DE1133582B - Electrical binary counter - Google Patents

Description

Electrical binary counter The invention relates to an electrical one Binary counter with multivibrators connected in series, their operating states bring about a predetermined operating state of a previous stage of the counter.

With electrical switching or counter stages connected in series it is - often - necessary - to achieve a special operating state of a stage - one previous stage automatically returns to a predetermined operating state bring. As a result, numerous types of feedback loops have been developed to for example by series-connected stages of a binary counter system, for example a decimally encrypted binary counter to be able to connect with each other and to cause the toggling of a binary element from one of its two states in the other a previous binary element automatically into a predetermined one State reset.

When going to control the operating state of the previous stage tried a common capacitive feedback from one of these stages to one If you use the previous stage, no insulation is provided between the stages. An actuation of the previous stage can therefore in an undesirable manner the next one Affect level. Therefore not only need an impedance isolation between the Stages, but also a polarity distinction can be provided as it is desirable is to feed back only the signals that are used to control the switching of the. previous stage in the desired operating state have suitable polarity. Accordingly, if a resistor is added to the capacitive resistance circuit, suitable insulation can be achieved. Unfortunately, such an additional, resistor connected in series with the input capacitance connected in parallel of the previous stage and severely affects the bandwidth of the feedback loop. In addition, with the resistance-capacitance feedback circuit, it is difficult to between Performance and reliability are a workable compromise, though Good operational reliability can be achieved at impermissibly low frequencies can.

For this reason, sets of bistable multivibrator units connected in series were or systems using "flip-flop" stages with special vacuum diodes Equipped with feedback circuits that cause the actuation of a stage in a predetermined operating state, the previous stage into a desired one Operating condition brings and that the requirements of polarity distinction and Impedance isolation between the stages have been met. However, if the diode has a Is vacuum tube, it has a significant energy consumption. If, on the other hand, you have crystal diodes takes aid, the circle is critically affected by the ambient temperature of the Device-dependent, which limits the applicability of the system subject. In addition, in many cases crystal diodes do not have any to be applied the insulation required between the stages connected in series is sufficient high feedback impedance.

Accordingly, it is the object of the invention to provide a new and improved one indicate electrical binary counter in which a stage has a suitable feedback without any of the aforementioned deficiencies in the resistance, capacitance, or diode feedback circuits connected for switching a previous stage to a desired operating state can be.

According to the invention this object is achieved in that a bilateral conductive, non-linear switching device, preferably a two-electrode glow tube, is provided between successive stages as AC coupling is interposed in such a way that it is the input of a Level accordingly controls the operating state at the output of another stage.

The invention is described in the following detailed description with reference to the drawings showing some embodiments of the invention explained. 1 shows a circuit diagram of a preferred embodiment of the invention, FIGS. 2 and 3 each show a similar circuit diagram of two modified embodiments.

In FIG. 1, two binary counter multivibrator circuits are shown as stages I and 1I connected in series. Stage 1 contains a pair of electron tube relays 1, 3 which, if desired, can be co-located with a single piston. The tubes 1 and 3 each have an anode 5 or 7, a control electrode 9 or 11 and a cathode 13 or 15. The anodes 5 and 7 are each connected to the control electrodes via resistance-capacitance circuits N 1 and N 2 11 and 9 of the respective tubes 3 and 1 are coupled, as is customary in circuits of this type. The cathodes 13 and 15 are each connected via a resistor 17 and a capacitor 19 to a ground or terminal B - the source supplying the anode voltage. The term "earth" used here should not -only- the actual earthing, but also the M_as "se or something else. 1- the source supplying the anode voltage. Negative triggering pulses can be supplied via the input coupling capacitor 18 to operate the multivibrator I. The control grid resistors 25 and 27 are each connected to the control electrodes 9 and 11 and the negative pole B-.

Since the next following switching stage II in Fig.1 essentially with a level I is identical, have the same parts, the same, with a dash provided reference numbers.

It is common to have the two operating states. such switching steps the To name states or conditions 0 and 1. The tube 3 of stage 1 can for example be conductive while the tube 1 is blocked (state 0), and the tube 3 can be blocked while the tube 1 is conductive (state 1). That about the capacitor 18 input trigger signal is used to reverse the state of the multivibrator I from the state it assumed before the trigger signal. If a square wave input is applied to the capacitor 18, only the negative and not the positive switch Vibrations of the input switch the multivibrator from state 0 to state 1 or from state 1 to state 0. This is why the next following multivibrator stage is used 1I, when connected to multivibrator stage I, is only switched half as often like the multivibrator stage I. This technology creates the well-known dividing chains for frequency division by integers of the second power. However, if a division required by other integers, as in decaders, must be between the aforementioned feedback circuits are provided for the switching stages.

Assume, for example, that in FIG. 1 there is no such feedback connection is present and that both stages 1 and 11 are originally in the 0 state. Everyone negative trigger pulse on input capacitor 18 will make the multivibrators I-11 like press the following (move forward): 0-0, 1-0, 0-1, 1-1, 0-0 etc. This results in a so-called scale-off, so that a further (not shown) stage behind level II would be triggered at a quarter of the level I input number. With Using the more fully described below, between stages II and I. switched feedback path, however, the sequence is 0-0, 1-0, 1-1, 0-0 etc., i. H. a scale-of-three. The one that effectively subtracts an operating state from the sequence Feedback in this case has the 0-1 state between states 1-0 and 1-1 eliminated by creating a division other than a second power. The reason for this elimination of the transition 0-1, explained in detail later, lies in that the transition from the 0-state to the 1-state of stage II served to to bring stage I from the 0 state back to the 1 state.

According to the invention, this feedback path or circuit contains between the anode 5 'of the second multivibrator circuit_od @ r_ of stage II assigned - neten- Röhrel '- and the control electrode 11 of the tube 3 of the preceding multivibrator circuit or level 1 a special type of impedance element. In contrast to the the aforementioned diodes of both vacuum and crystal diodes is the one in the feedback path of the present invention used a non-linear coupling device bilaterally conductive device operated with threshold voltage in both conduction directions Areas has. A preferred embodiment is the cold designated 2 Gas discharge tube with two electrodes, such as a neon tube. The electrode 4 of the neon tube 2 is via a conductor 8 to the anode 5 'of the tube 1' of the second Multivibrator circuit or stage II connected. The other electrode 6 of the Neon tube 2 is connected to the control electrode by a conductor 10 via a capacitor 12 11 of the electron tube 3 of the foregoing circuit or stage I is connected. The neon tube 2 and the capacitor 12 are thus between in this feedback path the anode 5 'of the electron tube 1' and the control electrode 11 of the electron tube 3 connected in series.

If the neon tube 2 is non-conductive, it naturally offers excellent insulation between the anode 5 'and the control electrode 11, since it has a very high impedance. It has also been found that the neon tube 2, when conducting, has a very high inductance, on the order of about 1 henry, which continues to act as insulation. The tube 2 thus insulates both in its conductive and in its blocked state for the two different reasons given above. It should be noted, however, that the electrode 6 of the tube 2 is connected via a resistor 14 to a point with a higher potential than the anode 5 ', namely to the common anode connection 16 of the multivibrator 1I. The neon tube 2 is therefore connected to the anode resistor 21 '. An alternating current coupling capacitor 18 ', which connects via the conductor 20 to the anode 7 of the tube 3 of the preceding multivibrator switching stage I, is also connected to the common anode connection 16 of the multivibrator 1I. If the preceding stage I is, for example, in state 1 and the next stage 1I in state 0, the next negative triggering pulse on input capacitor 18, as described above, will put stage 1 in state 0 and stage II in state 1. If there was no feedback, level 1 would remain in state 0. Since the multivibrator II switches to state 1 with the conductive tube 1 'and the blocked tube 3', the voltage at the anode 5 'drops and a voltage develops at the feedback neon tube 2 which is sufficient to bring the tube 2 into the conductive state Threshold. Part of the voltage drop resulting at the anode resistor 21 'is thus fed back to the control electrode 11 of the tube 3 via the feedback path containing the neon tube 2 and the capacitor 12 and begins to block the tube 3 of the previous stage and thereby stage I when the tube 3 is blocked reset to state 1. As a result of the special type of bilaterally conductive device 2 operated with threshold voltage, this switching back of the control electrode 11 of the tube 3 of the preceding stage 1 is positive and unambiguous. The use of a small capacitance 12, on the order of about 22 fF, supports the development of a high voltage pulse for the decisive reset of the previous stage 1.

When the tube 1 'blocks again, the voltage at its anode increases 5 ', whereby the tube 2 is blocked. The capacitor 12 is charged via the relatively large resistance 14 slowly on again. The retriggering changes of the tube 3 are therefore negligibly small, since only a small amount during this period Energy can be fed back.

The use of the neon tube 2 thus provides excellent insulation during a period when it is non-conductive, and while conducting, and it creates the desired polarity feedback path when switching the second Stage 1I is intended to control and bring about the downshift of the previous stage I. In addition, all of this is done with operational reliability at frequencies or speeds, which the resistance-capacitance feedback technology cannot handle reliably can. In addition, the neon tube feedback is less expensive than the above described diode circuits.

While the system according to Fig. 1 is preferred, the neon tube 2 also lie at other points in the feedback path. Thus Fig. 2 shows the tube 2 with its electrode 6 directly with the control electrode 11 of the tube 3 and with its Electrode 4 via the capacitor 12 and the conductor 10 to the anode 5 'of the electron tube 1 'connected. A resistor 30 is connected to the electrode 4 of the neon tube 2 earth terminal B - connected to tube 2 with resistor 30 as a shunt circuit at the control electrode 11, the resistor 27 and earth to be connected in series.

In the systems of both Fig. 1 and Fig. 2, the operates Circuit as the ionization time after applying a voltage to the neon tube 2 is on the order of about 10 to 25 #ts, best for maximum decade input frequencies on the order of about 40 kHz. So such circles work well in the lower ones Frequency decades of an electronic counter system. However, before the tube 2 in the circuit of Fig. 2 conducts, the voltage available for piston heating remains not constant during the ionization period, but tends to decrease. In Fig. 1, however, holds the tube 1 'for the entire time, since the anode 5' remains negative or until the tube 2 heats up, the tube 2 has the full ionization voltage. The circuit according to FIG. 1 is therefore somewhat more reliable than that according to FIG. 2.

While the invention relates to electron tube circuits has been described, it goes without saying that other types of Relay devices, including, for example, transistors, the new ones May suitably use coupling circuits of the present invention. It can for example high voltage transistors can be used. The system according to Fig. 3 is designed analogously to the system of FIG. 1 with the exception that transistor relays be used. The transistors 103 and 101 'replaced the electron tube relays 3 and 1 'of the series-connected circuits through bases 111 and 109', respectively, the emitters 115 and 113 'and the collectors 107 and 105', which are in one of the Connections of the respective electron tube electrodes 11, 9 '; 15, 13 'and 7, 5 analog way are turned on in the knees.

Further non-linear devices 2, which, in contrast to the aforementioned Diodes are operated with threshold voltage in both directions and are therefore bistable conductive, non-linear devices contain thyrites as voltage-dependent, with increasing voltage, resistances made of semiconductor material and decreasing magnetic substances that are known to be close to their original permeability range can be operated.

Claims (1)

PATENT CLAIMS: 1. Electric binary counter with series-connected Multivibrators whose operating states a predetermined operating state of a bring about the previous stage of the counter, indicated by a bilateral conductive, non-linear switching device, preferably a two-electrode glow tube (2) between successive stages (I, 1I) as an alternating current coupling such it is interposed that it has the input of a stage according to the operating state controls at the output of another stage. z. Binary counter according to claim 1, characterized in that characterized in that the two-electrode glow tube (2) is a neon tube. 3. Binary counter according to claim 1, characterized in that the non-linear switching device is designed as a thyrite device (2). 4. binary counter according to claim 1, characterized characterized in that the non-linear switching device as in its original Permeability area actuatable magnetic device is formed. 5. Binary counter according to claim 1, 2, 3 or 4, characterized in that the bilaterally conductive, non-linear switching device (2) can be operated with threshold voltage and between an anode electrode (5 ') of the first stage (11) and a control electrode (11) of the preceding circle (I). 6. binary counter according to claim 5, characterized characterized in that in series with the switching device (2) a capacitor (12) is switched. 7. binary counter according to claim 5, characterized in that between the anode (7) of the electron tube (3) of the previous stage (1) and a point (16) with a higher anode potential than the connection point of the feedback with the Anode electrode (5 ') of the electron tube (1') of the one stage (11) an alternating current path (20) is provided. B. binary counter according to claim 5, characterized in that one the anode electrode (5 ') of the electron tube (1') of a stage (II) with a Anode resistor (21 ') connecting source (B +) to anode potential, a connection ($) the gas discharge device (2) with the anode resistor (21 ') and one between the anode (7) of the electron tube (3) of the previous stage (I) and a point (16) of the anode resistor (21 ') with a higher potential from the connection point the feedback with the anode electrode (5 ') of the electron tube (1') of the one Stage (1I) lying alternating current line (20) are provided. 9. Binary counter after Claim 5, characterized in that the cathode (15) of the electron tube (3) the previous stage (I) is grounded; while one with the gas discharge device (2) Series-connected resistor (27) between the control electrode (11) of the Electron tube (3) of the previous stage (1) and earth (B -) is located. Into consideration printed publications: Electronics, October 1952, pp. 118 to 121.