DE1154509B - Monostable multivibrator circuit - Google Patents

Description

Monostabüe multivibrator circuit The invention relates to the Improvement of a monostable multivibrator circuit.

In principle, there are known monostable multivibrator circuits at least two heavily overdriven amplifier stages. The output is the first amplifier stage galvanically coupled to the input of the second, while the output of the second stage reacts capacitively back to the input of the first stage. Such a circuit generates a pulse with a more defined time at its output terminal Length as soon as a trigger signal is supplied to the input terminal.

The time constant of such a circuit that determines the pulse length generally depends mainly on the design of an RC combination. For certain applications it is desirable to have a comparatively large time constant available. This can be done by increasing the time-determining resistance or the capacitor. However, both values cannot be made arbitrarily large because the value of the resistance is still in other parameters of the monostable Multivibrator circuit is received, z. B. in the delivered pulse power, in such a way that an increase in the resistance results in a reduction in the pulse power Has. The dimensions of the capacitor grow with increasing capacitance, and this is undesirable in today's small construction, so that also in this way no increase in the time constant beyond a certain level is achieved can be.

It is therefore the purpose of the invention to specify a circuit arrangement, by which a known monostable multivibrator circuit is modified in such a way that that without any significant change in the time-defining terms an increase in the Time constant is reached or different values of the time constant can be selected.

The inventive monostable multivibrator circuit for generating long output pulses with a first and a second amplifier stage, which are galvanically, inductively or capacitively coupled to one another and in which the feedback from the output of the second to the input of the first stage takes place via a capacitor, is characterized in that the the base of the normally current-carrying transistor opposite end of the resistor is connected to a fixed or adjustable tap of the load resistance of the normally blocked transistor.

The invention is based on the knowledge that the base voltage of first transistor stage is applied to a variable voltage. The base voltage must be reduced in order to achieve a longer switching time. But this is only possible by reducing the resistance that determines the base current and the is also included in the time constant. However, a reduction in resistance means a small time constant. By lowering the tension alone one achieves no improvement of the known circuit.

The bias of the input stage can not only be applied by the output stage, but in a manner known per se from any variable voltage being controlled. Different tensions then arise in different ways long pulses.

The invention will now be explained in more detail with reference to the figures. A circuit arrangement with transistors is assumed here, for example. 1 shows a known monostable multivibrator circuit, FIG. 2 shows the profile of the voltages at points 12, 13 and 14 in FIGS. 1 and 3, FIG. 3 shows a monostable multivibrator circuit according to the invention.

Fig. 1 shows the basic circuit of a known monostable multivibrator circuit with pnp transistors. The transistor 1 is the active switching element of the first amplifier stage. It works on the load resistor 3, via which the operating voltage 9 is fed to the transistor 1. The output 13 of this stage is galvanically connected via a line or the resistor 5 to the input of the second stage consisting essentially of the transistor 2. This transistor receives its operating voltage 10 via the load resistor 4. The output 14 of the second stage is fed back via the capacitor 6 to the input 12 of the first stage. This input electrode receives the bias voltage 8 via the resistor 7. The three voltages 8, 9 and 10 can be the same or different from one another.

The mode of operation of this monostable multivibrator circuit is as follows: In the stable idle state, transistor 1 receives so much control current via resistor 7 that it has a low resistance to 3 . As a result, the potential of the output electrode 13 is almost identical to the potential 11, which was assumed here as the earth potential. As a result of the extraordinarily small potential difference between points 11 and 13 , the galvanically coupled transistor 2 receives so little control current that it itself has a high resistance to its load resistor 4. As a result, the potential of the output electrode 14 is almost identical to the operating potential 10.

The potential states are shown graphically in FIG. 2 for the three points 12, 13 and 14. The dashed line there denotes the position of the earth potential 11.

The capacitor 6 has its two terminals at points 12 and 14 and carries a charge corresponding to this voltage difference. Here, in the example shown, the terminal 12 more positive than 14. If the clip 15 at the time a positive trigger signal z. B. the input electrode 12, the transistor is high resistance, and then, the potential of the output electrode 13 approaches the operating potential 9 (see 16 in Fig. 2). The galvanically coupled transistor 2 thus receives so much control current that it has a low resistance to its load resistor 4. So the potential of the output electrode 14 rises until it has become almost identical to the ground potential 11 (17 in FIG. 2). This voltage jump is transmitted via the capacitor 6 to the input electrode 12 and continues to hold the transistor 1 in the high-resistance state even after the trigger signal 15 has disappeared (18 in FIG. 2).

However, the charge of 6 is not maintained. The capacitor discharges via 4, 7, 8 and 10, as shown in the diagram, curve part 19 . During this discharge, the potential of the electrode 12 drops until it is slightly below the earth potential 11 . At 20 the discharge process is aborted, since the transistor 1 now receives sufficient control current again, whereupon the potential of the electrode 13 rises again to its quiescent value 21. As a result, the transistor 2 no longer receives a sufficient control current. The potential of its output electrode 14 approaches the operating potential 10 again, while the capacitor is charged again via path 11, 14, 6, 4, 10 and 11. The circuit has returned to the idle state 22, which was initially assumed in the description of the mode of operation.

As can be seen in the diagram, a pulse of time-limited length has arisen at electrodes 13 and 14. The duration of this pulse is determined almost exclusively by the discharge time of the capacitor fi via the resistor 7 and is approximately proportional to the time constant which is calculated from the capacitance of the capacitor 6 and the resistance value of 7 . In order to achieve a short pulse duration, the product of these two values must therefore be small. A large value of the product RC is required for a large pulse duration. You do not have a completely free hand as to which of the two components 6 or 7 is expediently made large. If the small construction is required, then it is necessary to keep the resistance value of 7 large in order to be able to keep the volume of the capacitor 6 small for a given time constant. However, it is easy to specify an upper limit for the value of the resistor 7 , which must not be exceeded.

If one considers the monostable, multivibrator circuit as a pulse-generating member of a larger assembly, then this circuit must be able to deliver sufficient pulse power to the assembly connected to it. The size of the output pulse power is inversely proportional to the resistance value of the load resistors 3 or 4. For a given pulse power, the z. B. the output electrode 14 is to be removed, an upper value for the resistor 3 is determined. However, since the transistor 1 also has a current gain that is limited depending on the type, a maximum value for the resistance value 7 is determined from the knowledge of the resistance value of 3, the operating voltage 9, the current gain s and the operating voltage 8 Determine the value of the capacitor 6 after determining the resistance value 7 .

It is to achieve the purpose indicated in the following circuit, a sufficient pulse duration under the newly-made restrictions on the choice of the dimensioning of the resistor 7 and at the same time to give the capacitor 6 has a smaller capacitance value than it would be necessary according to the circuit example of FIG. 1.

The essential idea of the circuit according to the invention is that the resistor 7 is not, as previously known, applied to a fixed constant voltage. A change in voltage 8 also has an effect on the duration of the unstable state of the multivibrator circuit described, since the discharge curve 19 is determined not only by the time constant of the two components 6 and 7 , but also by the end potential to which this discharge would run , if the discharge curve were not broken off at 20 due to the non-linearity of transistor 1. If the value of the operating voltage 8 is applied closer to the potential 11 , the time function determined by 6 and 7 remains constant as such, but the discharge curve through the potential 11 will take place later. Characterized the duration of the unstable state of the multivibrator circuit is increased, the pulse is - become wider - while at the same time constant retarded.

The course of such a discharge curve, in which the potential is 8 moved closer to the potential 11 is shown in Fig. 2, 23. As can be seen, the point of intersection 24 with the potential 11 is shifted in time compared to the point of intersection 20 considered up to now.

Now it would not be enough to constantly, i. H. Both in the stable resting state and in the unstable tilting state, the potential 8 should be brought closer to the potential 11 . Namely, so that the transistor 1 has a low resistance to the resistor 3 in the idle state, a specific base current provided by the characteristics of the transistor 1 must be applied through the potential 8 and the resistor 7 . If the voltage between 8 and 11 were to be continuously reduced, the resistance value of 7 would also have to be reduced to the same extent so that the required base current can be applied unchanged. A reduction in resistance 7 would, however, immediately also have an influence on the time constant given in FIGS. 6 and 7 in the sense of reducing this time constant, which would at least partially compensate for the effect of reducing potential 8.

It is therefore proposed that the potential 8 can change its value synchronously with the switching process of the multivibrator circuit. One can imagine that the potential 8 is brought to a higher value by an external device during the stable quiescent state of the multivibrator circuit so that a sufficient base current to saturate the transistor 1 is generated at a given resistance value 7. Synchronously with the transition of the multivibrator circuit into the instable state, the external device should reduce the potential 8 when the transistor 1 becomes high impedance, so that the voltage between 8 and 11 becomes smaller. Then the discharge curve no longer runs according to curve part 19, but rather to curve part 23 , as a result of which the desired lengthening of the pulse is achieved with the time constant remaining the same. At the end of the unstable state, when the discharge curve goes through point 24, the multivibrator circuit flips back into the stable state, the external device should then bring the potential 8 back to the originally higher potential value in order to fully control the transistor 1 Apply base current.

A changeover switch can be used to implement this proposal, which alternately applies a high and a low voltage to terminal 8. However, it is more expedient to use the transistor 2 for controlling the synchronously fluctuating potential 8 . This arrangement according to the Erfmdung is shown in Fig. 3. For this purpose, the resistor 4 is subdivided or provided with an adjustable tap.

The tap of the resistor 4 or the connecting line of the two partial resistors is connected to the resistor 7 . This measure achieves the same effect as with the changeover switch.

In the stable idle state of the multivibrator circuit, the potential of the electrode 14 is almost almost identical to the potential 10, so that the resistor 7 is thus also connected to a potential which corresponds to the value 10. If the multivibrator circuit changes to the unstable state, then the electrode 14 approximately assumes the value of the potential 11 during the period of the unstable state. A voltage division occurs between points 14 and 10. The voltage ratio is determined by the value of the partial resistances. Under all conditions, however, the resistor 7 is now at a potential which - taken in absolute terms - is smaller than the rest potential 10.

The structure proposed in FIG. 3 , apart from the subdivision of the resistor 4, does not differ in complexity from the known circuit in FIG. 1. The transistors operate in a highly saturated state both in the idle state and in the flipped state. As a result, as is generally the case in digital circuit technology, environmental influences (temperatures, voltage fluctuations) and component tolerances are rendered ineffective.

The circuit arrangement according to FIG. 3 relates to a monostable multivibrator circuit with a constant large pulse length.

The arrangement can also be used advantageously in such a way that the resistor 7 is driven in a manner known per se at its terminal 8 by a variable voltage. This then influences the pulse length.

The specified circuit can then be used as a converter for telemetry and remote control tasks. The monostable multivibrator circuit is able to convert a continuously or discontinuously changing voltage value into a variable pulse duration, with a clear connection between the amplitude of a voltage and the pulse duration generated by the multivibrator circuit if terminal 8 is not, as previously suggested, is at the tap of the resistor 4, but is connected to a variable voltage, the z. B. is to be measured. With periodic triggering of the monostable multivibrator circuit, this circuit will then emit a series of pulses at the output electrode 14, the length of which is a true and unambiguous function of the voltage to be measured at terminal 8.

Claims (1)

PATENT CLAIM: Monostable multivibrator circuit for generating long output pulses with a first and a second amplifier stage which are galvanically, inductively or capacitively coupled to one another and in which the feedback from the output of the second to the input of the first stage takes place via a capacitor, characterized in that the Base of the normally current-carrying transistor (1) opposite end of the resistor (7) is connected to a fixed or adjustable tap of the load resistor (4) of the normally, blocked transistor (2).