DE1290583B - Astable multivibrator - Google Patents

Description

The invention relates to an astable multivibrator with two mutually capacitive feedback transistors. With known multivibrators In this way, the coupling capacitors are charged up to a voltage that is almost the same as the operating voltage for the transistors. At the moment of switching of the astable multivibrator is therefore due to the base-emitter path of the straight line in the blocking state transited transistor a blocking voltage, which also has almost the same size as the operating voltage of the transistors. The operating voltage the transistors must therefore only be so large that they reach the maximum permissible Base-emitter reverse voltage does not exceed. This is particularly disadvantageous when devices are to be switched that require a high operating voltage. For example, if a relay is controlled by the astable garbage vibrator should not be, the relay coil is not directly in the working circuit of either of the two Transistors of the astable multivibrator are placed, but there must be an additional one Amplifier stage can be provided, in whose working circuit the relay coil is inserted will. The invention now provides an astable multivibrator in which the operating voltage for the transistors over that for known astable multivibrators hitherto customary value can be increased without thereby reducing the maximum permissible Base-emitter reverse voltage for the transistors is exceeded. It will be here of astable multivibrators with two mutually capacitive feedback transistors assumed in emitter circuit, in which the base of each in the blocked State transient transistor at least temporarily to the interconnected The emitter of the transistors is connected via a capacitor. With a well-known Circuit arrangement of this type (German Auslegeschrift 1124 997, Fig. 2) is for the temporary connection of the base of the respective transistor to each other connected emitter of the transistors a capacitor between the base electrons of the transistors connected. This capacitor is dimensioned so that from its capacity and the resistors arranged in its charging circuit results in a time constant that is small compared to the duration of the control of the Toggle circuit provided control pulses is. In this way it is prevented that Interference pulses can influence the multivibrator without affecting the waveform the current delivered by the multivibrator is influenced. The occurrence of an impermissible high base = emitter reverse voltage is not avoided as a result. The invention thus relates to an astable multivibrator with two mutually capacitively fed back Transistors in common emitter circuit, in which the base of each in the blocked State transient transistor at least temporarily via a capacitor is connected to the interconnected emitters of the transistors. According to the invention this multivibrator is characterized in that the capacitor has such a large Part of the charge of the transistor connected to the collector of the other, Serving for feedback capacitor takes over that of the two capacitors jointly briefly maintained voltage below the permissible base-emitter voltage of the transistor going into the blocked state.

The invention will now be explained in more detail with reference to three figures.

F i g. 1 shows a known astable multivibrator without any measures to reduce the base-emitter reverse voltage of the transistors; F i g. 2 shows an astable multivibrator, which is also known per se, in which by applying the dimensioning rule according to the invention, a reduction in the Base-emitter reverse voltage of the transistors is reached; F i g. 3 shows a too in terms of circuitry, it differs from the known circuit arrangement Embodiment of the astable multivibrator according to the invention.

The mode of operation of the known astable multivibrator shown in FIG. 1 will first be briefly discussed. This multivibrator contains the transistors T 1 and T2, which are connected to the negative pole of an operating voltage source via the resistors R 1 and R 2, respectively. A bias voltage is supplied to the bases of the transistors via the resistors R 3 and R4, which are each connected on the one hand to the base of one of the transistors and on the other hand also to the negative pole of the operating voltage source. The two transistors are fed back to one another via capacitors C1 and C2, which are each located between the collector of one transistor and the base of the other transistor. The emitters of the two transistors are connected to the positive pole of the operating voltage source. The feedback via the capacitors C1 and C2 should be selected so that neither of the two transistors can assume a stable state.

For explanation it is assumed that the transistor T1 is currently in the has passed the conductive state, the transistor T2, however, has just been blocked. The coupling capacitor C2 is then charged via the resistor R 2 and the resistor R 2 in it Fall low-resistance base-emitter path of transistor T1 to a voltage of almost the size of the operating voltage. At the same time, the capacitor discharges C 1 through the resistor R 3 and is charged again with the opposite polarity. If this causes the potential at the base of the transistor T2 to be its emitter potential has fallen below-, this transistor becomes conductive. The positive one that occurs The potential jump at its collector is generated via the charged capacitor C2 transmit the base of transistor T1 and block it. At this moment, so after turning off transistor T1, there is practically the entire voltage of the Capacitor C2, d. H. a voltage of the size of the operating voltage, as reverse voltage at the base-emitter path of the transistor T1. Because now the main stream line of the transistor T2 is very low, the capacitor C2 is practically in parallel to the base-emitter path of the transistor T1. Corresponding proportions lie before when the transistor T2 goes into the blocked state and the transistor T1 becomes conductive. In the case of the known astable multivibrator, therefore, is at the moment after switching the base-emitter path of the transistor that is currently in the locked state has passed, always one Reverse voltage, which has the level of the operating voltage.

In FIG. 2 is now a first embodiment of the invention astable multivibrator shown, in which this undesirable effect does not occur. Corresponding switching elements are provided with the same reference symbols in this figure as in FIG. 1. The astable multivibrator according to the invention differs of the known multivibrator according to FIG. 1 through one to the base electrodes the capacitor connected to the transistors and from a known astable multivibrator, in which this capacitor is already provided, through the dimensioning of this Capacitor in such a way that it, as will be explained in detail, is capable is to take over as much of the charge of the coupling capacitor that connected to the base of the transistor which has just gone into the blocked state is that the voltage jointly maintained for a short time by both capacitors below the permissible base-emitter reverse voltage of the transistors used lies.

For the sake of explanation, it should first be assumed again that the transistor T1 has just switched to the conductive state, whereas the transistor T2 has just been blocked. As already explained above, the coupling capacitor C 2 is charged to almost the full operating voltage. The multivibrator is switched to the other astable state when the capacitor C 1 has discharged through the resistor R 3 to such an extent that the base of the transistor T2 is almost at the same potential as the emitter of this transistor. At this moment the capacitor C 3 is uncharged because its two assignments have the same potential: If transistor T2 has become conductive after switching the astable multivibrator, since the main current path of transistor T2 is now very low-ohmic, capacitor C 2 is parallel to the base-emitter path of transistor T1. At the same time, however, the up to then lies in parallel with the capacitor C2. almost uncharged capacitor C3, since the base-emitter path of the transistor T2 has also become low-resistance and the occupancy of the capacitor C 3 connected to the base of the transistor T2 is practically due to the interconnected emitters. The capacitor C 3 thus immediately takes over part of the charge of the capacitor C2. The voltage that is now on the parallel-connected capacitors C 2 and C3, i.e. on the base-emitter path of the blocked transistor T1, is, however, lower than when the capacitor is in accordance with the capacitance ratio of the two capacitors, since no significant recharging takes place C 3 would not be provided. When the transistor T2 then changes back into the blocked state, the capacitor C 3 takes over part of the charge of the capacitor C1 in a corresponding manner, which brings about a reduction in the base-emitter reverse voltage of the transistor T2.

Since the astable multivibrator according to the invention actually occurring base-emitter reverse voltage of the transistors in the manner described can be reduced, it is easily possible now to reduce the operating voltage of the To increase transistors without thereby reducing the permissible value of the base-emitter reverse voltage of the transistors is exceeded by the actually occurring value.

Since in each of the two transistors the additional capacitor between Collector and base, a negative feedback occurs, through which the turnover times of the multivibrator can be extended. However, this is for example in the introduction mentioned case in which the multivibrator directly controls a relay, no disadvantage, since the turnover time of the relay itself is already much longer than the turnover time of the multivibrator. Rather, it is even desirable here to avoid large switch-off voltage peaks to avoid that the switch does not take place suddenly. If you have the additional Capacitor now still adjustable, you can adjust the edge steepness of the collector voltage jumps adapt to the respective conditions. For use cases where the extension the turnover time of the multivibrator is undesirable, this can be described below Embodiment can be used with advantage.

The F i g. 3 likewise shows an astable multivibrator which, however, instead of the one additional capacitor C3, contains the two additional capacitors C 4 and C 5, which are each located between the base and emitter of the transistors. In addition, a resistor is connected here between the terminal of a feedback capacitor facing away from the collector of a transistor and the base terminal of the respective other transistor, which resistor is denoted here by R 5 or R 6. The additional capacitor C4 serves to take over part of the charge of the feedback capacitor C2, while the additional capacitor C5 takes over part of the charge of the feedback capacitor C1, as will be explained briefly below. If, for example, the transistor T2 has just switched to the blocked state and the transistor T1 has switched to the conductive state, the feedback capacitor C1 is, as in connection with FIGS. 1 and 2 has already been explained, still charged to a voltage of almost the size of the operating voltage. Since the main current path of transistor T1 is now very low-resistance, the series connection of capacitor C 1 and resistor R 5 is now practically parallel to the base-emitter path of transistor T2. In parallel with this, however, there is still capacitor C5 in this arrangement, which immediately takes over part of the charge of capacitor C 1. In this way it is achieved that a reverse voltage occurs at the base-emitter path of the transistor T2 which, in accordance with the capacitance ratio of the capacitors C1 and C5, is lower than the operating voltage of the transistors. The operating voltage for the transistors can therefore also be increased here without the permissible base-emitter reverse voltage of the transistors being exceeded as a result. Corresponding conditions exist when the transistor T 1 is blocked and the transistor T 2 is conductive. The capacitor C4 then takes over part of the charge of the feedback capacitor C2.

The mentioned resistors R 5 and R 6 are used to control the charging current of the additional capacitors C5 and C6 limit. This charging current flows namely in the forward direction over the main flow path of each in the conductivity state located transistor and could be without the limiting effect the resistors R 5 and R 6 assume an impermissibly high value for the transistor. In the garbage vibrator according to the invention according to FIG. 2 limiting resistors are unnecessary, because the charging current of the additional capacitor C 3 is due to the through this capacitor caused negative feedback is limited.

Claims (4)

Claims: 1. Astable multivibrator with two mutually capacitive feedback transistors in emitter circuit, in which the base of the respective transistor going into the blocked state is at least temporarily connected via a capacitor to the interconnected emitter of the transistors, characterized in that the capacitor (C 3, F i g. 1; C 4, C 5, F i g. 3) such a large part of the charge of the capacitor connected to the collector of the respective other transistor (e.g. T1) and used for feedback ( e.g. C1) assumes that the voltage jointly maintained briefly by both capacitors (e.g. C3, Cl, F i g. 2; CS, C I, F i g. 3) is below the permissible base-emitter reverse voltage of the respective transistor (e.g. T2) going into the blocked state. 2. Astable multivibrator according to claim 1, characterized in that for the temporary Connection of the base of the transistor going into the blocked state the interconnected emitter of the transistors a capacitor (C3) between the base electrodes of the two transistors (T1, T2) is connected (FIG. 2). 3. Astable multivibrator according to claim 1, characterized in that in order to switch on the base of the respective transistor going into the blocked state to the interconnected emitter of the transistors, one capacitor (C5, C6) between the base and the emitter of each transistor (T1, T2) is connected (Fig. 3). 4. Astable multivibrator according to claim 3, characterized in that a current-limiting resistor (R5, R6) is inserted (F i g. 3) in each case between the base of a transistor and the associated feedback capacitor (C1, C2). S. Astable multivibrator according to Claim 2, characterized in that the capacitor (C3) can be set to change the edge steepness of the collector voltage jumps (Fig. 2).