DE1042023B - Circuit for sending out a certain number of pulses - Google Patents

Description

In electronic automatic telecommunication exchanges, circuits are very often provided that on send a command a series of pulses with a certain number of pulses or series of pulses and repeat this for some time if necessary. According to a known circuit arrangement this Art, a counting chain consisting of electronic switching elements is used, which is controlled by a Pulse generator, ζ. Β. a multivibrator, which after sending out a desired Number of pulses is blocked depending on the corresponding presetting of the counting chain.

It is also known to use cathode ray tubes with two anodes as switching elements and Assemble counting circuits from cold cathode gas discharge tubes.

The invention relates to a circuit for transmitting a certain number of pulses with a switching tube with a heated cathode, two anodes and a system of electrodes, which a Generate electron beams, which are electrostatically generated by voltages on the deflection electrodes of the interrupter is controlled in such a way that the electron beam automatically alternates between the anodes of the interrupter is tipped over, as well as with counting circuits, consisting of gas-filled electronic switching elements.

The essence of the invention is that for the delivery of pulses in one the number to be sent out Defining impulses, consisting of gas-filled electronic elements with a cold cathode Counting circuit the electron bundle in the interrupter after ignition of a selectable counting circuit element It is continuously overturned by a voltage on a deflection electrode of the interrupter during charging and discharging a capacitor, one lead of which is grounded through a resistor Deflection electrode and the second feed to the opposite anode at the second deflection electrode is connected, and that the voltage at this second deflection electrode, which is from the to the mentioned capacitor is independent, the electron beam after progressive ignition and Successive counting circuit elements go out when the last element is ignited at one of the holds both anodes of the interrupter in place so that the delivery of pulses from the anodes of the interrupter in the counting circuit and the pulse transmission is interrupted.

To tip over the electron beam, a voltage can also be applied to the deflection electrodes of the interrupter when charging and discharging capacitors connected to both deflection electrodes, be used. The circuit can be

Circuit for transmission
a certain number of pulses

Applicant:
TESLA, närodni podnik, Prague-Hloubetin

Representative: Dipl.-Ing. A. Spreer, patent attorney,
Göttingen, Groner Str. 37

Jaroslav Budinsky, Cesky Brod (Czechoslovakia), has been named as the inventor

any number of discharge tubes in the counting chain or be provided with one or more electronic decade counters. In this case it will be when igniting a discharge tube or a discharge path of the electronic decade counter tube further discharge tubes or discharge paths under the influence of pulses from one of the two Anodes of the interrupter ignited progressively until the ignition of the last discharge tube or the last discharge path the electron bundle by a voltage on one of their electrodes, which with a Deflection electrode of the interrupter is connected, held in the interrupter at the aforementioned deflection electrode so that the transmission of further impulses from the anodes of the interrupter is interrupted, of which in the counting circuit with discharge tubes or in the decade counter tube a number of pulses is delivered which corresponds to the number of discharge tubes or discharge paths that hit the first ignited discharge tube of the counting chain or onto the first ignited discharge path of the decade counter tube follow.

The circuit according to the invention leads to a considerable technical advance over the known Arrangements. Above all, it must be emphasized that in the activity of the invention Switching heating current only from the switching electron tube is constantly carried out, while with the known Circuits using vacuum tubes or gas-filled tubes with a heated cathode, heating current is constantly led by all tubes. With a larger number of counting circles, in the known arrangements consumes a considerable amount of heat uselessly. The inventive

839 660/133

Switching accordingly leads to a considerable reduction in power consumption. Besides, the Operational readiness of the circuit according to the invention is higher than that of the known circuits because they are in In view of their small power consumption, it can be kept under tension at all times. Furthermore is the circuit according to the invention is more reliable than the known hot cathode tubes using Circuits, because tubes with a cold cathode have a much longer service life than tubes with a hot cathode ίο sit, so that the susceptibility to failure in the circuit according to the invention with cold cathode tubes is much smaller than with circuits with hot cathode tubes. Finally, the circuit according to the invention is relative simple, since the switching electron tube is directly influenced by the last electronic element of the counting series is, while z. B. in the first-mentioned known circuit arrangement, the blocking of the Multivibrators from the counting circuit is done by two additional electron tubes.

Some embodiments of the invention are shown schematically in the drawing.

Fig. 1 shows a switching tube connected as a pulse generator,

FIG. 1 shows a modification of the circuit according to FIG. 1;

Fig. 3 is a circuit diagram of a glow tube pulse transmitter;

Fig. 4 shows the shape of the transmitted pulses and the starting pulses;

Fig. 5 is a circuit diagram of a key set for transmission of pulse trains;

6 is the circuit diagram of a pulse transmitter with cold cathode triodes, and

Fig. 7 is the circuit diagram of a pulse transmitter with a Dekatron.

For purposes that do not require high transmission speeds, glow lamps can be used in the circuit according to FIG. 3. In the embodiment shown, ten glow lamps are used, but their number can be increased as required. A vacuum interrupter (FIGS. 1 and 2) is used here, the indirectly heated cathode k of which emits a ribbon-shaped electron beam by means of the cathode electrodes k _p. Accelerating electrodes are designated with u , which have one on the potentiometer i? ₃ tapped positive voltage is supplied. The ribbon-shaped electron beam is electrostatically generated by a voltage on the deflection electrodes d _v d. ₂ controlled in such a way that at certain voltages at both deflection electrodes it falls on one of the two anodes a _v a _{2 of} the interrupter. The grid m attached between the anodes a _v a ₂ and the deflection electrodes d _v d ₂ is connected to a high positive voltage and prevents the passage of secondary electrons from the anodes to the deflection electrodes if the electron beam strikes one of the anodes.

In the circuit according to FIGS. 1 and 2, the tube works in a similar way to a multivibrator, in such a way that the electron beam is automatically tipped over between the two deflection electrodes d _v d _o and alternately on the anodes a _v a. ₂ open. The anodes of the interrupter are connected through suitable resistors R ₁ , R ₂ to the source of the positive voltage E ₁₁ , to which the screen grid tn is also connected. In the circuit according to FIG. 1, the anode C _{1 is} connected to the deflection electrode d via the capacitor C. _z connected, which is connected to the middle version of the potentiometer R. One end of this potentiometer is grounded.

It is assumed that the capacitor C is charged to the full voltage E ₀ and that the electron beam is incident on the anode a _% . At the moment when the electron beam hits the anode U ₁ , its voltage changes by the voltage drop across the resistor R ₁ . The reduced voltage is fed via the capacitor C to the deflection electrode d ₂ , at which a negative voltage is formed at this moment. The capacitor C now begins to discharge, and at the same time the negative voltage on the deflection electrode d ₂ decreases. Since the deflection electrode ^ _{1 is} more positive than the electrode d ₂ , on which there is a negative voltage, the electron beam is constantly falling on the anode a _t . As soon as the voltages on both deflection electrodes equalize after the discharge of the capacitor C , the position of the electrode bundle becomes unstable and the bundle jumps over to the anode a ₂ , which has a higher voltage than the anode O ₁ . At the same time, the voltage at the anode a _{t increases} rapidly, and the resulting increase in voltage is fed via the capacitor C to the deflection electrode d ₂ , at which a positive voltage is now built up. When the capacitor C is charged at the same time, the positive voltage at the deflection electrode d ₂ drops until it disappears when the capacitor C has been charged. The electron beam is now again d _t upset in the direction of the deflection electrode and the anode a _t thrown, etc. The electron beam is d in this case by the positive and negative voltage to the deflecting electrode dominates _2, which by derivation of the voltage pulses at the anode a _t arise. The frequency of the impulses arising at the anodes a _v a ₂ , caused by the oscillation of the electron beam, depends on the voltage E _a and the time constant RC . The desired frequency can be set by changing the potentiometer R or the capacitor C. With a suitable choice of the circular constants and the voltages at the electrodes, rectangular pulses with an amplitude of up to 150 V can be achieved at the anodes a _v a _2. According to the invention, these pulses are used to control circuits which emit pulse trains. The circuits according to the invention are further characterized in that the oscillation of the electron beam is interrupted by applying a suitable voltage (approximately 60 V) to the deflection electrode.

The electron tube P also works in a similar way in the symmetrical circuit according to FIG. ₄ and R _{5 are} connected, is mastered. Instead of the resistors R ₁ and R 2 used in the circuits according to FIGS. 1 and 2, _{relay windings (not shown)} can be placed in the anode circuits of the interrupter.

Fig. 3 shows an example of a counting circuit with glow tubes. It is assumed for the time being that the interrupter P is not connected to the counting circuit. The anodes of the individual glow tubes are connected via the common resistor R ₂₁ to the source of the positive voltage E ₁ , which is greater than the ignition voltage of the glow tubes. After connecting the voltage E ₁ , one of the glow tubes, z. B. D ₁ , ignited, the voltage drop across the resistor R ₂₁ prevents the ignition of any other glow tube. At the cathode of the glow tube D ₁ , which is grounded via the resistor R _{1, arises}

a positive voltage, by which the rectifier U _{1 is} blocked, so that the capacitor C _{1 is} charged via the resistor R ₂₁ to the voltage generated at the resistor R _1. If the circuit is through-connected to the glow tube D ₁₀ by the connection xy indicated by dashed lines, the capacitor C ₁₀ charges up, since current initially passes through the rectifier U _{1 in the forward direction.} If a negative pulse is now fed to the input of the counting circuit via the capacitor C ₁₁ , the voltage at the anodes of all glow tubes is reduced and the glow tube D ₁ goes out. When the negative pulse ends, the voltage at the anodes of all glow tubes rises, but only the glow tube D _{2 is} ignited, which is preferred by the voltage on the capacitor C ₁ , which adds up to the voltage E ₁ and the voltage on the Discharge path of the glow tube D ₂ enlarged. Current now flows through the rectifier U ₁ , so that the capacitor C _{1 is} not charged and the rectifier U _{2 is} blocked. This charges the capacitor C ₂ . In the event of a further negative pulse from the capacitor C _11, the glow tube D ₂ goes out, and the glow tube D ₃ is automatically ignited. The glow tubes are thus connected to the associated resistors R ₁ ... R ₂₀ , R _2i ... R ₂₈ , capacitors C ₁ ... C ₁₀ and rectifier [Z ₁ ... i7 ₁₀ after each negative pulse in in the order D ₁ , D ₂ , D ₃ ... D ₉ , D ₁₀ ignited.

It is now assumed that the interrupter P is connected to the circuit according to FIG. 3 (ie that the connection xy is interrupted). The cathode of the glow tube D ₁₀ is connected to the deflection electrode d _{1 of} the switching tube P , the anode a _{2 of which is connected} to the input of the counting circuit and via the resistor R ₂₁ to the voltage B ₂ and the acceleration electrode of which is a positive voltage tapped off by the potentiometer R ₂₉ is fed. In the normal state the glow tube D ₁₀ burns, and the voltage at its cathode resistor R ₁₉ prevents the operation of the switching tube P, in which the electron beam constantly strikes the anode Ct _1, which is also connected to the voltage E ₂ via the resistor R _22. If the cathode of any glow tube is supplied with a steep negative pulse (An Anlaßimplus in Fig. 4) of a very short duration, the amplitude of which is sufficiently large to, for. B. to ignite the glow tube D _c , the glow tube D ₁₀ goes out. This removes the voltage at the deflection electrode Ci _{1 of} the tube P, whose electron beam begins to tip over, and the anode a ₂ sends negative pulses through the capacitor C ₁₁ to the input of the counting circuit. After each negative pulse, the glow tubes D ₁ , D ₈ , D ₉ ignite progressively until finally the glow tube D _{10 is also} ignited. A positive voltage arises at the deflection electrode (I _{1 of} the tube P , which permanently binds the electron bundle to the anode a _t . In the case mentioned, four pulses were emitted before the operation of the tube P was automatically interrupted. The desired number of pulses is thus emitted in that the corresponding glow tube is ignited by a negative pulse passed through the capacitor C _11.

In order to ensure the transmission of the correct number of pulses, the starting pulses must be very steep and have a certain amplitude, and they must be of very short duration. However, the ionization and deionization time must also be taken into account. If the amplitude of the negative starting pulse is too large, the case may arise that the pulse emitted by the i \ node of the switching tube P cannot extinguish the ignited glow tube. It only goes out with a further impulse, so that the correct number of impulses is not transmitted in the corresponding impulse series. With regularly repeated transmission of pulse series with z. B. nine pulses is the frequency of the

ίο Starting pulses selected in such a way that the necessary intervals arise between the individual pulse series, as shown in FIG. In order to prevent the accidental emission of a larger number of pulses than desired, the deflection electrode d _{x of} the switching series can also be supplied with a positive pulse at the same time as the negative pulse, whereby the instantaneous jump of the electron beam into the second position can be prevented.

ao The counting circuit with glow tubes according to FIG. 3 is only given as an example. Any circuit of a counting circuit with glow tubes can be used, provided that a sufficiently positive voltage is created at the cathode of the last glow tube in the counting series after its ignition, which can interrupt the operation of the pulse generator formed by the interrupter P.

According to the principle described, a simple pulse train transmitter controlled by keys can be constructed, the key arrangement of which is indicated in FIG. When one of the keys J ₁ to t ₉ is pressed down, a negatively directed pulse is generated which is sent to the cathode of the corresponding glow tube in the counting circuit and ignites this glow tube, after which the switch tube P sends out the corresponding number of pulses. The amplitude of the starting pulses and their duration depends on the voltage E and the constants R _a , R _b and C _{v of} the glow tube circuits. The ignition of the corresponding glow tube is independent of the time during which the key is depressed, since the starting pulse occurs immediately after the key is depressed. The undesired positive impulses which arise after the key is released can be suppressed by rectifiers (not shown) which are connected in the connections to the corresponding cathodes of the glow tubes in the counting circuit.

The circuit shown in FIG. 6 with cold cathode triodes in conjunction with a switching tube also works in a similar manner. Much higher transmission speeds can be achieved here, which in turn are only limited by the deionization time of the cold cathode triodes used. In the circuit according to FIG. 6, the anodes of all triodes T ₁ to T _{0 are} connected via a common resistor R ₁₁ to the source of the positive voltage Is ₁ , which is lower than its ignition voltage. In the normal state the triode T ₀ burns, at the cathode of which there is a positive voltage, which is also applied to the deflection electrode (I _{1 of} the switching tube P. This positive voltage holds the electron beam at the deflection electrode d ₁ , and it is noticeable the anode a _v Any triode in the counting circuit can

Sg are ignited by a negative pulse on the Cathode or by a positive pulse at the ignition anode, as indicated in Fig. 6 below and above is.

_{It is assumed that the triode T 4 is} triggered by a negative pulse applied to the input 6

Claims (3)

7 8 became. At the moment of ignition of this triode connected and the connection point of the voltage at the anodes of all triodes manufacturing resistors R _s' and i? / Connected Übertraabgesetzt, the voltage of the main discharge path narrowing cathode a negative pulse of a ₂ ago given (cathode-anode ) the triode T ₀ sinks below the value is, when the negative pulse of the Löschspamiung is extinguished, the triode T ₀ extinguishes, and the 5 the discharge at the cathode 6 to the preferred positive voltage on its cathode sinks to zero transfer cathode transferred. At further down after the associated capacitor C ₁₁ negative pulses the discharge proceeds from one discharged through the associated resistor R _k . The directional cathode on the other in the direction of the arrows interrupter P is activated, the electric forward. The zero cathode K ₀ is connected to the deflecting bundle in the direction of the deflecting electrode io electrode d _{t of} the switching tube P , and if the d ₂ overturned and the resulting positive baling - K _{0 is} ignited, the electron beam pulse is from the anode O ₁ is held at the anode a _L via the entrance of the del in the interrupter. In the counting circuit, the ignition anodes of all triodes are supplied. However, if a negative starting pulse is supplied to any one in the circle, only the triode T _{5 is} ignited, the corresponding ignition anode of the main cathode is ignited by the positive voltage from the charge path, and at the same time the cathode of the first ignited triode T ₄ goes out, preferably path A - K ₀ . The interrupter is opened and sends is, so that the voltage at this ignition anode increases negative impulses to the transmission cathodes of the amplitude of the positive impulse, nomotron, in which the glow discharge is progressively not large enough to cause any triode in this way in the direction of the Ignite arrows up to cathode K ₀ . The triode T ₁ goes out, and the voltage 20 is transmitted. As soon as the further positive voltage has preferably built up at the cathode / C ₀ on the cathode of the triode T _{5 , the switching triode T 6 is} in the counting series, which is ignited by a further tube P, whose acceleration electrode is picked up by the positive pulse , etc. The triodes of the potentiometer R _e ' with positive voltage are successively ignited and extinguished in the feed, blocked, and the electron beam remains in the order T _A , T ₅ , T ₆ ... until the sixth pulse 25 in the position O ₁ . the triode T ₀ "is ignited. At its cathode, through regular delivery of starting pulses stands a positive voltage, which allows the oscillation at a particular cathode to be selected of the electron bundle in the interrupter and thus pulse series during a chosen length of time also interrupts the transmission of further impulses. Time to be sent out. The rectifier U, which The negative directional pulses in the input of the counter 30 reduce the amplitude of the starting pulses circle go through the rectifier U ₂ . prevent, are not necessary, if there are impulses The starter supplied to the cathodes of the triodes is available with a sufficiently large amplitude, impulses are sent by the rectifier U from earth to the transmission of more than ten impulses can kept away. If with positive, the corresponding one more than one in known series connections Starting pulses supplied to ignition anodes worked using 35 bound decatrons, is used, the rectifier U _{1 is used} instead of the circuits with glow tubes and triodes with Rectifier U in the cathode circuits. The time cold cathode can be used as distribution circuits. constant of the cathode circuit of the last triode T ₀ , det, if the counting circuits in a circular whose cathode are connected to the deflection electrode d _{1 of} the switching formation, as indicated by the dashed line tube P is connected must be very small. At size 40 lines xy in Fig. 3 and 6 is indicated, and if so Ren transmission speeds must correspond to the connection between the cathodes of the last Cathode capacitor may be switched off, electronic element in the counting chain and the as indicated by the dashed line, around the deflection electrode of the interrupter is interrupted. Quickly hold the electron bundle in the interrupter. Also in the transmitter of pulse trains according to FIG. 6 and to be able to share. 45 you can use any known circuit of a counting circuit Use cold cathode triodes at higher transmission speeds of up to 50 kHz. It is just necessary have to tube in the counting circuit Dekadenzähler with cold dig that is at the cathode of the last triode in the Cathodes can be used, e.g. B. so-called Deka counting circuit forms a sufficiently large voltage that faithful. Remtrons, nomotrons. For the purpose of keeping the electron bundle of the interrupter in the given In particular, such tubes are suitable for the invention. types in which the discharge is only in a Rieh- The described transmitter of pulse trains can device moves, z. B. the nomotron with directional cathodes, advantageously used in electronic registers as indicated in FIG. Ten are denoted by arrows, and they considerably simplify the evaluation of the main or directional cathodes K ₁ to iC ₀ and ten of the registered numerical information. These circles of transmission cathodes are alternating in a 55 can also be used in all fields of telecommunication technology circular formation in a common KoI- and in all cases in which a 'certain impulses are attached. The directional cathodes are in such a row, started by a starting pulse, and emitted in such a way that the discharge is to be used in one of them,
strong ionization in the space between the
Transfer cathode and the directional cathode only in 60 one direction. For example, if the discharge path is patent claims:
between the common, across the resistor R ₅ Anödet connected to the voltage E ₁ and the 1st circuit for emitting a certain Directional cathode 6 ignited, then the number of pulses with an interrupter is triggered by the Ionisa tion coupling the transfer cathode between the 65 heated cathode, two anodes and a system Directional cathodes 7 and 6 are preferred. The ignition voltage of electrodes that create a bundle of electrons This transfer cathode will be much smaller than the testify that electrostatically through voltages Ignition voltage between the directional cathodes 8 and deflection electrodes is controlled in such a way that the 7 or 5 and 6 lying transfer cathode. Electrons automatically alternate on the As soon as the anodes of the interrupter is tipped over on the inside of the flask among each other 70, as well as 1 U4Z ΌΖ2 10 with counting circuits, consisting of gas-filled electronic switching elements, characterized in that for the delivery of pulses in a counting circuit which determines the number of pulses to be transmitted and consists of gas-filled electronic elements with a cold cathode, the electron bundle in the interrupter is continuously overturned after ignition of a selectable counting circuit element a voltage at a deflection electrode (d ₂ ) of the interrupter when charging and discharging a capacitor (C), one of which is fed to the deflection electrode (d ₂ ) mentioned, which is grounded via a resistor (R ), and the second feed to the opposite anode ( %) is connected to the second deflection electrode (^ ₁ ), and that the voltage at this second deflection electrode (^ ₁ ), which is independent of that on the mentioned capacitor (C), the electron beam after progressive ignition and extinction of successive counting circuit elements during ignition of the last element on one of d en both anodes (a _v a ₂ ) of the interrupter, so that the delivery of pulses from the anodes of the interrupter in the counting circuit and the pulse transmission is interrupted. 2. A circuit according to claim 1, characterized in that the electron beam is overturned by a voltage on the deflection electrodes (d _v d ₂ ) of the interrupter (P) when charging and discharging capacitors (C) which are connected to both deflection electrodes (Fig . 2). 3. A circuit according to claim 1 or 2 with any number of discharge tubes in the counting chain or with one or more of electronic decade counters, characterized in that when igniting a discharge tube or a discharge path of the electronic decade counter tube further discharge tubes or discharge paths under the influence of pulses from one of the two anodes (C ₁ , a ₂ ) of the interrupter (P) are gradually ignited until, when the last discharge tube (D ₀ , T _n ) or the last discharge path is ignited, the electron bundle is triggered by a voltage on one of its electrodes, which is connected to a Deflection electrode (Ci ₁ ) is connected to the interrupter, is held in the interrupter at the aforementioned deflection electrode (^ ₁ ), so that the transmission of further pulses from the anodes (C ₁ , a ₂ ) of the interrupter is interrupted, from those in the counting circuit _{with discharge tubes (D 1} to D ₀ , T ₁ to T ₀ ) or in the decade counter tube a number of pulses is supplied which corresponds to the number of discharge tubes or discharge paths that follow the first ignited discharge tube of the counting chain or the first ignited discharge path of the decade counter tube. Considered publications:
U.S. Patent No. 2,536,035;
Telecommunications, Issue 7, July 1955, pp. 301 bis
303 For this purpose 2 sheets of drawings