DE1098032B - Monostable multivibrator with two transistors - Google Patents

Description

Monostable multivibrator with two transistors for storage of communication units are often mönöstabile and in telecommunications technology bistable multivibrators are used. Through this, a message unit becomes a stored for a certain period of time, with the use of a bistable multivibrator this message unit. until it is held for as long as required. A.' Such a bistable multivibrator thus represents a static memory A monostable multivibrator, however, can only enter information for a period of time that depends on the dimensioning of certain components depends on the multivibrator circuit. Such a monostable multivibrator thus represents a dynamic memory, which is also referred to as a transit memory can be.

It is now often desirable that a monostable multivibrator for is held in its astable position for a long time, as one example Message unit receiving and evaluating organ for receiving such Message unit is not yet ready. In this case it is necessary to to give a monostable multivibrator a bistable behavior that enables him to to pass on the message unit stored in it only on request. A such a monostable multivibrator, which contains two transistors, gets through one via a switch to the control. electrode of one of the transistors can be switched on Additional voltage a bistable behavior, since this additional voltage makes the monostable The asymmetry that triggered the behavior is canceled.

The invention relates to such monostable multivibrators with two transistors and thereby makes them bistable switching elements that the control electrode of a further transistor acting as a switch via a coupling network both the collector electrode of the transistor that can be switched to the additional voltage of the monostable multivibrator as well as to a control voltage source and the coupling network and the potential of the control voltage source are dimensioned in this way are that only with simultaneous connection of one of the multivibrator in its unstable Position controlling pulse and the control voltage the controlled electrode path of the transistor serving as a switch for the additional voltage is turned on and maintain the connection for the duration of the application of the control voltage remain.

For example, such a monostable multivibrator is used as an intermediate element between a subscriber line in telephone systems and one made of ferrite toroidal cores formed dialing memory inserted, each dialing information in the monostable State of the multivibrator with a certain delay time in the core memory given. If, however, an extraction process is running in this core memory, which is a simultaneous Storage of information is prohibited, so can for the duration of this storage process to those between the subscriber lines and the core memory, a control voltage are applied to monostable multivibrators themselves, which this there is now a bistable behavior. Dialing information is running in this state into one of these intermediate stores, it will be used for the duration of the storage process: process-des .Core memory-dependent control voltage is held in this buffer and only passed on when the simultaneous withdrawal process has ended the control voltage is removed from the corresponding, now bistable multivibrator will. When the control voltage is switched off, the relevant multivibrator receives again his usual monostable behavior, in which every election information with the time span determined by the delay time of the monostable multivibrator is passed into the core memory.

In the drawing, an embodiment of the invention is on hand a multivibrator consisting of two transistors (FIGS. 1 and 2) is shown.

The conventional monostable multivibrator contains the two transistors TR 1 and TR 2. The reversing pulses for this multivibrator are fed to input E, which is connected to the base of transistor TR 1 via a capacitor C 1 and a diode D 1. The monostable multivibrator is accompanied by a switching transistor TR3, which is connected to the base of the transistor TR2 via a resistor R8. In addition, the base of the transistor TR3 is connected via the resistor R 12 to a coupling network which contains the resistors R 9, R 10, R 11, R 12, R 13, R 14 and R 15. The formation of this coupling network is only to be understood as an example, because this coupling network can also be replaced by an arrangement according to FIG. 2, for example, without any significant change in its properties. In the initial state, when the battery voltage UBat is negative, the monostable multivibrator is in its steady state, in which the transistor TR2 draws current through its emitter-collector path as a result of the negative bias voltage applied via the resistor R7. The transistor TR 1 is blocked in this state of the multivibrator. As a result, the point PC2 has a low negative potential, with a low potential also being applied to the point PSp. With these potentials at the points PC2 and PSP and a fixed positive bias at the point Pv, the voltage dividers R 9 -R 10, R14-R15 and R I1-R13 are set so that the base resistor R12 at the base PB3 of the transistor TR3 there is a high positive voltage. The transistor TR3 is therefore blocked.

If an information pulse arrives at the input E of the circuit, the transistor TR 1 is opened and the transistor TR2 is blocked in a known manner. The resulting negative pulse at the point PC 2, ie at the collector of the transistor TR2, allows the positive voltage at the base PB3 of the transistor TR3 to drop via the coupling network, but the transistor TR3 remains blocked because its base is still positive. The monostable multivibrator remains in its quasi-stationary state for a period essentially determined by the time constant C3 # R7 and then falls back into its rest position. If, as a result, there is a low negative potential at point PSP, the arrangement works in the known manner as a monostable multivibrator, ie as a through-memory.

If a high negative potential is applied at the point PSP of the coupling network, then in the idle state of the monostable multivibrator there is a low positive potential at the points P3 and PB3, which still holds the transistor TR3 in the blocked state. If, however, an additional information pulse arrives at input E, the negative pulse generated by switching the monostable 1VTultivibrator at point PC2 via the coupling network causes the potential at point PB3 and thus at the base of transistor TR3 to become negative, so that transistor TR3 opens . The voltage divider R7 to R8 generates a potential which is positive with respect to the emitter potential of the transistor TR2 at the point PB2, so that the transistor TR2 remains blocked even after the period determined by the resistor R7 and the capacitor C3. The reversed multivibrator thus remains in its quasi-stationary state when the potential is applied at the point PSp. If the high positive potential is removed from the terminal PS.p and thus from the coupling network, the potential at the base of the transistor TR3 also becomes positive again, so that this transistor blocks and the multivibrator can fall back into its starting position.

Claims (1)

PATENT CLAIM: Monostable multivibrator with two transistors, by a switch to the control electrode of one of the transistors switchable additional voltage has a bistable behavior, characterized in that that the control electrode of a further transistor (T3) acting as a switch a coupling network (R9 to R14 or R16 to R20) with both the collector electrode of the transistor (TR2) of the monostable multivibrator that can be switched to the additional voltage as well as to a control voltage source (PS15) and the coupling network and the potential of the control voltage source are dimensioned so that only at Simultaneous connection of one that controls the multivibrator in its stable position Pulse (E) and the control voltage, the controlled electrode path (PB3) of the als Switch for the additional voltage serving transistor (TR3) is switched through and maintain the connection for the duration of the application of the control voltage remain.