DEI0006728MA - - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

Registration date: December 19, 1952. Advertised on November 15, 1956

GERMAN PATENT OFFICE

PATENT APPLICATION

CLASS 21a ¹ GROUP INTERNAT. CLASS H03k

I 6728 Villa / 21a

Maurice Charles Branch, London

has been named as the inventor

International Standard Electric Corporation, New York, N.Y. (V. St. A.)

Representative: Dipl.-Ing. H. Ciaessen, patent attorney, Stuttgart-Zuffenhausen,

Hellmuth-Hirth-Str.

Electronic circuit arrangement for information storage

The priority of the registration in Great Britain of December 20, 19Sl has been claimed

The invention relates to a circuit arrangement for querying by means of a gas discharge or vacuum electron tube stored binary information, at which the stored for the Information characteristic switching status of this tube in one assigned to it Output circuit is determined when a test pulse is applied to one of its electrodes.

There are already electronic circuit arrangements for storing message content known on a binary basis. The switching state of a changed by the storage process Storage element, e.g. B. a gas discharge or vacuum electron tube, is immediately with the storage detectable. But there are also memory arrangements of this type known in which the memory content is only created by creating a test pulse, which causes a current gain in the storage tube, is detected. Such arrangements have the disadvantage that either, if to keep the when checking the current of the im

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Cathode circuit of the storage tube lying resistance compared to the resistance, which is before the storage electrode is, is made large, an output pulse during the storage process is released at the cathode. If you try to avoid this disadvantage, that the resistance in the cathode circuit is selected to be small and therefore that which occurs at the cathode Impulse is kept low, when ίο testing a very high current is set in the tube, through which the limit values of the tubes may be exceeded.

According to the invention, an arrangement is proposed which has the disadvantages mentioned avoids that in the cathode branch of the gas discharge or vacuum electron tube a voltage-dependent Resistance combination is such that the cathode potential is stabilized with low current flow of the tube and only in the case of a current carrying increased under the influence of the test pulse, the resistance the combination assumes a fixed value, so that only when a stored Information a defined output pulse is generated.

The invention is explained with reference to the figures. Here shows

Fig. Ι a known circuit,
2 shows a circuit according to the invention,
3 shows the application of the invention for a four-part memory device using the switching elements in FIG.

4 shows a pulse-controlled storage element,
FIG. 5 shows a variant of the arrangement according to FIG. 4,

Fig. 6 shows a single member of a binary counter, which for the connection between the individual Stages gas-filled tubes are used,

7 shows an individual element of a binary counter, FIG. 8 shows a further circuit arrangement for Pulse counting and

9 shows another embodiment of the invention.

The known circuit shown in Fig. Ι shows the application of a single gas-filled Cold cathode tube as a storage element.

The anode of this tube is connected to + 13OVoIt via the resistor R 1, its cathode to -50 volts via the resistor R 2 and its control electrode is fed via the resistor R 3.

The input is normally connected to earth potential so that the grid-cathode voltage cannot ignite the tube when it is idle. The switching indicator to be saved is represented by a positive potential which is applied to input I and from there to the control electrode (grid) via resistor R 3. This potential is sufficient to ignite the tube solely via the path between the control electrode and the cathode. If a pulse is stored on the tube by applying it to input I, the continuous voltage after the pulses is selected so that the path between the cathode and control electrode remains ignited. The current flow between the cathode and control electrode is in the order of magnitude of a few microamps, so that the effect of this current flow can be neglected.

In the case of such a memory circuit, it is desirable to determine whether the corresponding circuit identifier has been received in the tube. For this reason, a positive pulse P is applied to the anode via the rectifier MR 1. This pulse and the normal anode voltage cannot ignite the tube until an ignition has taken place between the control grid and the cathode. For this reason, the pulse can only ignite the tube when the storage has already been started. When the discharge has taken place over the main section between the anode and the cathode, a higher current flows through the resistors R 1 and R2. In addition, the voltage at the upper end of the resistor R 2 is increased, so that a positive pulse is generated at the cathode. However, no such pulse is generated at the cathode if no discharge has previously taken place between the control electrode and the cathode. The normal voltage between anode and cathode is below the burning voltage, so that the main ignition path is extinguished as soon as the pulse has ended: The fact that the pulse P could be made visible in the tube is a sign that it has been stored.

In order to get a strong output pulse when the pulse P is applied to the tube, the resistance R 2 should be greater than the resistance which is in front of the rectifier MR ι. In practical operation it is difficult to produce a favorable ratio between the values of the resistors in FIG. 1 in order to obtain a powerful output pulse at a low operating voltage.

The arrangement in FIG. 2 avoids these disadvantages in that the cathode resistance R 2 is connected to a voltage which is more negative than that in FIG. In Fig. 2, -100 volts is applied to the end of resistor R 2. The cathode is also connected to a rectifier MR 2, which has a less negative potential than the resistor R2 , namely -50 volts. The purpose of this rectifier is to stabilize the cathode at -50 volts so that the cathode voltage cannot drop below this amount. This means that when the cathode voltage increases to less than -50 volts, the resistance of the cathode is equal to the internal resistance of the rectifier MR2 . If the cathode voltage rises above -5OiVoIt, the rectifier MR 2 is blocked.

As mentioned before, the storage criterion ignites on the path control electrode-cathode, and if the current flow at the cathode is a few microamps, the potential at the cathode remains practically unchanged. If the pulse is applied to input P , the tube will only ignite if a discharge has previously taken place between the control electrode and the cathode

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has. The current therefore flows through resistor R i, the main ignition gap and resistor R 2. This current flow causes a voltage at the cathode of the tube, which increases via —SoVoIt, ie becomes more positive, and thereby the rectifier Mi? 2 blocks. When using dry rectifiers, this takes on a high resistance during the blocking process. Thus the real resistance at the cathode is the same

ίο the value of R 2.

The output pulse arises as before in FIG. 1 via the resistor R2, but with the arrangement in FIG. 2 it is possible to set the resistance R 2 much higher than is possible with the arrangement in FIG. The reason is that the rectifier MR 2 produces an effect which takes into account the variable load on the cathode. This makes it possible to obtain a stronger output pulse while maintaining the voltage limits within the tube.

In Fig. 3, a four-stage memory circuit with the tubes Vi to V 4 is shown. Each link of this memory chain is designed in accordance with the circuit in FIG. Each tube has access with its cathode via the rectifier MR 3 to a common cathode line on which the resistor R 4 and the rectifier MR 2 are connected. The common cathode circuit is arranged in the same way as the cathode circuit for the tube in FIG. 2. The rectifier MR 2 acts as a regulating rectifier for each of the tubes Vi to V4.

Each tube Vx to V 4 has its own input, namely A to D, and the tubes are each checked for their bias voltage so that they ignite at the incoming pulses at the different times P 1 to P 4. For every tube function is the common line across resistor R4 and rectifier MT? 2 effective.

A typical application of such a circuit is the storage of a decade digit on a binary basis. In this case, a tube represents its preparatory section between the control electrode and cathode has ignited, the binary digit 1, and a tube, over its preparation section no discharge has taken place, the binary digit O identifies. If such Circuit containing a large number of such tubes, after which the storage process is queried, at the starting point O a series of impulses arises which converts the coded value of the digit to binary Represents base. The order of checking can be varied in such a way that the pulse series sends out the digits starting with the highest or lowest value.

4 shows a simple pulse-controlled storage element, a pulse applied at point P serving as anode feed, but only becoming effective when the auxiliary path (cathode grid) has ignited beforehand.

5 shows a memory element with a resistor i? 5 and rectifier MR4 lying parallel to it. While there is a relatively negative potential at the left end of this rectifier in the quiescent state of the tube, in this case -50 V, a series of positive pulses is applied to the point / and fed in parallel via the rectifier MR 4 , so that no output pulses arise. However, if the tube has ignited, it will remain ignited when the ignition pulse is applied to point /. The cathode causes the rectifier MR4 to increase its resistance, ie it is blocked, and the pulse series at point / is sent to the output via the resistor R5. The resistor R 5 has a value between the forward and blocking resistance of the rectifier Mi? 4. The cathode circuit in connection with the resistor i? 2 and the rectifier MR 2 operates in the same way as the circuit described in FIG.

The arrangement according to FIG. 6 shows a single link in a binary counting chain in which the gas-filled tube B 3 is used as a coupling element between the individual storage elements. In this circuit, the control pulses are applied to point E and run via the capacitor C ι to the control electrodes of the two tubes. Each pulse applied to point E switches the discharge of the tube. The tube B 2 is ignited by switching means, not shown, before the storage device is put into operation.

An applied pulse causes an idle tube to ignite, and the 95 ■ Lowering its anode voltage causes a negative pulse that is sent to the anode of the other tube is applied across the capacitor C 2. This negative impulse extinguishes the previously ignited tube.

The first applied pulse ignites tube Bx which extinguishes tube B 2. This has no effect on the coupling tube B 3, since the anode of this tube is connected to the anode of the tube B 2 . When the tube B 2 is ignited, the anode voltage of the tube B 1 is kept below the ignition voltage, so that the tube B 3 cannot ignite when the control pulse is received. Even during the pulse, tube B 3 cannot ignite because the time constant of capacitor C 3 and resistors R 6 and Ry is such that capacitor C 3 does not change as much around tube B 3 at the end of the pulse to ignite.

The second applied pulse ignites tube B 2 and extinguishes tube B 1. Thus two pulses have arrived, the binary level is switched to the zero position, and a preparation pulse is necessary. The capacitor C 3 has now changed its charge, so that the pulse ignites not only tube B 2 but also tube B 3. The control pulse for the next stage is taken from the cathode of tube B 3.

The circuit of the tube B 3 is the same as that of the tube in the circuit according to FIG. 2. ■ A pulse is allowed to pass through when the circuit is in zero position, i.e. when the circuit is in zero position. H. if

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the anode of tube B 2 is positive and capacitor C 3 has had enough time to change and a pulse is applied to the control electrode of tube B 3. In the case of odd series of pulses, the preparatory section of tube B 3 ignites,

. however, this has no effect on the output control. In the case of even-numbered series of pulses, a discharge takes place via the main ignition path. Thus, the tube B 3 operates in the same way as the tube in FIG. 2.

'Fig. 7' shows a binary counter in which the preparation pulse is taken from the cathode of tube B 2, which has previously ignited. As previously mentioned, the first pulse ignites tube B 1, extinguishing tube B 2, and the second pulse ignites tube B 2, thereby extinguishing tube B 1. The sudden increase in cathode voltage causes the trigger pulse. The tube B 2 therefore only works in the same way as shown in FIG.

If in the circuit of FIG. 7, the cathode voltage of the tube for generating the trigger pulse is stabilized, can, similar to the circuit of FIG. 6, the shape of the Improve output pulses.

8 shows a counting chain with control and biasing pulses which has a common anode resistance R 8. A tube is initially ignited and each time a pulse is applied to the grids of all tubes, the tube immediately behind the previously ignited tube is ignited. The previously ignited tube is extinguished because the voltage across the common series resistor R 8 drops. In this circuit, the control pulse is sent to the cathode of the previous tube via the rectifier Mi? 5 and to the control electrode of the next tube, which results in a higher control voltage. The connection of the midpoint between the resistors R 7 and R 10 via the rectifier MR6 to earth ensures the bias of the control electrode. If the rectifier MR 7 is missing and there is again a lower voltage at the cathode, the pulse is suppressed if the preparatory section has ignited only as a function of the capacitor C 3. However, assuming the arrangement of FIG. 8, this rectifier Mi? 7 such an undesired impulse is effectively suppressed. The operation of the cathode circuit of FIG. 8 is the same as that of FIG. 2.

Although the arrangements of FIGS. 2 and 8 use the known dry rectifiers as blocking rectifiers, it would also be possible to use heated tubes or voltage-dependent resistors. In Fig. 9 an example of the invention is shown in which the electron tube T ι is used as a blocking element.

. The grid cathode arrangement is used as a diode, with the grid at a voltage of - 50 volts and the output pulses from the Anode can be removed.

In the case of the gas-filled tube V 5, the preparatory section is ignited in order to allow the pulses selected from the points Pa to Pd to pass through. Each of these pulses, when passed, causes the cathode potential of the tube T1 to rise. At the specified voltages, the tube T. 1 carries approximately -50 volts at the cathode in the idle state. When a positive pulse appears at the cathode, the tube is switched off, thereby generating a positive output pulse. In this circuit, the triode T 1 is also used as a pulse amplifier.

Although the circuit arrangements described relate to cold cathode tubes these arrangements are also conceivable with electronic tubes.

Claims (6)

Patent claims: i. Circuit arrangement for querying binary information stored by means of a gas discharge or vacuum electron tube, in which the switching state of this tube, which is characteristic of the stored information, is determined in an output circuit assigned to it when a test pulse is applied to one of its electrodes, characterized in that the cathode branch (Fig. 2) the gas discharge or vacuum electron tube has a voltage-dependent resistor combination (- ■ 100 V, i? 2, MR 2, -50 V) in such a way that the cathode potential is stabilized when the tube conducts less current (storage, cathode grid ignited) and only when the current (cathode-anode ignited) increases under the influence of the test pulse (P) , the resistance of the combination assumes a fixed value (i? 2, MR-2 blocked), so that a defined output pulse is only created when a stored information is queried . 2. Circuit arrangement according to claim 1, characterized in that the cathode of the Tube at the tap of a negative different between two voltage-carrying points Potential (e.g. -50 V and -100 V) lying voltage divider whose on partial resistance from a voltage-dependent resistor with a higher potential There is a rectifier characteristic that is polarized in such a way that it flows through the cross current in the forward direction is flowed through when no or only a very low current in the feed to the tap of the voltage divider flows. 3. Circuit arrangement according to claim 1 and 2, characterized in that as a tension-dependent Resistance a dry rectifier is used. 4. Circuit arrangement according to claim 1 and 2, characterized in that as a voltage-dependent Resistance the grids st «7017/121 Cathode path of an electron tube (T ι in Fig. 9) is used, in which the negative potential (-100 V) is on the cathode and the less negative potential (-50 V) on the grid and at which the output pulses are applied. the anode can be removed when the tube (T 1) is blocked when the cathode potential of the storage tube (V 5) rises. 5. Circuit arrangement according to claim 1 and 2 or 1 to 3, characterized in that a common output circuit with a voltage-dependent resistor combination (R 4, MR 2, 0 in Fig. 3) is provided for several storage tubes (Vi to V 4 in Fig. 3) to which each individual tube is connected with its cathode via a decoupling rectifier (Mi? 3). 6. Circuit arrangement with gas-filled storage tubes according to claim 1 and 2 or ι to 3, characterized in that the binary information is assigned by this Discharges are stored between grid and cathode, and that when applying positive test pulses to the anodes of the individual storage tubes each have a main discharge occurs between anode and cathode, a pulse being generated at the cathode. Considered publications:
U.S. Patent Nos. 2,426,278, 2,533,739. 1 sheet of drawings