DE1181739B - Monostable or astable multivibrator circuit - Google Patents

Description

Monostable or Astable Multivibrator Circuit The invention relates to a monostable or astable multivibrator circuit with a coupling network for Stabilization of the duration of the quasi-stable state of the arrangement.

As is known, a monostable multivibrator consists in principle of two suitable feedback amplifier stages and has a stable operating point. However, it can be forced to work unstable with the help of an input signal so that it temporarily changes from its stable state to a quasi-stable one State and automatically revert to the initial state after its termination stable state returns. A monostable triggered by an input pulse Multivibrator therefore emits an output pulse, the width of which corresponds to the duration of the quasi-stable state. Astable multivibrators correspond in their Structure largely the monostable multivibrator, with the difference that they do not have a stable working point and thus swing freely from one to the other Toggle unstable state. Accordingly, they emit output pulses, their width is in turn determined by the duration of the quasi-stable state. The stable resp. The unstable state of such multivibrators is characterized by alternating Conducting current or blocking the two reinforcement elements forming the amplifier stages. The quasi-stable state is characterized by the time in which an unstable State is maintained.

A property of such circuits is therefore that with them Pulses of a certain duration can be generated. There is a requirement that To stabilize the duration of the emitted impulses and thus independent of unwanted ones To make influences. This requirement gives rise to the technical task that Stabilize the duration of the quasi-stable state.

The duration of the quasi-stable state is primarily determined by the time constant of the output of one with the input of the other amplifier stage connected coupling network (RC element). The duration is also influenced by the Initial value of the voltage on the capacitor of the coupling network at the beginning of the switching process and the final value to which this voltage would rise after an exponential function if the switching process does not occur at an intermediate critical voltage jump would be terminated. As a result, of course, the value of this also has due to the dimensioning given critical step voltage has an in fl uence on the pulse duration. Instabilities, resulting from temperature fluctuations, operating voltage fluctuations, etc. can therefore be avoided by stabilizing the sizes mentioned here.

It is already known e.g. B. the time constant of the coupling RC element to stabilize against temperature fluctuations by the fact that the temperature coefficient of the resistance is chosen to be equal to but opposite to that of the capacitor.

It is also known to monitor the voltage curve on the coupling network during of the switching process, i.e. during the charge reversal of the capacitor, not after one e function to run, but the course by switching on a preloaded To straighten the diode with the appropriate characteristic. This measure will probably Influences of operating voltage fluctuations reduced, but not eliminated.

It is also known to stabilize the critical jump voltage by that the rise in the voltage curve is chosen as steep as possible at this value. This can be achieved by making the largest possible difference between the initial value and the said actual final value of the voltage on the capacitor of the coupling network. However, this measure requires that the resistors, via which the capacitor is reloaded will be chosen as large as possible, but especially when generating short Impulses, in turn, should have small values.

To stabilize the initial value of the above on the coupling network It has already become known to use diodes to limit the voltage in usual circuit to be inserted. This measure, of course, requires one exactly stabilized operating voltage.

The final value of the voltage, it is in most circuits the operating voltage itself can only be achieved by a good stabilization of the operating voltage be kept constant. With strict demands on the constancy of the pulse duration the expenses for stabilizing the operating voltages become considerable.

To avoid the difficulties encountered with the known circuits and defects, in particular to avoid the expense of an exact stabilization the operating voltages required to stabilize the pulse duration a monostable or astable multivibrator circuit with a coupling network for Stabilization of the duration of the quasi-stable state of the arrangement proposed, such that in a known manner the output of the one with the input of the another stage of the multivibrator, consisting, for. B. from transistors, through a Coupling capacitor is connected, its two assignments separate, in time constant ratio of direct currents from two constant current generators are supplied and also its occupancy located at the output of one stage is connected to the reference potential via a resistor in such a way that the voltage proportional to the direct current at the beginning of the quasi-stable state The parallel transistor on the coupling capacitor becomes conductive as before due to the direct current conducting transistor causes blocking voltage jump and the coupling capacitor for the duration of the quasi-stable state through the DC is recharged linearly in time.

A particularly advantageous embodiment results from the fact that to generate the direct currents that are in constant relation to one another over time of the constant current generators on the assignments of the coupling capacitor each one of the Collectors of two systems connected to their bases and related to the two systems of the multivibrator forming transistors having the reverse conductivity type Transistors, the emitter of which is connected to the operating voltage of the multivibrator via resistors are led.

Fluctuations in the base potential of the two as constant current generators used transistors, as they can occur during a switching process, are avoided that the common base connection on the one hand via a Capacitor with the operating voltage, on the other hand via a resistor with the Reference potential is connected and the time constant of this element when taken into account the parallel switching elements are large compared to the duration of the quasi-stable State is selected.

To protect the two constant current generators against temperature fluctuations To make insensitive, it is further suggested that the two used Transistors are of the same type and have the same emitter resistances to get voted.

An exemplary embodiment of the invention is illustrated with reference to FIGS. 1 to 3 explained in more detail. It shows F i g. 1 shows the basic structure of a multivibrator with a coupling network according to the invention, FIG. 2 those occurring on the coupling capacitor Voltages during a switching process and 5,; F i g. 3 a working one Embodiment according to the invention, where already the temperature compensation additionally used components are added.

The two pnp transistors T10 and T20 are o with their emitters on the reference voltage, with their collectors via the load resistors R 10 and R20 on the operating voltage - U and form the two amplifier stages of a monostable multivibrator in a simplified representation. The capacitor C3, which connects the output, that is to say the collector of the transistor T10, to the input, that is to say the base of the transistor T20, is inserted as a time-determining element. The collectors of two npn transistors T 1 and T 2 , whose emitters are connected to the common operating voltage - U via resistors R 1 and R 2, are also connected to the two assignments of capacitor C3. The bases of the transistors T 1 and T 2 are connected to one another. The collector of the transistor T1 is also connected to reference potential via a resistor R 3. In the idle state, the transistor T10 is blocked and the transistor T20 is conductive. The two transistors T 1 and T 2 serving as primary current sources draw currents 11 and 12. The currents are determined by the common operating voltage, the common base voltage of the two transistors and also by the size of the emitter resistors R1 and R .. Especially when using transistors T1 and T "of the same type can be safely assumed that the currents Il and 12 change uniformly in the event of temperature fluctuations and operating voltage fluctuations and that they are thus at least always in a constant ratio to one another Potentials: on the left-hand side the voltage Uc which drops across the resistor R 3 as a result of the current II and on the right-hand side the base control voltage UB which keeps transistor T20 conductive. The current 12 flows out of the base of this transistor as a control current now blocked transistor T10 at its bas If a voltage pulse is supplied to keep it conducting in saturation, then resistor R 3 is suddenly short-circuited via the collector-emitter path of transistor T10. A voltage jump of the magnitude Uc is thus caused at the coupling capacitor C3, which is transmitted to the base of the transistor T20 via the coupling capacitor C3 and switches the previously conductive transistor into the blocked state. With this process, the quasi-stable state of the multivibrator begins. Since the transistor T20 is now blocked, the current 1l recharges the capacitor C3 linearly over time. The charge reversal takes place until the initial condition is again established at the base of transistor T20 , that is, the transistor becomes conductive, which means the end of the quasi-stable state. The potential profile UB on the right side of the capacitor and thus on the base of the transistor T20 is shown in FIG. 2 shown. At time t1, transistor T10 becomes conductive as a result of a control pulse. The voltage jumps by the amount Uc, and this blocks transistor T20. It is UB, = UB ; - Uc. The current 12 now recharges the capacitor linearly with the time t, so that we get: when C3 represents the capacitance of the capacitor C 3.

At time t2, the voltage UB has dropped so far that it has again reached the value UB and the transistor T20 is blocked. The duration of the quasi-stable state is thus given by and there the relationship = K = is constant, T = K - R3- C3. It can be seen from this that the duration of the quasi-stable state and thus the duration of the pulse emitted by the multivibrator is independent of fluctuations in the operating voltage. Another prerequisite is that the control voltage at the two transistors T1 and T2 remains the same at the time of the voltage jump occurring and for the duration of the quasi-stable state. For this reason, the common base connection is connected to an RC element. The capacitor C4, in conjunction with the resistor R 4, keeps the control voltage constant, provided that the resulting time constant is selected to be large in relation to the duration of the quasi-stable state. At the same time, the necessary base current for the transistors T 1 and T 2 is supplied via the resistor R 4 and the base potential is set to a useful value.

The functional embodiment according to FIG. 3 illustrates a monostable multivibrator. The coupling network of the invention is closed Toggle through the diodes D 11 and D 21 to the collector and the base of the transistors T10 and T20. For the diodes D11 and D21 are suitably silicon diodes to be used to minimize the amount reverse currents. When transistor T10 is blocked (initial position), diode D11 is also blocked, since there is no voltage drop across resistor R10. The current through the resistor R3, which determines the voltage Uc, is composed of the current 11 and the reverse current ID 11 of the diode D 11. During the duration of the quasi-stable state, transistor T20 is blocked. It receives its defined reverse voltage via the diode resistor element D 20R 21. The potential on the right-hand side of the capacitor C3 is more positive than the base potential of the transistor T20 during its charge reversal in the quasi-stable state. During this time, the diode D21 is also blocked, and the charge reversal current for the capacitor C3 is composed of the current 12 and the blocking current 1D 21 of the diode D 21. Under the condition that I1 > 1D 11 and 12 > 1D 21 What is given when using silicon diodes, the ratio of the total currents remains constant.

The diode D 3 in series with the resistor R 3 serves to reduce the temperature dependence the voltage Uc to eliminate the. Potential at the beginning of the quasi-stable State on capacitor C3 jumps. For this purpose, the diode D 3 according to their Semiconductor properties with regard to forward resistance and its temperature dependence selected in such a way that they correspond to the corresponding sizes of the Series connection of diode D 11 and collector-emitter path of transistor T10 match in the conductive state.

The others in the circuit according to FIG. 3 switching elements used only serve to complete the monostable multivibrator, and their use represents known measures. So the input E via the differentiating element C 10R 12 and a certain threshold voltage generating; member represented by a biased diode D13 which supplies the multivibrator triggering pulses. Also at the entrance. arranged diode resistor element R 11 D 10 generates a defined reverse voltage. From output A, at which the output pulses stabilized in their width, are available, the usual feedback circuit, consisting of the timing element R 22 C 20 in series with a, also leads. Diode D 12, back to the input of the other stage.

The coupling network according to the invention described here is implemented in a corresponding manner Way used in astable multivibrators. With this type of multivibrator it is appropriate to insert the network twice according to its structure and function.

Claims (7)

Claims: 1. Monostable or astable multivibrator circuit with a coupling network to stabilize the duration of the quasi-stable state the arrangement, characterized in that in a known manner the output one with the input of the other stage of the multivibrator, consisting z. B. made of transistors (T10 and T20), connected by a coupling capacitor (C3), its two assignments separate, in constant time relationship to each other standing direct currents (I "12) of two constant current generators are supplied and its assignment located at the output of one stage (T10) also via a resistor (R 3) is at the reference potential, such that the resistor (R3) applied to the Direct current (1i) proportional voltage at the beginning of the quasi-stable state The parallel transistor (T 10) on the coupling capacitor (C 3) becomes conductive a transistor (T20) which was previously conductive due to the direct current (12) blocking Voltage jump and the coupling capacitor (C3) during the duration (T) of the quasi-stable state is reloaded linearly in time by the direct current (12). 2. Monostable or astable multivibrator circuit according to claim 1, characterized in that to generate the constant over time direct currents (l1, I2) of the constant current generators on the assignments of the coupling capacitor (C3) each one of the collectors of two connected to their bases and related of the transistors (T 10 and T 20) which form the two systems of the multivibrator and which have the opposite conductivity type transistors (T1, T2), the emitters of which are connected to the operating voltage (U) of the multivibrator via resistors (R 2, R 1). 3. Monostable or astable multivibrator circuit according to claims 1 and 2, characterized in that to prevent fluctuations of the base potential of the two transistors serving as constant current generators (T1, T2) the common base connection on the one hand via a capacitor (C4) with the operating voltage (U), on the other hand via a resistor (R4) to the reference potential is connected and the time constant of this element when taking into account the associated parallel switching elements large compared to the duration of the quasi-stable state is. 4. Monostable or astable multivibrator circuit according to Claims 2 and 3, characterized in that transistors (T1, T2) of the same type are used for temperature compensation of the two constant current generators and the emitter resistors (R 1, R 2) are chosen to be of the same size. 5. Monostable or astable multivibrator circuit according to claims 1 to 4, characterized in that for temperature stabilization of the duration (T) of the quasi-stable state, the sum of the temperature coefficients of the coupling capacitor (C3), the resistor (R3) connecting it to the reference potential and the Emitter resistance (R2) of the transistor (T2) located at the input of one stage (T20) is selected to be equal to the temperature coefficient of the emitter resistance (R 1) of the transistor (T1) located at the output of the other stage (T10). 6. Monostable or astable multivibrator circuit according to claims 1 to 5, characterized in that the coupling network is connected to the output of one and the input of the other system of the multivibrator via diodes (D 11, D 21), preferably silicon diodes, which are so are polarized so that they are operated in reverse direction when the respective system is saved. 7. Monostable or astable multivibrator circuit according to claims 1 to 6, characterized in that in series with the coupling capacitor (C3) with the Reference potential connecting resistor (R 3) one or more in the forward direction polarized, so selected diodes (D 3) are connected that taking into account the temperature coefficient there is a voltage drop in the forward direction, which is equal to the total voltage drop at the adjacent coupling diode (D 1) and at the collector-emitter path of the transistor (T10) in the conductive state is.