake-up signal is generated to the circuit order to switch to active mode.

In DE 44 14 734 C2, for example, the actuator the handle on the driver's door in a corresponding manner supervised.

In practice, however, operator errors, such as an accidental prolonged opening of a door with over monitored door contact, or malfunction of switches, for Example of the switch getting stuck, so that the respective switch or contacts in an undesirable Switching state remain and no longer to generate a Wake-up signal can be used.  

The invention is therefore based on the object of a scarf tion arrangement and a method for detecting Schaltzu stands of at least one actuating means, in particular Switch to activate automotive electronics create that also generate a wake-up signal such operating errors and misconduct guaranteed.

This object is achieved by a circuit solved with the features of claim 1. A procedure ren for detecting switching states of at least one Be agent is specified in claim 9.

Any change in the switching state ei nes or more switches monitored so that an operator such as an accidentally open one Door, after closing a change in the switching state of the door contact and generates a wake-up signal. Exactly so a wake-up signal can be generated if despite ord proper closing of the door the door contact in front current switching state remains hanging (open door) and through repeated actuation is released so that he is closing the Door signals.

According to one embodiment of the invention, the wake-up Signal by changing a switching state of little at least two switches are generated independently. This can ensure that even with one complete failure or permanent malfunction switch still generates a wake-up signal safely can be.

In a further embodiment of the invention, the rest current in sleep mode limited to a value close to zero. In active mode, instead of a perma, to save energy nent energy supply a switched or pulsed energy  Power supply used and the energy consumption advantageous t be reduced.

This advantageous effect also occurs without monitoring one any change in the switching state at least one Switch on, but is only in the context of a sol Chen circuitry described. But it is also think bar, the energy consumption of a conventional circuit order in a sleep mode in a corresponding manner to one Limit value close to zero.

Further advantageous embodiments of the invention result itself from the subclaims.

The invention is described below with reference to the drawing illustrated embodiments explained in more detail. In the Show drawing:

Figure 1 is a block diagram of the general operation of a circuit arrangement according to the invention.

FIG. 2 is a circuit diagram of the circuit arrangement for realizing a block diagram according to FIG. 1; and

Fig. 3 is a schematic signal flow diagram of Signalver run in a circuit according to FIG. 2.

The circuit arrangement of Fig. 1 has to monitor input signals X1, X2 and X3 on two pulse shaper I1 and I2 and a connecting unit D1. The signals X1, X2 and X3 are independent of one another at the inputs of the connection unit D1, which outputs any change in an input signal X1, X2 or X3 as signal Xe.

The output of the connection unit D1 is with both inputs the pulse shaper I1 and I2 connected so that the signal Xe both at the input of the pulse shaper I1 and at the input  of the pulse shaper I2 is present. Here the pulse shaper forms I1 a rising edge to a defined pulse, and the pulse shaper I2 forms a falling flank into one Pulse from I1 corresponding pulse, for example, to a positive impulse as shown in the drawing Xp1, Xp2.

This positive pulse Xp1 and Xp2 is a OR gate D2 to signal Y, the wake-up pulse, together leads. Of course, this function could be used instead of two pulse formers I1 and I2 and their output Ver binding by means of gate D2 in an equivalent manner also as Er block diagram can be described with only one pulse shaper, one positive and one negative edge in one Converts impulse of the same form.

According to the invention, the input signals X1, X2, X3 by changing a switching state of an operation by means of, as explained below. Of course The number of input signals is not on X1 to X3 limited, so that depending on the request and area of application any number of input signals through D1 to a Sig nal Xe can be summarized without this Impulse shapers become necessary.

In FIG. 2, an implementation of the block diagram of FIG. 1 is shown as a circuit diagram.

At the input X1, the circuit arrangement has a switch S1, one side of which is connected to ground and the other side of which is connected at point 1 to both cathodes of decoupling diodes D12 and D13. The diode D12 is connected on the anode side to one side of a capacitor, the point 1 'and at the same time via a resistor R12 to a power supply of, for example, 12 V. The other side of the capacitor C11 is as point 1 ″ via a resistor R01 with the power supply +12 V and at the same time with the point 2 ″ of one side of a capacitor C21, a collector of an NPN transistor T01 and via a base resistor R02 with a Base of a PNP transistor T02 connected.

The transistor T01 is connected to ground on the emitter side and the transistor T02 is connected to the power supply of +12 V on the emitter side. The collector of T02 forms the output for the output signal Y, this collector being connected to ground via the resistor R03. At the input X2, the circuit arrangement has a switch S2 which is on the one hand grounded and on the other hand connected to a point 2 '''and at point 2 to the cathodes of diodes D22 and D23.

On the anode side, diode D22 is connected at point 2 'to the side of capacitance C21 opposite point 2 ''and at the same time via a resistor R22 to the +12 V power supply. Here, R01 represents the resistance via which the capacitors C11 and C21 are charged, and R12 the discharge resistor for C11 and resistor R22 the discharge resistor for the capacitor C21. Switch S2 is connected via point 2 '''to one side of a capacitor C22, the other side of which is connected to the base of transistor T01 via a resistor R26. This basis is over resistance R27 again on ground.

At the input X3, the circuit arrangement has a switch S3, which is connected on the one hand to the power supply +12 V, and on the other hand is connected at point 3 to one side of a capacitor C32, and at the same time is connected to ground via resistor R31. The other side of capacitance C32 is also connected to the base of transistor T01 via resistor R32, like R26 and R27.

The function of this circuit arrangement according to FIG. 2 is explained below using the signal flow diagram according to FIG. 3.

The input signals X1 and X2 are each implemented as switches closing to ground, so that at the connection point of the cathodes of D12 and D13 when closing switch 1 a negative edge, and by opening a positive edge as signal X1. In the same way, the signal X2 arises at the connection point 2 of the cathodes D22 and D23. In contrast, the switch for the input signal X3 is designed as a switch that closes against a high level, for example +12 V, so that its closing at point 3 causes a positive edge and its opening causes a negative edge.

Now closes the switch for X2 to ground, for example by actuation of the door contact by opening of the door, as' a negative edge occurs at the points 2 and 2 according to signal 2 a of FIG. 3, via the capacitor to a nega tive Dirac -Impulse 2 a2 is differentiated. This negative Dirac pulse is applied to the base of the PNP transistor T02 via the base resistor R02 and turns it on until the capacitor C21 limits the current through it to such an extent that its value exceeds the threshold at point 2 ″ value of transistor C02 arises and closes again. The charging time is essentially determined by the RC element R01-C21, since the current flow through the emitter of the transistor T02 to its base through the base resistor R02 is comparatively low. At output Y, which is normally connected to ground via R02, a positive pulse 2 a3 according to FIG. 3 is produced by opening and closing transistor T02.

If the switch at X2 remains closed for a longer period of time, points 2 and 2 'remain at LOW (ground) as described above, and point 2 ''at the level of +12 V after charging of C21 has ended reopened at X2, points 2 , 2 'are thereby at a level of 12 V and point 2 ''also remains on this level, with capacitor C21 discharging again via R22.

When opening, the level of point 2 ''', which was 0 V when closing, is also changed to +12 V (signal 2 b1). The capacitor C22, which has discharged to ground when the switch X2 closes via this, now charges again essentially via R26 and R27 and in a negligibly small manner via the base emitter current from the transistor T01, so that at the The base of the NPN transistor T01 is at a positive level and drives it on until the capacitor C22 is charged to such an extent that the base voltage falls below the threshold value of the transistor T01 (signal 2 b2). Finally, this creates a negative pulse 2 b3 at the collector of transistor T01, which turns transistor T02 on and off via base resistor R02, so that signal 2 b3 is inverted and causes a signal in the form of 2 a3 at output Y.

The course of the signal from X1 differs from the signal from X2 just described only in that there is no connection point corresponding to point 2 '''to the base of transistor T01 or the upstream RC circuit. Points 1 , 1 'and 1 ''correspond to points 2 , 2 ' and 2 ''. Accordingly, the levels present at 1 , 1 'and 1 ''when the switch at X1 is closed correspond to the levels 2 , 2 ' and 2 '' when the switch is closed at X2 and consequently also produce a positive pulse in the form of 2a3 at the output Y. Since a point corresponding to the point 2 '''is missing, no corresponding opening and closing of the transistor T01 is effected in this circuit arrangement during a transition from the closed to the open state of the switch at X2. Of course, it is also conceivable to provide such a connection point corresponding to point 2 '''and to generate a wake-up signal for X1 both with falling and rising flanks.

At point 3 at point 3 when the switch is open, a level of 0 V is applied via R31, which changes to this level when the switch is closed to +12 V (signal 3 a1). The capacitor C32, which is discharged in the idle state, is now charged via R32 and R27, so that a plus level is present at the base of the NPN transistor T01, which previously was R27 at zero level, and turns on the transistor T01. This dear supervisor continues as long, as far as charged to the capacitor C32 (signal 3 a2), that the level at the base of T01 value falls below the threshold T01 and closes again. In this way, a negative pulse in the form of 2 b3 arises at the collector of T01, which, as described above, is inverted at output Y to a positive pulse in the form of 2a3. When the switch on X3 is opened, the base T01 remains at a level of 0 V via R27 and the previously charged capacitor C32 discharges to ground via the resistor R31.

In the circuit shown in FIG. 2, the generation of a wake-up signal at any changes in the switching state of the switch at X2 is realized only as an example at input X2, whereas only one change in each case at X1 and X3 in the case of X1 negative edge and Case X3 positive edge is used to generate a wake-up signal. Of course, several switches of the X2 type, but also several of the X1 and / or X3 type, depending on the field of application of such a circuit, could be provided. Likewise, the number of input signals or the switches can be increased or decreased, with D12 and D22 corresponding diodes having to be used to decouple the circuits. This results in any expandable and modifiable circuit arrangement that can be adapted to a wide variety of applications.

As shown in Fig. 2, the circuit arrangement has an additional power supply +12 V_GESCH, which can advantageously be switched or pulsed.

This is opposite across the diodes D11, D21 and D13 and D23 the circuit described so far and the +12 V energy ver supply is decoupled and is only switched on in active mode tet. Switching on is done, for example, by feeding the wake-up signal via a switching unit, for example a microprocessor.

By decoupling the power supplies, the radio tion of the circuit arrangement is not affected, so that in active mode the switching state of the switch from X1 to the Voltage dividers R14 and R15 at Xa1, for example by means of egg nes microprocessor can be queried because with the switch open X1 at Xa1 a positive level, for example in the form of a Pulse, which is in the case of closing the switch of X1 become a zero signal (for example in the form of a low Level pulses) changed. The Si present at Xa1 and Xa2 Signals depend on the energy source used in the ak active mode and are only in the embodiment because the pulsed energy source +12 V_GESCH in the form of a pulse (High or low level). But it would also be conceivable for Xa1 and Xa2 constant levels (high or low) by using ei to generate a permanent energy source in active mode.

The signal at Xa2 behaves with regard to the switch X2 in the same way. In contrast, X3 is a special case hen whose circuit in active mode is not pulsed Energy source is supplied. Here at Xa3 is only ge closed switch S3 a constant high level above one Voltage dividers R33 and R34. Using X3 only ge shows that a detailed query of the status of a switch with a permanent energy source possible is, and instead of a switch closing to ground a switch closing after +12 V is used as a variant can be. In this case, energy is used as for the Sleep mode for the circuits X1, X2 and X3, apart from minor leakage currents only with one ge closed switch consumed.  

The individual ones shown for X1, X2 and X3, for example Circuits can of course be made in any way a circuit arrangement can be combined and so on under different areas to the respective requirements will fit.

In the circuit arrangement shown in the exemplary embodiment with individual overlapping circuits The energy consumption in sleep mode is almost the same Zero, because normally - all switches open - except the Leakage currents through diodes, capacitors and transistors, none Streams flow. In this mode it is not exactly detected which switch generates a wake-up signal.

This wakeup signal can be used to span the Power supply of a microprocessor, for example of a voltage regulator. This will be advantageous the energy consumption of a circuit arrangement limited to almost zero, since the circuit arrangement in Sleep mode uses no energy.

An increased energy consumption of the circuit arrangement takes place only in active mode, the circuit now detailed the switching states of the respective switches are detected. This However, increased energy consumption can be achieved by using a pulsed energy source with compared to the pulse width longer breaks between the pulses advantageously ge ring are held. The breaks can last several ms, for example 10 ms. The pulse width value can do this for example from a range of 50 to 500 µs to get voted.

Claims (9)

1. Circuit arrangement for detecting switching states of at least one actuating means (S1, S2, S3), in particular switches for activating a motor vehicle electronics,

• the circuit arrangement generates a wake-up signal (Y, 2 a3),
• if at least one actuating means (S1, S2, S3) changes from a first defined switching state to a second defined switching state,

characterized in that

• - The circuit arrangement is designed such that it generates the wake-up signal (Y, 2 a3) even when the second switching state changes to the first switching state.

2. Circuit arrangement according to claim 1, characterized in that the wake-up signal (Y, 2 a3) by changing a switching state of at least one of several actuating means (S1, S2, S3) independently of the switching state of the other actuating means (S1, S2, S3) can be generated. 3. Circuit arrangement according to claim 1 or 2, characterized in that the circuit arrangement has an active mode for detecting the switching state of each individual actuating means (S1, S2, S3), which can be activated by the wake-up signal (Y, 2 a3) . 4. Circuit arrangement according to claim 3, characterized marked that in active mode a pulsed energy source (+12 V_GESCH) is activated. 5. Circuit arrangement according to claim 4, characterized characterized that the impulses of energy source (+12 V_GESCH) a pulse width in the range of 50 have up to 500 µs and Pau between individual pulses range from 5 to 20 ms.   6. Circuit arrangement according to one of the preceding claims, characterized in that the circuit arrangement for the at least one actuating element (S1, S2, S3) has a first circuit with a first pulse shaper ( 11 ) in order to change the first switching state to second switching state to generate a wake-up signal (Y, 2 a3) and in a two-th circuit has a second pulse shaper (I2) with an inverter to the wake-up signal in a transition from the second switching state to the first switching state (Y, 2 a3). 7. Circuit arrangement according to claim 6, characterized characterized that the first and second Circuit partially overlap. 8. Circuit arrangement according to claim 7, characterized characterized that the second circuit the pulse shaper (I1) of the first circuit closes. 9. A method for detecting switching states of at least one actuating means (S1, S2, S3), in particular switch ter for activating motor vehicle electronics, the at least one actuating means (S1, S2, S3) with at least two switching states giving each switching state a different value (0 , +12 V), characterized in that every change in the values (0-12 V, 12-0 V) is not shaped into a wake-up signal (Y, 2 a3).