DE3627069A1 - Monostable flip flop - Google Patents

Abstract

A monostable flip flop is specified which, compared with known monostable flip flops, is improved in such a manner that, after its turn-on time has elapsed, after the time at which its output signal resumes its rest state, it is no longer triggerable by further trigger pulses having a predetermined pulse amplitude for a predetermined minimum pause time and can only be triggered again by such pulses after this minimum pause time has elapsed. The circuit is preferably suitable for reducing the pulse repetition rate of pulse sequences to an upper limit frequency and thus provides for a transition from circuits having a high processing frequency to circuits having a lower processing frequency. <IMAGE>

Description

The invention relates to a monostable multivibrator according to the preamble of claim 1. A monostable multivibrator with those specified there Characteristics is known from the textbook U. Tietze, Ch. Schenk: "Semiconductor circuit technology", 4th edition, Springer-Verlag, Berlin / Heidelberg / New York, 1978, Fig.8.15 from p. 136.

It is typical for monostable multivibrators with this or a similar circuit design that they return to their idle state immediately after their switch-on time and can then be triggered again. From DE-OS 26 07 448 it is known that monostable multivibrators are not readily suitable because of this property for converting a pulse train with pulse repetition frequencies that are within an extremely large frequency range into a pulse train whose maximum pulse repetition frequency is below a limit frequency , which can be processed without problems by a subsequent circuit. As a solution to this problem, a circuit arrangement is known from DE-OS 26 07 448, in which a first monostable multivibrator is followed by a second monostable multivibrator, which is triggered at the end of the switch-on time t _{e of} the first monostable multivibrator and via one of the first monostable multivibrator upstream gate during their turn-on time t _e 'blocks the first monostable multivibrator against trigger pulses occurring.

It is the object of the invention, a Circuitry specifying this problem also solves, but less circuitry represents.

The object is achieved by that specified in claim 1 monostable toggle switch solved. Training courses are the dependent claims.

The invention will now be described with reference to the drawings for example explained in more detail.

It shows:

Fig. 1 is a circuit diagram of the monostable multivibrator according to the invention and

Fig. 2 shows pulse diagrams for explaining the operation of the circuit of FIG. 1.

The monostable multivibrator of Fig. 1 includes as essential elements two transistors T 1, T 2, whose collectors are connected to one pole of a supply voltage source is connected via collector load resistors R ₃ and R ₄ and its emitter connected via a common emitter resistor to the other pole are. One pole is grounded (0 volts) and the other pole has a negative voltage -U _B. The base of the transistor T 1 is connected to the connection point of two resistors R ₁ and R ₂, which are connected as a voltage divider circuit between the poles of the supply voltage source and provide a certain bias for this transistor. A voltage divider circuit comprising resistors R ₆ and R ₇, which is also connected between the two poles of the supply voltage source, similarly provides a bias for the base of transistor T 2 .

The collector of the transistor T 1 forms the input E of the circuit and is connected via a coupling capacitor C ₁ to the base of the other transistor T 2 . The collector of this transistor T 2 forms the output A of the circuit and is connected via a coupling capacitor C ₂ to the base of the transistor T 1 .

According to an important feature of the invention, the meaning of which will be explained later, the voltage divider circuits are dimensioned such that there are different bias voltages for the bases of the two transistors, in the exemplary embodiment a bias voltage U- Δ U for the base of the transistor T 1 and one Bias voltage U for the base of transistor T 2 . The circuit is intended for activation by current pulses as trigger pulses.

The operation of the circuit will now be explained with reference to FIG. 2. Before this, some meanings are introduced for the different voltages and currents of the circuit:

It is:
U- Δ U the base bias of the transistor T 1 determined by the voltage divider circuit R ₁, R ₂ ( Δ U is a positive value),
U is the base bias of the transistor T 2 determined by the voltage divider circuit R ₆, R ₇,
U _{B 1} is the base voltage of the transistor T 1 which varies over time with respect to the base bias, in the idle state of the circuit equal to the base bias U- Δ U ,
U _{B 2} is the base voltage of the transistor T 2 which varies over time with respect to the base bias, in the idle state equal to the base bias U ,
i the input signal of the circuit consisting of a sequence of current pulses with a predetermined pulse amplitude i _A and a strongly fluctuating pulse repetition frequency,
U _{C 1 is} the collector voltage of transistor T 1 ,
U _{C 2 is} the collector voltage of transistor T 2 , at the same time output signal,
I _{E is} the current flowing through the emitter resistor R ₅,
U _{A is} the amplitude of the voltage pulses resulting from the input current pulses with the current pulse amplitude i _A at the collector resistor R ₃,

U ₁ = I _E · R ₃

U ₂ = I _E · R ₄.

The following should also be noted about the emitter current I _E : The exact emitter current is calculated from the base voltage of the currently conducting transistor, minus the base-emitter voltage, divided by the resistance R ₅. To explain the circuit, it is sufficient to consider the current I _E as constant. The base currents, which also contribute to the emitter current, are neglected. It is also possible to replace the emitter resistor R ₅ with a constant current source. The principle of the circuit remains unchanged, but the effort is increased.

The circuit can now be described as follows: The base bias voltages are selected so that the base voltage of T 1 is more negative by Δ U than the base voltage of T 2 , e.g. B. by 0.8 V. This leads T 2 and blocks T 1 . During this time of the idle state, which is shown in the pulse diagrams of FIG. 2 as the time following a time t = 0, the base voltage U _{B 1} in the diagram d is equal to the base bias U- Δ U and the base voltage U _{B 2} of T 2 equal to the base bias U. In diagram d of FIG. 2, the time profile of the base voltage U _{B 1 is marked} with circular rings and the time profile of the base voltage U _{B 2 is} marked with crosses.

In this idle state, because T 1 is blocked and no current flows to the input, no current flows through the resistor R ₃, so that the collector voltage U _{C is 1} 0 V, which is shown in diagram b . The entire current I _E then flows through the conductive transistor T 2 , so that its collector voltage (based on the potential of the grounded pole of the supply voltage source ) is -U ₂ = I _E · R ₄. This voltage is also the output voltage of the circuit at rest, diagram C.

An example of a possible sequence of trigger current pulses with a pulse amplitude i _A is shown in FIG. 2 in diagram a . As you can see, the frequency of this pulse train fluctuates greatly. Each of these trigger current pulses generates a negative voltage pulse across the resistor R ₃. This negative voltage pulse is coupled through the coupling capacitor C 1 to the base of T 2 .

If the circuit receives such a trigger current pulse during its idle state, the following happens: The negative voltage pulse which is based on T 2 via C 1 makes U _{B 2 more} negative than U _{B 1} . This causes T 2 to be in the blocked state and T 1 to be in the conductive state with the consequence of a positive voltage jump in the collector voltage U _{C 2} from T 2 (diagram c) and a negative voltage jump in the collector voltage U _{C 1} from T 1 (diagram b) , ie with a trigger pulse (time t = t ₁ in the pulse diagrams of Fig. 2), the circuit tilts from its idle state to the on state. The positive voltage jump of the collector voltage U _{C 2} of T 2 is transferred via the coupling capacitor C ₂ to the base of the transistor T 1 so that its base voltage U _{B 1} makes a significant jump in a positive direction from its rest state value U Δ U. This state is shown in Fig. 2 in diagram d at time t ₁.

The diagram b shows that when tilting from the idle state to the on state, the collector voltage U _{C 1} of T 1 drops from the value 0 to the value -U ₁ = I _E · R ₃ and that this drop due to pulses with the voltage amplitude U _A , the at the resistor R ₃ arise from trigger current pulses of amplitude i _A , pulse-like to more negative values - (U ₁ + U _A ) is amplified. Since this added value to the voltage -U ₁ pulses pass through the coupling capacitor C to the base T ₁ ₂, they also make the base voltage U _{B 2} during the on pulse-wise negative.

During the switch-on time, starting from the time of tipping, the base voltage U _{B 2} of T 1 becomes a time constant

again more positive, apart from the pulse-shaped negative jumps shown, and the base voltage U _{B 1} of T 1 becomes with a time constant

more negative. The negative voltage jumps shown, added to the base voltage U _{B 2} , do not change this switch-on state of the flip-flop, since U _{B 2} is more negative than U _{B 1} in this state, that is, further trigger current pulses have no effect on the circuit during the switch-on state.

Up to here is how the new circuit works equal to that of an ordinary monostable multivibrator.

As soon as the two base voltages have become equal to one another, at the time t ₂ in the diagrams of FIG. 2, the flip-flop tilts into the state in which T 1 blocks and T 2 conducts. Here, 1 is a positive voltage jump of the collector voltage U _{C 1} -U ₁ to 0 V and the collector of T 2 a negative voltage jump of the collector voltage U _{C 2} from 0 V to -U ₂ = I _E · R ₄ at the collector of T is produced. The negative voltage jump of U _{C 2} is transmitted via the coupling capacitor C ₂ on the basis of T 1 , so that U _{B 1} makes a negative jump (the voltage curve marked with annuli at t ₂ in the pulse diagram d of FIG. 2), and the positive voltage jump of U _{C 1} is transmitted via the coupling capacitor C ₁ on the basis of T 2 , so that U _{B 2} makes a positive voltage jump (the voltage curve marked with crosses in Fig. 2 at time t ₂).

But this does not yet passed as in known mono-shots of the on-state to the quiescent state since the base voltage U _{B 2} still clearly still significantly higher than its rest state value U and the base voltage U _{B 1} under their hibernation value U- Δ U. The two base voltages now approach their idle state values U and U- Δ U with the above-mentioned time constants τ ₁ and τ ₂. Voltage pulses that arrive in this state of the circuit with an amplitude U _A on the basis of T 2 and lower the base voltage U _{B 2 in} pulses by U _A , which the pulse diagram d shows in the period after t ₂, the state of the circuit is not change because they cannot make U _{B 2 more} negative than U _{B 1} . Only after the difference between U _{B 2} - U _{B 1 has become} smaller than (or equal to) U _A can the circuit be flipped again into its switched-on state by further trigger current pulses. In the pulse diagram d of Fig. 2, this state is reached at time t ₃. The next trigger pulse occurring after the time t ₃ then triggers the same tilting process that has already been described for the trigger pulse occurring at the time t ₁. The other, indicated in Fig. 2, running after the time t ₃ processes therefore no longer need an own explanation.

The above explanation has shown that the monostable multivibrator according to the invention after a switch-on time t _e (from time t ₁ to time t ₂) for a predetermined time t _p , which can be referred to as the minimum break time (from time t ₂ to time t ₃) assumes a state in which its output signal adopts the level -U ₂ of the idle state, but in which it is insensitive to further trigger pulses. So it certainly maintains this level of the output signal for the minimum pause time t _p . This means that, as in the known solution mentioned at the outset, the sequence of trigger pulses is converted into a pulse sequence whose maximum pulse repetition frequency is the same

is, the output pulses (pulse diagram c) compared to the pulses of the input signal (pulse diagram a) are significantly broadened as a result of the relatively large turn-on time t _e .

The difference Δ U of the Hibernation base bias voltages must be corresponding to the voltage amplitude U _A are chosen such that in any case, a trigger pulse can cause the tilting of the circuit in quiescent state, ie U _B makes ₂ more negative than U _{B 1,} or at least leads to the equality of the two voltages . Is U _A z. B. equal to 1 V, then Δ U = 0.8 V is a suitable value. In general, Δ U should be chosen so that it is slightly smaller than U _A or equal to U _A. In the first case, the minimum pause time ends when U _{B 1} and U _{B 2 have} almost reached their idle state values, in the second case when they have reached them exactly.

The control of the circuit of FIG. 1 via the collector of T ₁ by current pulses can be replaced by a driving of the base of T ₁ with positive voltage pulses or the base of T ₂ with negative voltage pulses as the trigger pulses.

To the category of the circuit described above is to note the following. Because of their compared to known monostable multivibrators symmetrical Construction is similar to an astable Multivibrator as it is e.g. B. from Fig. 8.17 on p. 137 of is initially known textbook. Nevertheless she doesn't work like this since she doesn't work all the time tilts back and forth between the two states, but triggered again after every minimum pause got to. So it seems justified to them of the genus of the monostable multivibrators.

Claims (4)

1. Monostable multivibrator with two transistors, the collectors of which are connected via collector load resistors to one pole of a supply voltage source, characterized in that

• - That the emitters of the two transistors (T ₁, T ₂) are connected to the other pole of the supply voltage source via a common emitter resistor (R ₅),
• - That the collector of a transistor is coupled to the base of the other via a coupling capacitor (C ₁, C ₂),
• - that the bases are each at a bias (U- Δ U, U) ,
• - That the bias voltages of the bases are chosen so differently according to the predetermined amplitude (i _A ) of trigger pulses that the circuit, after being tipped into its unstable state by a trigger pulse received at its input (E) for a certain switch-on time (t _e ) was and tipped back into its stable state, initially remains in a state for a certain minimum pause time (t _p ) in which it cannot be triggered by further trigger pulses with the predetermined pulse amplitude (i _A ) and only after this minimum pause time has elapsed by others Trigger pulses can be triggered again.

2. Toggle switch according to claim 1, characterized in that instead of the common emitter resistor (R ₅) a constant current source is available for both transistors (T 1 , T 2 ). 3. Toggle circuit according to claim 1 or 2, characterized in that the difference ( Δ U) of the base bias voltages is chosen so that a base of one of the transistors (T ₂) supplied voltage pulse, which occurs at an input (E) Trigger current pulse arises or is supplied as a trigger voltage pulse directly to this base, slightly exceeding this difference. 4. Toggle switch according to claim 3, characterized in that the difference ( Δ U) of the base biases is chosen equal to 0.8 V when the amplitude U _{A of} the voltage pulse is 1.0 V.