DE1261547B - Astable or monostable multivibrator circuit - Google Patents

Description

Astable or monostable multivibrator circuit The invention relates rely on an astable or monostable multivibrator circuit with transistors of the same conductivity type for switching electrical circuits, e.g. B. from Traffic signal systems.

For example, an astable multivibrator consists of two amplifying ones Elements whose input terminals cross over capacitances with their output terminals are connected, each with a charging resistor with a fixed operating voltage is arranged at the entrance of the reinforcing element.

For the quality of such multivibrator circuits or flip-flops and especially for their use in traffic signal systems is crucial the stability of the switching properties, both against temperature influences as well as with very long desired switching times as well as short-term Interference pulses from mains power surges and from magnetic or electrical interference fields. In the case of the known circuits of the type specified in the generic term, it is so far not succeeded in a satisfactory way, if possible all of the above at the same time and to meet the requirements necessary for stability, rather remained always at least one of the defects described despite considerable switching effort exist. In particular, it was not possible with any of the known circuits those for long switching times, as required in particular by traffic signal systems, necessary enlargement of the charging resistances without an increased sensitivity to it to carry out the described interference.

The invention is based on the object, with the aid of particularly simple circuit elements and a particularly simple circuit technology, to meet the described requirements for the desired stability of the switching properties and at the same time to practically eliminate all of the described disruptive influences. This is achieved according to the invention in that in order to determine the voltage to which the capacitance, which determines the switching time, of each time circuit of the multivibrator circuit is charged, this capacitance is bridged by voltage-limiting elements. Through this measure, certain special features are achieved in the mode of operation of the multivibrator circuit, which have very decisive advantages. In a further embodiment of the invention, the voltage-limiting elements are expediently designed as Zener diodes and their voltage is 10 to 30% below the working voltage. In the following, the achievable advantages are explained in more detail: First, the influence of the switching time by the residual collector current, z. B. as a result of heating, practically switched off, since the highest possible charging voltage of the bridged capacitance of the time circuit is precisely determined by the limiting voltage of the voltage-limiting elements, namely by the Zener voltage. The bridging voltage-limiting switching element, namely the Zener diode, also creates an additional current path for the base-emitter current of the transistors when the predetermined charging voltage of the capacitance of the time circuit is reached. The Zener diode then takes over the charging current, so to speak. This ensures, on the one hand, that the associated transistor is operated in saturation, which is very desirable in order to keep its collector potential at the lowest possible value. On the other hand, the switching time, i. H. the resistance determining the time constant of the time circuit can be dimensioned because of the current transfer by the Zener diode so that it alone would not be able to let a current flow into the base, which alone would be sufficient for saturation. The charging resistor can therefore be selected to be very high-resistance. Overall, it is achieved that the respective conductive transistor is definitely saturated. The switching times of the toggle switch can therefore be selected to be large while strictly adhering to, which particularly improves the possibility of using the multivibrator circuit for traffic signal systems.

A third advantage can be seen in the following: The collector resistance of the respective blocked transistor carries the large base current flowing through the Zener diode or the voltage-limiting switching element for the conductive transistor. When the blocked transistor is briefly turned on by interference pulses of any kind, the blocked transistor takes over part of the current flowing through its collector resistor. However, its collector voltage is retained. The short-term Störünpulsä therefore have no effect on the conducting transistor. This means, however, that the switching or flipping process can only start with certainty when the collector of the previously blocked transistor has taken over the entire current that previously flowed through the Zener diode. This greatly reduces the influence of any interference pulses. # It has become. Multivibrator circuits specified at the beginning have proven to be useful to secure the transistor of the multivibrator circuit against overloading at the base of this transistor, so that the influence of the resistance determining the time constant on the current load of the transistor is largely reduced, but overall the choice of resistance for the Time constant not to be restricted. In - further development of the invention, the described advantages of the invention will be brought for such a multi-vibrator circuit for effect. This is based on a multivibrator circuit of the type specified at the beginning, in which a current limiter is connected to each transistor base, which consists of a series resistor and a voltage-limiting element, the series resistor between the charging resistor and the base of the transistor being switched on and also the voltage-limiting element from the connection point of the charging resistor with the series resistor is connected to the emitter potential of the transistor. According to one embodiment of the invention, the above-described advantages of the invention can be achieved in such a multivibrator circuit that the base-side connection of the voltage-limiting element bridging the capacitance is placed at the connection point between the voltage-limiting element of the current limiter and the series resistor.

To explain the invention, the drawing shows on the one hand two known multivibrator circuits and on the other hand several exemplary embodiments of the explanation, which are described below. In the drawing, F i g. 1 shows the circuit diagram of an astable multivibrator circuit as an example of a known embodiment, FIG . 2, as a further example of an embodiment, one from the circuit according to FIG. 1 derived monostable multivibrator circuit, FIG . 3 shows the circuit diagram of a basic embodiment of a multivibrator circuit according to the invention, FIG. 4 shows the example of a current limiter circuit for a multivibrator circuit, FIG . 5 shows the circuit diagram of a multivibrator circuit with current limiting using a further embodiment of the invention.

In the example - # "of a known multivibrator circuit according to FIG.". are the amplifying elements pnp-Transistoreü -.- T1 and T2 in the so-called emitter circuit # RI- and R2 are the load resistances in the collector leads, C 1 and C 2 are the coupling capacitors, which, each from the collector of one transistor to the base of the other Transistor are switched. R3 and ', R4 are the charging resistances from the bases of the timing transistors to the negative operating voltage. During operation, one transistor is conductive and the other is blocked. The conductive transistor, e.g. B. Tl, receives its control current from the negative operating voltage to the base via R3, while the capacitor C 1 connected to the base is at negative potential with its other coating, - d. that is, this capacitor C1 is charged. In contrast, the transistor T2 is blocked because the capacitor C 2 connected to its base applies a positive voltage there with respect to the emitter. This positive voltage decreases to the same extent as the capacitor C2 is discharged via the resistor R4, which is connected to the negative operating voltage from the base. As soon as the voltage at the base has assumed a sufficiently negative value, this previously blocked transistor T2 becomes conductive, as a result of which a voltage drop occurs at its collector resistor R 2, the potential at the base of the previously conductive transistor Tl to positive via the capacitor C 1 Shifts values towards and thus blocks this transistor. Due to the blocking, the collector potential of this transistor goes to minus operating voltage and thus also one layer of the one capacitor C2, ie. that is, the capacitor C2 is recharged. The associated base receives an additional negative pulse and controls transistor T 2 through, which accelerates the overturning process.

From the method of operation described it follows that the times while the circuit remains in one or the other position are essentially determined by the capacitances of the capacitors CI and C2 and by the resistance values of the charging resistors R 3 and R4. Setting resistors for R3 and R4 are usually used to set the times, as they can be used to cover large time ranges with little effort.

In the circuit described above, the switching times are still subject to various influences. The switching times are z. B. on fluctuations in the operating voltage. In addition, the two times influence each other in such a way that when the charging resistance R3 of the transistor TI changes, the switching time of the transistor T2 changes with it. After all, the times depend on the temperature of the environment, because with it the collector quiescent current IC 0 and the base quiescent current IB 0 increase.

A monostable multivibrator of known design is shown in FIG . 2 shown. It develops from the astable circuit according to FIG. 1 in that z. B. the coupling capacitor C 2 of the astable circuit is replaced by a coupling resistor R 5 and the base resistance R 4 of the astable circuit is not switched against the negative, but against the positive operating voltage. It is also useful to the emitter z. B. to give a negative bias voltage by means of voltage dividers R7, R6. In this circuit, the transistor Tl is conductive in the idle state, since negative voltage is applied to its base via the charging resistor R 3. The transistor T2 is not conductive because the voltage divider R 1, R 5, R 4 at the base generates a potential that is positive with respect to the emitter. The circuit switches to its astable state when negative voltage is applied to the base of the transistor T2, whereby this transistor becomes conductive, its collector assumes a positive potential and the capacitor Cl generates a positive voltage at the base of the transistor TI, which the transistor T 1 locks. This state is maintained so long as it is charged so far to the capacitor C1 via the LadewiderstandR3 that again a negative voltage is present at the base of the transistor Tl, thus the transistor T 1 becomes conductive and the transistor T 2 is turned off.

Regarding the question of the disadvantage of disrupting the function of the multivibrator circuit by glitches, it should be noted that, for. B. with a common charging resistor of 2M9 and an operating voltage of z. B. 8 V into the base about 4 pA. Here, an induced current change of perhaps only 1 gA is already able to drive the transistor out of saturation and initiate the switching process.

In Fig. 3 shows an embodiment of a multivibrator circuit according to the invention in the electrical circuit diagram, in which the deficiencies described have been eliminated.

In the multivibrator shown, the switching time-determining capacitance CI or C2 of the time circuit for determining the voltage to which it is charged is bridged by voltage-limiting elements, namely by the Zener diodes D 4 and D 5. The voltage of the Zener diodes is expediently about 10 to 30% below the working voltage. The polarity of the voltage-limiting elements, e.g. B. the Zener diodes D 4, D 5, is chosen so that the charging voltage of the capacitors Cl and C2 to the limiter voltage, z. B. the Zener diodes D4 and D5, is limited. When the capacitors C1 or C2 are charged, the associated Zener diode D 4 or D 5 becomes conductive after this voltage range has been reached; it supplies the base connected to it with a powerful current which strongly saturates the associated transistor T 1 or T 2.

F i g. 5 shows, as a further exemplary embodiment of the invention, the application of the invention to a multivibrator circuit of the type specified at the beginning, in which according to FIG. 4, a current limiter is switched on to each transistor base, which consists of a series resistor R 8 or R 12 and a voltage- limiting element "namely the diode D 1 or D 6 , the series resistor R 8 or R 12 between the charging resistor R3 or R4 and the base of the transistor T1 or T2 is switched on and the voltage- limiting element D 1 or D 6 is switched from the connection point of the charging resistor to the series resistor to the emitter potential of the transistor be that the base's own connection of the Zener diode D 4 or D 5 is not directly connected to the base, but via the respective series resistor R 8 or R 12 to the connection point between the series resistor R 8 and the diode D 1 or between the The series resistor R 12 and the diode D 6. The capacitance C 1 is connected in this case in a line section t, which connects the collector of the transistor T2 to a point between the series resistor R 8 and the base of the transistor Tl. In a similar way, the capacitance C2 is switched into a line piece which connects the collector of the transistor Tl to a point between the series resistor R 12 and the base of the transistor T2.

Claims (2)

Patent claims: 1. Astable or monostable multivibrator circuit with transistors of the same conductivity type for switching electrical circuits, e.g. B. of traffic signal systems, d a d urch g e - indicates that to determine the voltage to which the switching time determining capacity (C1, C2) of each time circuit of the multivibrator circuit is charged, this capacity by voltage-limiting elements (D 4, D 5 ) is bridged. 2. Multivibrator circuit according to claim 1, characterized in that the voltage-limiting elements are designed as Zener diodes and their voltage is 10 to 30% below the working voltage. 3. Multivibrator circuit according to claims 1 and 2, in which a current limiter is connected to each transistor base, which consists of a series resistor and a voltage-limiting element, the series resistor between the charging resistor and the base of the transistor switched on and also the voltage-limiting element from the connection point of the Charging resistor is connected to the series resistor after the emitter potential of the transistor, characterized in that the base-side connection of the voltage-limiting element (D 4, D 5) bridging the capacitance to the connection point between the voltage- limiting element (D 1, D 6) of the current limiter and the Series resistor (R 8, R 12) is placed ( Fig. 7) - Documents considered: Deutsche Auslegeschriften Nr. 1 084 755, 1065 874, 1080 142. Older patents considered: German Patent 1 144 329.