DE1256691B - Monostable or astable transistor multivibrator circuit - Google Patents

Description

Monostable or astable transistor multivibrator circuit The invention relates to a transistorized multivibrator circuit with two operating states and RC elements, whose time constants the occurrence of at least one of the two operating states determine. It is therefore a monostable or astable multivibrator circuit. Both types of multivibrator circuits have the characteristic that they are after one through the dimensioning of the RC elements in certain time from the working state back in tilt back to the initial state. They differ in that the tilting from the initial state to the working state in the case of the monostable multivibrator circuit through external impulses and, in the case of the astable multivibrator circuit, through the dimensioning the circuit itself is triggered.

If transistors are used to build the multivibrator circuit, so there arises a problem that transistors are relatively small Require work resistances and it is therefore usually very difficult to use RC elements to verify with large time constants in known multivibrator circuits. Since the size of the resistors is limited, one must determine the capacitance values of the RC circuit choose appropriately large, which encounters difficulties, as electrolytic capacitors in terms of their tolerances and the need for voltage charging alternating polarity usually cannot be used.

In the German Auslegeschrift 1173 937 a solution to the problem underlying the invention is proposed, which consists in using a bistable arrangement in which the element determining the tilting time emits a pulse after a certain time has elapsed, which is the bistable arrangement itself returns to the starting position and thus turns the bistable into a monostable multivibrator circuit. In the case of the acquaintance, the time-determining element is also separated from the multivibrator circuit in terms of direct current. This makes the properties of the multivibrator circuit independent of the time-determining element. However, a simple RC element cannot be used as a time-determining element because it does not have the properties of emitting a pulse after a certain time has elapsed. The time-determining RC element must therefore be supplemented by a trigger circuit when known.

In the German Auslegeschrift 1155 480 a monostable or astable multivibrator with transistors is described, in which the unfavorable influence of the resistance of a time-determining RC element is compensated with the help of a circuit consisting of two diodes, an additional transistor and a parallel connection of a resistor with a Condenser exists. The transistor can be omitted if a special auxiliary voltage source is used in its place.

In contrast, the circuit according to the invention should use as little as possible and the simplest possible switching elements to achieve the same result.

The task is given in a monostable or astable transistor multivibrator circuit with RC time constant elements that determine the occurrence of at least one of the two unstable or stable operating states and in which the resistances of the RC elements are outside the circuits for the base currents of the transistors, according to the Invention achieved in that the multivibrator circuit, as known per se, contains a transistor of the pnp and npn type, of which the pnp transistor with its emitter-collector path is connected to the voltage source via a collector resistor, to the one above a connection containing the capacitor of an RC element, the base voltage for the npn transistor is tapped, whose emitter is connected to the voltage source and whose collector is connected to the base of the pnp transistor, possibly via resistors, and that the resistance of the RC- Link between the base of the npn transistor and the voltage source, vo is preferably switched via a voltage divider. In addition to an additional resistor, at most two voltage divider resistors are required for the astable circuit in order to prevent the resistances of the time constant elements from influencing the base circuits of the transistors.

In the preferred embodiment of the invention, the resistors are the RC elements with their connection facing away from the associated capacitor with that Connected voltage source, with which the associated capacitor is also connected stands. In this embodiment, the circuit for the capacitor discharge closes So via the resistance of the respective RC element and at least one terminal of the Voltage source.

To achieve great times for the multivibrator circuit to stay in one or the other operating state it is advantageous to adjust the resistances of the RC elements not directly, but via a voltage divider with the voltage source to connect, which ensures that the resistors receive a suitable bias.

While the exemplary embodiments described so far can be applied both to the case of a monostable and to that of an astable multivibrator circuit, a monostable multivibrator circuit requires additional circuit measures with regard to the supply of control pulses. Exemplary embodiments for this are given below: A preferred embodiment of the circuit arrangement according to the invention for the case of a monostable multivibrator circuit is characterized in that the series connection of a base resistor and a circuit element polarized in this way with directional current permeability, for example a diode, is parallel to the capacitor in the base circuit that an undesired discharge of the capacitor via the base resistance is prevented. So while in the case of an astable multivibrator circuit the connection between the base of the npn transistor and the collector of the pnp transistor was made via the capacitor of the RC element and control pulses were accordingly sent to the base of the npn transistor, the corresponding connection in the monostable multivibrator circuit contains parallel in addition to the capacitor of the RC element, the series connection of a resistor and a diode, d. H. a branch that conducts direct current. The suitably polarized diode ensures the required separation between the base current of the npn transistor on the one hand and the discharge current of the capacitor of the RC element on the other hand.

The base of the pnp transistor is expediently via diodes and capacitors with a control pulse generator connected to the input for the Control pulses during the quasi-stable state of the monostable multivibrator circuit to block, the diodes can be on one side with the base and on theirs the other side connected to the collector of the pnp transistor via a resistor be. This resistor is responsible for blocking the input for the control pulses during the quasi-stable state by suitable biasing of the diode.

The invention is described below with reference to the circuit example shown in the figure for a monostable multivibrator circuit. By omitting the circuit elements C 1, D 1, i. H. the supply line for the control pulses coming from input B, as well as the resistor R 4 and the diode D 2, d. H. of the branch lying parallel to the capacitor C2 of the RC element, the circuit arrangement preferably used in the invention for an astable multivibrator circuit is obtained from the circuit arrangement shown in the figures.

The exemplary embodiment of the invention shown in the figures contains the two transistors T1 and T2, of which the former is of the pnp type, while the latter is of the npn type. The transistor Tl lies with its collector-emitter path at the location indicated in the right part of the figure voltage source, while the transistor T2 has its emitter via resistor R 5 to the negative pole of the voltage source, on the other hand to its collector via the resistor R 8 the base of the transistor Tl, which in turn is connected to the positive pole of the voltage source via the resistor R 3. The base voltage for the transistor T2 is tapped off at the collector resistor R 1. This tap is done via the parallel circuit of the capacitor C2 of the RC element C2, R6 to the series circuit of the resistor R4 and the diode D 2, the diode D 2, also some other rectifying element can be used in their place, serves to undesirable To prevent discharge of the capacitor C2 through the resistor R4, which represents the base resistance of the transistor T2. This ensures that separate resistors are used for the base resistance of transistor T2 on the one hand and the resistance of RC elements C2, R6 on the other, so that these individual resistors can be dimensioned solely with regard to the task to be solved by them in the context of the circuit arrangement . The resistor R4 will therefore be designed as a base resistor in accordance with the requirements of the transistor T2 used in each case, while the resistor R6 can be dimensioned with regard to the desired time constant.

In the illustrated embodiment, the transistor Tl is conductive in the stable operating state of the circuit, so that a base bias for the transistor T2 is tapped at its collector resistor Rl. Since this base bias is close to zero, a base current flows into transistor T2 through resistor R4 and diode D2. This in turn has the consequence that a base current flows into the transistor T1 via the transistor T2 and the resistor R8 in its collector line, so that the described state is maintained in a stable manner.

If a blocking pulse is now applied from the outside to terminal B, it passes through the capacitor Cl and the diode Dl to the base of the transistor Tl. The collector current of the transistor Tl disappears, the potential for the base of the transistor T2, i.e. H. the potential at the connection point between the collector of the transistor Tl and the collector resistor R 1 assumes at least approximately the value of the negative voltage of the voltage source, and the transistor T2 is also blocked. Again, the state of the transistor T2 supports the operating state of the transistor Tl causing it. Since the transistor T2 is now blocked, the base of the transistor Tl receives a positive bias voltage via the resistor R 3, which supports its blocking.

This quasi-stable operating state of the monostable multivibrator circuit is maintained until the capacitor C2 has discharged so far that the transistor T2 can become conductive again. For this purpose, a charge reversal of the capacitor C2 is necessary, one of which, in the figure, the left layer is connected to the negative terminal of the voltage source in this operating state of the circuit. This charge reversal takes place via the resistor R 6, which, since it is not in the base circuit of one of the two transistors, can be dimensioned as desired with regard to the time constant required in each case. The dwell time of the monostable multivibrator circuit in the quasi-stable operating state is determined solely by the dimensioning of the circuit elements C2 and R6 and the level of the voltage between the negative terminal of the voltage source on the one hand and terminal A of the resistor R 6 on the other. In order to achieve a long dwell time in this operating state, it is therefore expedient, as shown figuratively in the embodiment, the connection A of the resistor R 6 of the RC element not directly to the zero terminal of the voltage source, but via the voltage divider R 7, R 9 to the voltage source connect to. Terminal A then has a voltage that is slightly more positive than the voltage of the negative terminal of the voltage source.

So that the duration of the quasi-stable operating state of the circuit actually only depends on the two factors just described, the resistors R 2 and R 5 are also provided in the circuit. Through the resistor R2, which connects one terminal of the diode D 1 in the feed line for the control pulses to the collector of the transistor TI, the input B for the control pulses is blocked for the duration of the quasi-stable state. The resistor R 5 in the emitter circuit of the transistor T2 is used to prevent unintentional tilting of the circuit in the event of fluctuations in the supply voltage.

As soon as the base voltage of the transistor T2 has become positive again by discharging the capacitor C 2 through the resistor R 6 that this transistor becomes conductive, it determines the base potential and the base current of the transistor TI via the collector resistor R 8, and the original - stable - state of the monostable multivibrator switch is reached again.

As already mentioned, the illustrated embodiment of the monostable multivibrator circuit according to the invention can be easily converted into a circuit arrangement for an astable multivibrator circuit by simply removing two circuits required for the operation of only the monostable multivibrator circuit. This is the circuit with the circuit elements C 1, D1, R2 and the circuit with the elements R 4 and D 2 for the supply of a base current for the transistor T2 mentioned circuit elements, an astable multivibrator circuit is obtained which also has the advantage that the time constant of its RC element can be freely selected solely with regard to the desired operation of the circuit arrangement. This advantage is achieved both in the case of an astable and in the case of a monostable multivibrator circuit in that separate circuit elements are used for the base resistances of the transistors on the one hand and the resistances of the RC elements on the other hand. In order to achieve large time constants, it is not necessary in the invention to make the capacitors of the RC elements large, which is often difficult, but the time constant can be increased by increasing the resistances of the RC # elements, which also results in the advantageous possibility of the to connect the terminal of the resistors not connected to the capacitor to a suitable voltage.

Understandably, there are deviations from what is shown in the figures Embodiment possible without leaving the inventive concept. For example Circuits with more than one RC element can be built, and then likewise it can be ensured that the resistances of all or part of the RC elements lie outside the base circuits of the transistors of the multivibrator circuit and accordingly, in turn, their dimensioning does not depend on the required sizes the load resistance of the transistors is limited. The pnp and the npn transistor can also swap their positions when the power supply and the diodes be reversed.

Claims (2)

Claims: 1. Monostable or astable transistor Mult! Vibrator circuit with RC time constant elements that determine the occurrence of at least one of the two unstable or stable operating states and in which the resistances of the RC elements are outside the circuits for the base currents of the transistors, d a d urch g e - indicates that the multivibrator circuit, as known per se, contains a transistor of the PNP and NPN type, of which the PNP transistor (T1) with its emitter-collector path via a collector resistor ( R 1) is located on the voltage source, the base voltage of the nPN transistor (T2) is tapped at the a capacitor (C2) of an RC element-containing compound, its emitter connected to the voltage source and its collector to the base of pnp The transistor, possibly via resistors (R8), is connected, and that the resistor (R6) of the RC element (C2, R6) between the base of the npn transistor (T2) and the Voltage source, preferably via a voltage divider (R9, R7), is connected. 2. Monostable transistor multivibrator circuit according to claim 1, characterized. that parallel to the capacitor (C2) in the base circuit is the series connection of a base resistor (R4) and such a polarized circuit element with directional current permeability, for example a diode (D2), that an undesired discharge of the capacitor (C2) via the base resistor (R4 ) is prevented. 3. Monostable transistor multivibrator circuit according to claim 2, characterized in that the base of the pnp transistor (T1) is connected to a control pulse generator via diodes (D 1) and capacitors (C 1). 4. Monostable transistor multivibrator circuit according to claim 3, characterized in that the diodes (D 1) are connected on their one side to the base and on their other side via a resistor (R2) to the collector of the pnp transistor (T1) . Considered publications: German Auslegeschriften No. 1129 528 # 1 141 095, 1 154 509, 1 155 480, 1173 937.