DE1173935B - Astable multivibrator with at least two electronic amplifier elements - Google Patents

Description

Astable multivibrator with at least two electronic amplifier elements With the known astable multivibrators, regardless of whether they are electronic Amplifier elements containing tubes or transistors are always at least two RC circuits are used as the frequency-determining switching means, each of which between the control electrode of an electronic amplifier element, e.g. B. the base of one transistor, and the output electrode of the other electronic Amplifier element, e.g. B. the collector of the other transistor is connected. Two RC circuits as time-determining switching means for the toggle frequency of an astable Flip-flops have the disadvantage that the half-waves are not equal to the relaxation oscillation are, because even with the most careful selection of the individual switching means, z. B. capacitors, Transistors and resistors, hardly two completely equivalent switching means available stand. For this reason, they are from both sides of the astable trigger circuit The pulses emitted are never completely identical in terms of their pulse length. Behaves in the same way it is when the pulses to be emitted from both sides of the astable trigger circuit should be in a certain ratio with respect to their pulse length, d. H., a certain pulse length ratio cannot be kept constant.

Besides the different tolerances of the components that are within the time-determining switching means are used, affect the pulse length or the pulse length ratio of the breakover oscillation also - the temperature-dependent ones Blocking resistances of the amplifier elements themselves, e.g. B. the blocking resistors used transistors. So is z. B. with an arrangement of the RC circuit in the aforementioned type between the output electrode of the one and the control electrode of the other transistor, the blocking resistance of the last-mentioned transistor always the resistance of the RC circuit connected in parallel, so that by the temperature dependence of the blocking resistance, the value of the RC circuit that determines the breakdown time is always changed will. In the same way, the blocking resistance of a transistor also acts on the time-determining switching means of a monostable multivibrator.

The invention is based on the problem of, on the one hand, time-determining To arrange switching means in the flip-flop circuit that has an almost complete symmetry of the pulses to be delivered, and on the other hand the flip-flop circuit itself designed in such a way that no reaction caused by temperature influences takes place on the time-determining switching means used within the flip-flop. This task is achieved in that as a switching means that determines the breakdown time a series resonant circuit is provided and to the control electrode of the one electronic Amplifier element, preferably the base of a transistor, as well as to the Output electrode of the other electronic amplifier element, preferably the Collector of the other transistor, is turned on, while the control electrode. of the other electronic amplifier element, preferably the base of the other Transistor, with the output electrode of the first electronic amplifier element, preferably -the collector of the first transistor; connected is.

In the case of monostable multivibrators, it has already been proposed that to stabilize the pulse width between the collector of one transistor and to connect the base of the other transistor to a series resonant circuit. One Astable mode of operation cannot be achieved with this arrangement, however.

With the arrangement according to the invention, however, it is made possible that pulses to be emitted from both sides of the flip-flop circuit are, as a first approximation, the same size with regard to their pulse lengths. In order to achieve the equality of the pulse lengths completely, the reverse voltage for the one amplifier element generating resistor can be made just as large as the working resistance of the other amplifier element within the scope of the invention. Under this condition, the damping of the series resonant circuit is the same in both half-waves and thus complete symmetry of the pulses to be emitted with regard to their pulse lengths can be achieved. Details of the invention emerge from the embodiment described with reference to the drawing: The astable multivibrator shown in the drawing, constructed according to the invention, is in the idle state, ie the transistors Tr1 and Tr2 used in this example are blocked. The normally closed contact .s applies to the base of the transistor Tr2 the potential -I- UB , which is more positive than the emitter potential of the same transistor tapped from the voltage divider formed by the rectifier Gr 1 and the resistor R 4. The transistor Tr2 is therefore blocked. The transistor Tr 1 is also blocked in the idle state due to the voltage of + UB applied to its base via the resistor R 1. The capacitor C arranged in the series resonant circuit is charged in the idle state via the resistor R 1, the resistor R, the coil L and the resistor R 3 to the potential of + UB .

When the contact s is opened, the disconnection of the potential -I- UB from the base B 2 of the transistor Tr2 removes the blocking of this transistor. The base current of the transistor Tr 2 that has become conductive flows through the resistor R 2. The capacitor C of the series resonant circuit discharges through the coil L, the resistors R and R 1, the rectifier GR 1 and the emitter-collector path of the transistor Tr2.

When the capacitor C in the aforementioned circuit is discharged, the resonant circuit current at the resistor R 1 generates a voltage which blocks the transistor Tr 1 . The resonant circuit current of the series resonant circuit reaches a maximum, then decreases again and reverses its direction of current when it crosses zero, ie it now flows out of the transistor Trl as base current. The transistor Tr 1 thus becomes conductive during the second half-cycle of the oscillation determined by the series resonant circuit, and its collector potential blocks the transistor Tr2.

The negative voltage jump connected with the blocking of the transistor Tr2 at the collector of the transistor Tr2 acts as a supporting impetus for the resonant circuit current flowing from the base of the transistor Trl to the collector of the transistor Tr2. The resonant circuit current also reaches a maximum value in this direction, then goes back to zero and reverses its direction again, ie it begins to flow again from the collector of the transistor Tr2 to the base of the transistor Trl. As a result, the transistor Tr 1 is blocked again and the transistor Tr2 is again conductive. The positive voltage jump at the collector of the transistor Tr2 when it becomes conductive causes the series resonant circuit to be triggered in the opposite direction, ie the direction desired for this phase.

Due to the triggering of the series resonant circuit at every zero crossing the series resonant circuit itself can be very strongly fought, under certain circumstances even up to the vicinity of the aperiodic limit case. This results in a very large one Freedom of movement in the dimensioning of inductance and capacitance, d. H., you can have a very high inductance and only a small capacitance for the series resonant circuit choose without the strong attenuation of the high inductance associated with the Series resonant circuit is important. The small capacity also has the advantage of that they are replaced by a capacitor with a very constant dielectric, e.g. B. Styroflex, is feasible. This material in turn opens up the possibility of the temperature behavior of a suitably selected core material of the inductance, z. B. ferrite to compensate. That way it is even after a long period of operation the astable flip-flop can be achieved, not just the pulse lengths of the two to be emitted Impulses are the same among themselves, but also over a very specific absolute length to keep.

As already stated above, the resistance R 1 generating the reverse voltage for the transistor Tr 1 can be selected to be as large as the operating resistance R3. The latter is, for example, of the order of 1 kOhm. Since the highly temperature-dependent blocking resistance of the emitter-base path of the transistor Trl is parallel to the resistor R 1 and this blocking resistance value is many times higher, e.g. B. 100 kOhm, in the circuit constructed according to the invention, the blocking resistance change of the transistor Trl, depending on its operating temperature, has no influence on the damping of the series resonant circuit which determines the breakover time. The strongly temperature-dependent forward resistances of the transistors Trl and Tr2 are also irrelevant for the damping of the series resonant circuit, since the direct current resistance of the coil L is significantly greater than the forward resistance of both transistors Trl and Tr2.

The arrangement of a series resonant circuit made according to the invention between the control electrode of one amplifier element and the output electrode of the other As explained above, not only has the advantage that the ratio of the half-wave of a desired breakover oscillation is precisely maintained can be, but because the capacity of the series resonant circuit is already in the idle state is fully chargeable, also the fact that the breakover oscillations after switching on of the astable multivibrator start with exactly the correct phase. Because of this property is an application astable multivibrator constructed in accordance with the invention particularly suitable as a start-stop generator.

The proposed within the scope of the invention as a time-determining switching means Series resonant circuit, which has a capacitor with a dielectric, which Compensates temperature behavior of a suitably selected core material of the inductance, is not only in an astable, but also advantageous in a monostable Flip-flop can be used as switching means determining the flip-flop time when the circuit should have a good time constant with regard to their temperature behavior. However the request for protection does not extend to the stabilization of the pulse duration in a monostable multivibrator with a series resonant circuit as a timing element.

Claims (5)

Claims: 1. Astable multivibrator with at least two electronic ones Amplifier elements, preferably transistors, characterized in that as one that determines the tipping time Switching means a series resonant circuit (L, C) provided and to the control electrode (B 1) of an electronic amplifier element, preferably the base of one transistor (Trl) and the output electrode of the other electronic amplifier element, preferably the collector of the other Transistor, is turned on, while the control electrode (B 2) of the other electronic Amplifier element, preferably the base of the other transistor (Tr2), with the Output electrode of the first electronic amplifier element, preferably the Collector of the first transistor (K1) is connected. 2. flip-flop circuit according to claim 1, characterized in that the control electrode of an electronic amplifier element to which the series resonant circuit (L, C) is connected, via a resistor (R 1) generating the blocking voltage for the electronic amplifier element to the positive pole (- I- UB) of the supply current source is connected. 3. Toggle switch after Claim 1 and 2, characterized in that the reverse voltage for the one electronic amplifier element generating resistance is just as large as the working resistance of the other electronic amplifier element. 4. flip-flop circuit according to claim 1, characterized in that the series resonant circuit (L, C) consists of a relatively small Capacitor (C) with a highly constant dielectric, especially Styroflex, and a relatively large inductance (L), the iron core material of which, preferably ferrite, is chosen so that the temperature behavior of the inductance through the temperature behavior of the capacitor can be compensated. 5. flip-flop circuit according to claim 1 to 4, characterized in that it is used as a phase-constant start-stop generator. Older patents considered: German Patent No. 1 124 545.