DE1274643B - Trigger circuit with floating input circuit for a variable direct current - Google Patents

Description

Trigger circuit with floating input circuit for a variable Direct current The invention relates to a trigger circuit with a potential-free Input circuit for a variable direct current, which can be exceeded at any slow rate an upper response threshold tilting the trigger circuit into its one position and its slow falling below a lower response threshold that Causes tilting into their other position.

There are versions of trigger circuits, so-called step triggers, known, which essentially consists of two or more mutually coupled amplifier elements, z. B. transistors exist. In this group of trigger circuits; for example in the arrangement according to German Auslegeschrift 1149 056, the input terminals are galvanically with the circuit arrangement, but in particular with the operating voltage source tied together. This is undesirable in many applications. A capacitive coupling the signal source to the trigger circuit results in only more or less rapid Changes in the input signal can be evaluated. In addition, the There is still no risk of potential fluctuations affecting the signal source eliminated.

On the other hand, a circuit arrangement is also known which is used for galvanic separation of two DC circuits is used (German Auslegeschrift 1052 447). However, this circuit arrangement has no tilting behavior and fulfills therefore not the requirements to be placed on a trigger circuit.

The German Auslegeschrift 1148 261 is also an electronic Known switches with toggle behavior and potential-free control input circuit. However, only AC signals can be used to control this switch.

In contrast, the invention is based on the object of a trigger circuit indicate which is suitable for control by a variable direct current, which has a potential-free input circuit, the hysteresis properties with respect to the size of the DC control current and which suddenly tilts, even if the Response thresholds can be passed through as slowly as required.

According to the invention, this object is achieved in that a in the input circuit lying, controllable by the input direct current in a manner known per se Resistance through inductive coupling depending on the switching status of the trigger circuit as a variable collector resistance of a type of blocking oscillators known per se switched, self-fed back first transistor stage or as a variable Emitter resistance (negative feedback resistance) also similar to blocking oscillators switched, in itself fed back second transistor stage acts and that the Transistor of the first stage and the complementary transistor of the second transistor stage together with a third transistor form a bistable multivibrator, that in the one stable state of the flip-flop the first transistor is saturated and the third transistor is blocked and the second transistor has an operating point in the active area with a collector current which differs significantly from the saturation current and in the other stable state the second and third transistors are saturated and the first transistor is in the active (amplification) area.

The invention is explained in more detail below with reference to the drawings. F i g. 1 shows an embodiment of the trigger circuit according to the invention, F i g. 2 a bistable multivibrator, the extension of which creates the trigger circuit according to FIG. 1 is formed, FIG. 3 a simplified circuit diagram of a feedback Amplifier of the first type with a control circuit as part of the trigger circuit F i g. 1; finally, FIG. 4 a simplified circuit diagram of a feedback Amplifier of the second type with a control circuit as a further part of the trigger circuit according to Fig. 1.

The embodiment of the trigger circuit according to FIG. 1 contains three transistors T 1 to T 3. These transistors are mutually coupled in such a way that they form a bistable multivibrator. The output signal is picked up at the collector of transistor T 3 (or terminal A). The two other transistors T 1 and T 2 each form amplifier stages which are inductively fed back and which are excited to oscillate under certain conditions, which will be discussed in more detail below. Depending on the current I in the control circuit R 1, R 2, D 1 or on the voltage UE applied to the input terminals E 1 and E2, the trigger circuit switches to one or the other stable position.

Before details of the trigger circuit according to FIG. 1, the basic form of the bistable, consisting of the transistors T 1 to T 3 , on which the trigger circuit is built, is to be considered in more detail.

Like F i g. 2 shows, the transistors T 1 and T3 are of the pnp conductivity type, while the transistor T2 is of the npn type. Of course, if the polarity of the operating voltages U1, U2 and the forward direction of the diode D 5 are reversed, the line types can be interchanged.

The collector of the first transistor TI and the emitter of the second transistor T2 are connected via a common resistor R3 to the negative pole (with respect to the reference potential) of an operating voltage source U1 (e.g. -12 V). Separate resistors R 9 and R 7, respectively, lead from the emitter of transistor T 1 and from the collector of transistor T2 to the positive pole of a second operating voltage source U2 (eg + 12V). The emitter-base path of the transistor T3 is located between the emitter of the transistor T1 and the collector of the transistor T2. Its collector is connected to the output terminal A, via the resistor R 10 to the negative pole of the voltage source U1 and via the diode D 5 to the reference potential. The resistor R 10 can also be replaced by a correspondingly connected load resistor R10 '. (For easier understanding, all circuit elements in FIG. 2 and also in FIGS. 3 and 4 have the same designation as the corresponding circuit elements in FIG. 1, if at least their essential functions are the same.) To explain the mode of operation the bistable trigger circuit according to FIG. 1 it is initially simply assumed that in a certain switching state ("0" position) the transistor T3 is blocked and the transistor T1 is saturated. (A transistor is saturated when the collector current only depends on the operating voltage and the external resistances in the collector circuit and in the emitter circuit. The very small voltage drop across the transistor is irrelevant here and is therefore neglected.) The current in the emitter circuit of the Transistor T1 is determined by the difference between the base potential and the potential U2. The resistor R 3 is determined so that with the still available driving voltage between the base or emitter potential and the potential U1 a current results which is less than the emitter current or at most equal to it. However, this means that the transistor T1 can no longer contribute to an increase in the collector current, and its collector arises based on the values shown in FIG. 1, approximately to the +2 V potential. However, this potential is also the emitter potential of the transistor T2, so that this transistor remains blocked because of the negative base potential. The transistor T3 also remains blocked, since its base is considerably more positive than its emitter. The switching state of the flip-flop circuit assumed above thus proves to be stable.

5 In the other of the two stable states of the trigger circuit ("1" position), transistor T 1 is blocked and transistors T 2 and T3 are saturated. In this case, both the emitter and the collector of the transistor T2 approximately assume the potential -2 V.

o The base-emitter path of the transistor T3 becomes conductive and thus also sets the emitter of the transistor T1 approximately to the potential -2 V, so that the transistor T1 remains blocked. The collector of the conductive transistor T3 is held at the reference potential by the diode 5 D 5 , the only condition being that the value of the resistor R 10 is higher than the value of the resistor R 9.

For the transition from one stable state to the other, the flip-flop is to be regarded as a three-stage, internally fed back amplifier. It is easy to see that the transistors T 1 and T 2 are operated in the so-called base circuit and the transistor T3 in the so-called collector circuit. Despite the current gain factors of the two first transistors T 1 and T 2, which are just below one, the entire loop gain of the arrangement can easily be brought to a value exceeding one thanks to the high current gain of the third transistor T3. However, this guarantees a sudden shift in the circuit once it has been initiated by a sufficiently large disturbance.

Such a disturbance is initiated by the fact that, depending on the position of the multivibrator, an oscillation is fanned in one or the other of the amplifier stages that are fed back with the transistors T 1 or T 2. The principle of such an amplifier stage which is fed back via the windings W12 and W13 of the transformer via l is shown in FIG. 3 shown. Such an arrangement is generally known per se as a so-called blocking oscillator, so that it is not necessary to go into more detail about its mode of operation. As experience teaches and as can also be proven by theoretical consideration, which, however, will not be discussed, it is easy to find a dimensioning in which a steep transition takes place between the two temporarily stable states of the circuit arrangement.

Via the input control circuit EI, R 1, D1, W 11, E 2, which is also shown in a simplified manner, the feedback amplifier can be influenced in such a way that an amplification of vibrations is made possible or prevented. The dynamic resistance of the diode DI is set by the current I flowing in the control circuit. The capacitor C 1 has the effect that the dynamic resistance of the diode D 1 is connected in parallel in terms of alternating current to the winding W11 of the transformer Exercise. In this way, however, the resistance of the diode D 1 acts as a (changeable) alternating current collector resistance of the transistor T 1 in the feedback amplifier stage, if necessary with a corresponding transformation. If the dynamic resistance of the diode D1 is sufficiently small, that is to say if the control current I is sufficiently large, the loop gain of the amplifier stage is no longer sufficient to amplify the oscillation. If, on the other hand, the dynamic resistance of the diode D 1 increases by a corresponding reduction in the control current 1 above a certain value that is dependent on the circuit dimensioning, the oscillation begins.

The second amplifier stage according to FIG. 4 is with transistor T2 constructed in a similar way, but the control of the vibration application takes place in a different way. The collector alternating current resistance R 6 is now constant, on the other hand, the dynamic resistance of the diode D 1 acts here as a (variable) negative feedback resistance. It is coupled into the emitter circuit of the transistor T2 through the capacitor C 4. A change in the resistance of the diode D 1 thus acts at this stage in the opposite way to the first stage.

The input control circuit in the manner described so far has the disadvantage that the control current I flows through the winding W 11 of the transformer U 1 . This can be achieved by implementing the control circuit according to FIG. 1 can be prevented. The direct current is blocked by the capacitor C1 '. The filter element consisting of resistor R 2 and capacitor C 2 ensures on the one hand that the internal resistance of the control source does not influence the start of the oscillation, on the other hand, short-term interference pulses are kept away from the trigger circuit.

Since in the trigger circuit according to the invention according to FIG. 1 the two Amplifier transistors T 1 and T 2 at the same time elements of a bistable trigger circuit are, it must be ensured, in order to enable an amplification of vibrations, that at least one of these transistors has an operating point in its active Characteristic area assumes. In fact, additional measures prevent that that of the two transistors that, according to the above description of the simplified Toggle switch according to FIG. 2 was designated as blocked, really completely is blocked. This should be based on FIG. 1 are shown.

It is initially assumed that the trigger circuit is in the "1" position. According to the definition made previously, the transistors T2 and T3 are driven into saturation. The collector of the transistor T 3 and thus also its other electrodes, in particular also the emitter, are kept approximately at the reference potential by the diode D 5. Since the diode D 3 is now reverse biased, a small control current (about 5% of the saturation current) is still fed to the emitter of the transistor T1 via the relatively high-resistance resistor R 4.

The procedure is similar if the trigger circuit is in the "0" position the transistor T1 is saturated. The diode D 4 is then blocked and the transistor T2 receives a control current through resistor R 5.

To the trigger circuit according to FIG. 1, for example, from the "1" position To switch to the "0" position, the initially higher input control current I must be reduced will. If its value falls below the lower response threshold of the trigger circuit, so the oscillation begins in the first amplifier stage. As soon as the collector current of the associated transistor T1 has reached a certain value for the first time, flips the trigger circuit. At the moment of the tilting, the coupling capacitors C3 act and C 4 like short circuits. The transistor T 1 is driven into saturation, see above that he can no longer intensify and the oscillation that has just begun again immediately rips off. The trigger circuit switches to the "1" position in a very similar manner back when the input control current 1 is back up to the upper response threshold is increased. The transition is made through the second amplifier stage with the transistor T 2 initiated.

The transitions between the two stable layers of the trigger circuit take place, as already because of the barrier oscillator-like switching of the two in itself feedback amplifier stages can be expected without oscillating. This through practical testing confirmed property is still through within the bistable Basic trigger circuit supports effective feedback.

The exemplary embodiment according to FIG. 1 on which the description is based G. 1 of the trigger circuit according to the invention can still be in different, in the drawing are expanded in a manner not shown. So, for example, are the two Base potentials -I-2 V and -2 V advantageously through voltage dividers from the operating voltages derived. Furthermore, by dividing the resistor R 5 into two partial resistances and applying a positive potential via a diode to the connection point of the two partial resistances can be achieved that the trigger circuit is independent of the size of the control current I is held in the "1" position. By investing of a positive potential via a resistor to the emitter of the transistor T 1 can be prevented from tilting from the "0" position to the "1" position.

Claims (2)

Claims: 1. Trigger circuit with potential-free input circuit for a variable direct current, the slow exceeding of an upper threshold causes the trigger circuit to tilt into its one position and its slow falling below a lower threshold causes tilting into its other position, characterized in that one in the input circuit Lying resistance, controllable by the input direct current in a manner known per se, by inductive coupling, depending on the switching state of the trigger circuit, as a variable collector resistance of a first transistor stage (transistor T1) with feedback, connected in the manner of known blocking oscillators, or as a variable emitter resistance (negative feedback resistance) a second transistor stage (transistor T 2) which is also connected in the manner of blocking oscillators and which is fed back acts and that the transistor (T 1) of the first stage and the transistor (T2) complementary thereto d he second transistor stage together with a third transistor (T3) form a bistable trigger circuit in such a way that in the one stable state of the trigger circuit the first transistor (T1) is saturated and the third transistor (T3) is blocked and the second transistor (T2) has an operating point in the active area with a substantially different collector current from the saturation current and in the other stable state the second and third transistor (T2, T3) are saturated and the first transistor (T1) is in the active (amplification) area. 2. Trigger circuit according to claim 1, characterized in that the switching from the "1" position to the "0" position through an amplification of the oscillation in the first in feedback amplifier stage by reducing the input control current below the lower response threshold and the resulting increase in the controllable as the collector AC resistance of the first amplifier transistor (T1) effective resistance (D1) and switching from the "0" position to the "1" position by amplifying the oscillation in the second amplifier stage, which is fed back into itself by increasing the input control current above the upper response threshold and the resulting reduction in the controllable, as emitter alternating current -Resistance (negative feedback resistance) of the second amplifier transistor (T2) effective Resistance (D1) is triggered. Publications considered: German Interpretation document No. 1148 261.