DE1207673B - Adding machine - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. CL:

Number:
File number:
Registration date:
Display day:

G06f

German class: 42 m-14

I 207 673

B77412IXc / 42m
June 25, 1964
December 23, 1965

The invention is in the field of improvements in electronic circuits in which Cold cathode tubes are used and relates, among other things, to the problem of a method indicate the service life and operational reliability of such tubes and circuits extend. The invention also relates to devices for practicing this method.

Circuits with cold cathode tubes, for example as trigger tubes, as counter tubes or the like, often have to be in a standby position for long periods of time. Often one or more of these tubes must be in such circuits during their standby position Conduct electricity. Most of the tubes in readiness are, however locked until a signal arrives. However, while in some circuits a certain The tube always carries current during the standby state, another of a number can be used Tubes belonging to tubes in other circuits are current-permeable during the standby state be.

An important disadvantage associated with the use of such tubes, and a disadvantage at the same time of the whole electronic circuit in question is that these tubes are proportionately age rapidly, especially if the tubes are used frequently during the standby state are current-permeable. This means that the properties of the whole circuit are already after change in a relatively short time and the circuit may therefore become unreliable. this naturally provides for the use of such tubes in high-speed counters and calculating machines is a serious disadvantage, since in counters and calculating machines of this type an unchanged exact working method is required for long periods of time.

In developing the invention, it was rounded off that cold cathode tubes were much slower old when the standby state is frequently interrupted by intervals of normal tube use will. Furthermore, it was found that those associated with frequent normal use Advantages, d. H. a slower aging can be achieved when the standby current in the live tubes pulsed {d. H. "Pulsed"). However, when signals a circuit to accomplish a pulsed keying of a tube are fed, which in the the respective standby state carries electricity, so is the calculating machine

Applicant:

Bell Punch Company Limited, London

Representative:

Dr.-Ing. E. Sommerfeld and Dr. D. v. Bezold,

Patent Attorneys, Munich 23, Dunantstr. 6th

Named as inventor:
Norbert Kitz,
John George Lloyd,
James John Drage, London

Claimed priority:

Great Britain 26 June 1963 (25 377)

it is difficult to restore the circuit to its original state without delay, required for normal use.

According to the invention it is proposed to periodically complete a full cycle of short pulses to generate and this series of pulses during the circuit or the tube in question of the standby state so that the circuit or the tube transmits this series of pulses. The number of pulses within the cycle or series of pulses is chosen so that the circuit always returns to its ready position to terminate the pulse train. if for example a series of ten ring counters or a single decatron type counter is used, each pulse train would consist of ten pulses.

The pulses are preferably implemented as pulse trains or pulse trains with constant intervals generated, each pulse train comprising a complete pulse cycle, and one can hence say that a train of impulses is periodically "recirculated" during the standby state. In such a case, the repetition period or recirculation period should be compared to the duration of the pulse train must be long enough so that there is a minimal delay when the machine is supposed to operate normally. So it has to be on it care must be taken that the repetition or

509 759/474

3 4

Circulation cannot take place before the circuit is actually in its standby row, in which a multi-digit number is located, so that the circuit cannot be keyed in for alleles and the one switch arrangement is switched on to its normal operation before he control, which in turn has returned the number of pulses in the ready state. 5 successive pulse trains determines which If the normal input signal is generated by a long pulse generator and supplied via a device that works together, for example, from a common pulse input line counters that can be incremented by the pulses, the normal mode of operation is required to be fed to the machine without interruption. Such a machine will be with the. If, however, a fast-working advantage further features that the row of keys is used under direction, it may be necessary to control by a first clock, which is to use a buffer in which the pulses generated by the pulse generator are gradually stored chemically the input signals are, until it is switched, one after the other with a Einsie recirculated circuits and tubes can be coupled again direction, which the supply of are ready for operation. 15 pulses from the pulse generator to a common-It can control a typical calculating machine with the same pulse input line, which under an electronic register according to the invention with control by a second, through pulses from the devices for periodic generation of a pulse generator step-by-step clock pulse series during the standby times and transmitter device can be connected one after the other to the counters with devices for simultaneous supply, and that an arrangement of these pulses provided to each register stage is equipped in order to additionally increment one of the clocks so that this stage supplies a complete working pulse and the Clock sequences run through the clock cycle and shift again in their readiness transmitter against each other in such a way that the state returns. In this case, each row of buttons for controlling the pulse feed pulses, which can be used for different counters while the 25 is being applied, is suppressed if register levels are already generated. It has also been proposed. The application of the invention, the pulse generating devices generation on such a machine is subsequently stopped when an input signal from one of the to be explained in more detail, but unless stages is received. The pulse generation has already pointed out that these devices are not shut down before only one embodiment or application of each register stage goes through its working cycle example of the invention,
Has. The register stages can multi-cathode start. 1 illustrates a block diagram of a pointer tube, ring counter circuit, or combination calculator that has been improved in accordance with the present generation of ring counter circuits and display inventions. In this fig. 1 should contain tubes. ₃₅ to the figure part 1 a at the point of to the right It is often possible, however, to achieve the advantages according to the directional, arrow-provided unmark of the invention when the ring counter Neten line, which is from the connecting line of the or another circuit that switching elements SG1 and SG2 branches off, the middle one single known trigger tube always carries current during the unmarked line on the left side of the standby state. In this 40 switching element PG in Fig. Ib connected in the latter case, only this current-carrying tube must be the. Pulsed to the right of the vertical to the right, ie impulses are applied. Side of the figure part Ib located vertical. 1c tube is, according to this aspect of the invention, the part of the circuit arrangement shown and achieved in that one consists of two elements;

standing trigger circuit from this current-carrying- F i g. 2 is a single circuit diagram of a portion of the clock generator TR, along with additional circuit diagrams, of the tube and a similar auxiliary tube. The auxiliary tube is preferably so elements that are shown schematically in Fig. 1 switched that they are for a significant part of the.

Cycle conducts electricity, but does not conduct electricity 50 The calculating machine according to FIG. 1 contains ten

can when a normal input signal from the rows of keys or groups of keys, each of which

mentioned ring counter is received. is assigned to a digit or decimal place.

According to another aspect of the invention, only the first three rows of keys IK,

electronic circuits or machines with 2 K and 3 K and the last two rows of keys

Ring counters for driving register stages DA 9 55 K and IQC in FIG. 1. The register of

be improved by having a trip machine containing twelve counters, ten of which are den

circuit with ring counters, as described above, mentioned ten rows of keys are assigned

used and a pulse from the trigger circuit can. Of these counters only the first are

relates. This pulse is then converted into a number of three counters 112, 2 R and 3 R and the last four

broken down by sub-pulses, which is just enough to add 60 counters 9R, 1OR, UR and 12R in the drawing

each register stage is represented by a complete cycle. The two counters 11J? and 12R

to run. These carry pulses from the counter 10i ?, and

The impulses obtained are transferred to the register levels of these two counters, i.e. the counters Hi? and 12 R,

fed at the same time. cannot be assigned to any key row. Man

A case in which the aforementioned 65 sees that the number of rows of keys and the

Age problems are important and in which counters are even greater than in Fig. 1.

chem the invention can be applied advantageously set, can be chosen to any desired

can, however, is an electric desktop calculator with the capacity of the machine to be obtained

5 6

normally the number of counters by two larger row of keys consists of nine keys beginning with 1

chosen as the number of rows of keys, numbered from one to 9, with all keys starting with the

To be able to record a carry value, which is assigned from ordinal number 9 to a common line.

are linked to the counter assigned to the highest row of keys, all keys with the ordinal number 8

is delivered. 5 also through a common line.

Each counter is preferably connected in the form of one another, etc. The operation of a known ring counter is carried out. This well-known key within a row of keys be ring counter has a multi-cathode counter tube, the connection of the relevant connection with cold cathodes acts as a display tube and a line or ordinal number line, as these lines are to be called from io gen in the following, with each one with one cathode of the display-related iCG gate. If no key is pressed, the tube is connected in such a way that the display tube is opened, a negative cathode, which is supplied with a current-permeable triggering voltage, is applied to the relevant G-gate. The ordinal number lines tube is connected, glows and when received are connected to a pulse generator PG , which deletes an input pulse, the respectively current-permeable 15 a clock oscillator or control oscillator, and the next endurance, which in turn ignites the pulse repetition trigger tube. Such a counter can determine frequency and which ten outputs have the further special characteristics that one of terminals 0 to 9 has. Corresponding display tube pulses with longer deionization times than this generator occur at these outputs, the trigger tubes are used and each cathode 20 is stuck to the trigger electrode on the duty cycle for corresponding time intervals of one type of display tube. The pulse generator PG has the next cathode of the display tube associated with an output terminal Z, to which nine nth trigger tube is coupled in such a way that voltage pulses occur during each operating cycle, voltage fluctuations which occur at the anode of these nine pulses at one time , in which the pointer tube after the discharge between 25 the output terminals P1 to P 9 are energized. These its anode and its cathode occur times the records still fließen- to as tPl to TP9 leg follow this latter cathode, and accordingly, also the time the Entionisierangsstromes to the trigger electrode in which the terminal PO is energized, as TPO beder the next trigger tube can be transferred,
will. 30 You can see that the output terminal PO with all

Each of these known ring counter is connected in the line to the associated ordinal number is Schlos circuit according to Fig. 1, an input gate assigned Senen rows of keys IK to 10 K. Demnet. The input gate for the first three counters is output terminal 1 with all Ii ?, 2R and 32? are labeled IRG ₁ 2RG and 3RG buttons connected to ordinal number line 8. The input gates for the last four ₃₅ connected, etc., so that the output terminal counters 9 R to 12 R are marked with 9RG to 12RG be P 8 with the key 1 above the ordinal number. The line 1 not shown in FIG. 1 is connected.

Counters 4 R to 8jR are also not included. The mode of operation of the machine is essentially

provided input gates ARG to 8RG borrowed by two clock generators TR and TK and one

equips. 40 control counter CC determined. Any of the clocks ti?

Each of the input gates li? G to 12i? G and TK can, for example, take the form of a logical AND stage from a ring counter. The input consist and with a number of output gates 1.RG has an input terminal H and terminals are provided with the clock generator a second input terminal Tl. The output TR are designated with Γ0 to Γ12 and the terminal of the gate IRG is on the counter IR on ₄₅ clock generator TK with ti to tl2. Each of the clock generators is closed and delivers a signal to this counter, is switched forward by means of input pulses if a potential increase at both input terminals and therefore delivers successively at its output increase, ie a signal occurs. So if there is a positive potential. For example, the input terminal H delivers a positive pulse, the clock TR appears to be a positive pulse, while at the same time the input _{terminal 50 of} the terminal Γ0, and this positive potential at T1 is excited, the counter IR disappears by one of these terminals when the clock unit is switched on. receives a new input pulse. At the same time with

In addition, the rows of keys are assigned to the disappearance of the positive potential at the gate IKG to 10 ^ G. The drawing terminal Γ0 shows a positive potential on the display again the gates IKG to 3KG for the ₅₅ output terminal Γ1. The input pulses are key rows IiC to 3 K and the gates 9KG and the clock Ti? from the output terminal P 9 10 KG for the rows of keys 9 K and 10 K. These of the pulse generator PG via a differentiating gate are also logic AND stages, and up and reversing stage KD 2 , which is used for a common output line K of these gates, Delayed pulses, referred to as dP9 , so a signal occurs when both input 6 are ₀ to deliver. Another input pulse of the clamps are excited at the same time. Each of these clocks TR occurs at an input terminal ST2 with an input terminal on the gate, and the output voltage is connected to the row of keys that hit the output, while the terminal Γ 0 of this clock remains until the other input terminal for gate 1 AG with ti positive pulse of the input terminal ST2 and for the gate 10 KG with ilO. 65 is performed. As long as this positive pulse continues at the intermediate gates on their respective terminals ST 2 , the clock TR because the second input terminal can use the corresponding input designation, that is, the designation 12 to t9. Each pulse dP 9 can be switched on so that subsequent

connected to each other at its output terminals Γ 0 to T12. When the two mentioned clock output pulses occur. While each employer is switched on, the key cycle of the pulse generator PG is thus connected to a row 2K with the counter 2R and so on, until the other output terminal of the clock TR finally reaches the key row 10 K with the counter output voltage. So the clock generator TR becomes S 10i? connected is. However, if, for example, the pulse generator TK is on its output terminal t2 for thirteen work cycles, rators FG from its output terminal TO until while the clock TR is switched to its output terminal T12 . output terminal Tl is located, the row of keys is set. These output terminals are connected to the input 2 K with the counter Ii? tied together. Among these, the input gate IRG clamp to 12RG which io conditions, the row of keys 3K are provided with the respective same reference numerals counter 2R connected etc., that is, that as the output terminals of the clock generator TR, comparable row of keys 1OK to the counter 9 R connected tied. In addition, the output terminals of the will.

Clock TR still connected to other gates The various counters IJ? to be 12 R.

den, as indicated by the labeling with the reference 15 pulses during the corresponding T times of

characters TO to Γ12 are fed to these latter gates on a common input line H ,

is interpreted. which from the exit side of an OR gate

The clock generator TK is constructed in the same way as GlO is fed. The OR gate G10 has

the clock generator TR, but with the exception that ten input terminals, which are connected to the output

it contains only twelve steps instead of thirteen. The clock 20 terminals of AND gates Gl to G9 and GIl

transmitter TK is made with the help of input pulses that are connected.

are supplied via an OR gate TG 3, further. It can be seen that each of the gates Gl to G 9 is disconnected. This OR gate has three input terminals or one input terminal labeled FO, which has a wide range of output terminals or one input terminal labeled Z ren three AND gates TG 4, TG S and TG 6 and that also some these gates are still bound to one. The AND gate TG4 has two input input terminals KA or one input terminal KB output terminals, one of which has the delayed output. Those gates that have input terminal output pulse dP9 of stage KD2 and whose men FO have the task of feeding the output terminals T1 to T12 of the pulse to line H when the other clocks TR are connected. Thus, the 30 input terminals of this gate are energized. In a similar clock generator TK, provided that the clock generator TR does not have the same way, those AND gates which currently have the output pulse at its terminal TO with Z input terminals, which delivers nine pulses of the line during each work cycle of the pulse task H , generator PG will be switched one step forward when its other input terminals are energized. Since the pulse generator TK cannot be switched forward, the gates with the input terminals KA and KB can be switched, while the clock generator TR has the task of supplying as many pulses to the line H at the output terminal TO as the values of the actuated outputs , also thirteen working cycles of the keys in the key rows IK to 10 K pre-pulse generator PG are required to write the clock. Terminals KA and KB are to be connected through with TK to output terminal 1 12. 40 the output terminals of a bistable stage KC The task of the AND gates TG 5 and TG 6 is connected, and in the idle state their output is excited , a further pulse to the clock TK terminal KB. The bistable stage KC can, depending on certain conditions, during the duration of the but by means of an input pulse, which is supplied via output pulse TO. These latter two- a differentiating and reversing stage KDl the gates will now run even more precisely in the following, be switched over, and the input-described signal for this stage KDl is indicated by the output

The output terminals to ilO of the clock output signal of an AND gate IvGl are supplied. One

TK are with the input terminals of the gate IKG the input signals of this AND gate is from

connected to 10JfG, as supplied by matching the line K and the other by one

Reference numerals on the left input terminal 50 Klemmet, the task of which is described below

clamp this gate and the output clamps will be ben. The KC level is in its rest

of the clock TK is indicated. Return other connections with the help of a second input line.

applications of the output terminals of this clock TK provided, which from the output terminal F 9 of the

are also by attaching this reference pulse generator FG over the differentiating and

characters ti to ill at input terminals of inverted 55 level KD 2 runs. The effect of the

various other gates indicated. Stage KD 2 is that the trailing edge of a

It can be seen that in the case of the pulse supplied by terminal P9 , the circuit resets each counter, one after the other, KC to its idle state. In a similar way connected to the line H for a period of time, the effect of the differentiating is, during which the output terminal of the clock 60 and reversing stage KDl is that the feedback TR is energized and that each row of keys with the edge of one of the input terminals K des AND gate of the line K in sequence for a period of time .KGl supplied pulse, the stage KC is connected from its, during which the corresponding idle state is transferred to that state is excited in the output terminal of the clock TK. which at the output terminal KA is an off. If the clock TR occurs at its output voltage.

Terminal T1 supplies voltage during the clock cycle. To explain how the pulses hit the counters

transmitter TK sends an impulse to its terminal il under control by the keys of the key rows

ready, the row of keys 1 £ on the counter Ii? IK to 1OK are supplied, it is assumed that

that the key 6 in the row of keys IK has been pressed, that the clock generator TjR is on its output terminal Tl and that the clock generator TK is on its output terminal ti . The actuation of the key 6 in the row of keys IK connects the output line of this row of keys with the output terminal P 3 of the pulse generator PG. Since the clamping part is energized, the pulse P3 of the pulse generator occurs on line K. It is also assumed that the terminal ./4 is excited, so that the pulse P 3 passes through the gate KG and that accordingly its trailing edge reverses the bistable device KC , so that it gets into the state in which at its output terminal KA a Tension occurs. It is also assumed that the terminal M, furthermore the plus terminal and the terminal Y of the gate G 6 are excited and that accordingly this gate opens when the terminal KA is excited, so that the remaining pulses which occur at the output terminal Z of the pulse generator PG , reach line H via the OR gate GlO. The period of time during which the terminal KA is excited is such that six pulses appear at the output terminal Z of the pulse generator PG during this period. Since the terminal Tl is excited, these pulses flow on the line H via the AND gate RG on the input side of the counter Ii? to. As a result of the actuation of key no. 6 in the row of keys IK does the content of counter 12 increase? by six units.

In order to ensure that the number registered in a counter increases by one unit each time the counter of the next lower row of keys goes through zero, a carry memory CS is provided. This carry memory is a bistable stage which is set by a pulse fed to it via a line C when a counter goes through zero. When the carry memory is set, its output terminal CSO is energized. The bistable stage is reset by a pulse PO at the beginning of each cycle of the pulse generator PG. However, the circuit is made so that the output terminal CSO of the carry-over memory remains energized for a short period of time after the arrival of the pulse PO, by which it is supposed to be reset. The output terminal CSO is connected to one of the input terminals of the AND gate G 9, the other input terminals of this gate being formed by the output pulse PO of the pulse generator PG and by the signal at a terminal TX, which will be described below. If the terminal TX is energized, a pulse PO will appear on the line H if the carry memory has been set during the previous cycle of the pulse generator PG. A carry pulse is therefore fed to one of the counters 2 R to 12 R during the period of the clock TR if the input gate RG of this counter is open and if the carry memory has been activated during the previous period of the clock TR. Thus, for example, a carry pulse is fed to the counter 2R during the period T1 if the carry memory has been activated during the period T1. The only counter that can receive pulses and therefore the only counter that can go through zero during the period T1 is the counter Ii ?. Therefore, the counter 2 R can only receive a carry pulse from this counter Ii? and every other counter can only accept a carry pulse when the next lower counter has passed through zero.

The switching elements described so far represent the majority of those switching elements

ίο which the machine needs to carry out addition and subtraction processes. When the machine is used to perform multiplication or division operations, the clocks TR and TK must go through a number of cycles and a control counter CC is provided to control these working cycles. The control counter CC has eleven output terminals, which are indicated by Cl to C. 11 A bank or series of multiplier keys MK is provided to carry out a multiplication, and each of these multiplier keys is assigned to one of the output terminals C 3 to ClO of the control counter. Each of these multiplier keys connects to the corresponding output terminal of the control counter CC when pressed

as the output terminal MR of the multiplier key row. When the multiplier key 1 is operated or when none of the multiplier keys are operated, the output terminal TO of the register clock generator is connected to the terminal MR . Normally the output terminal Y, which is connected to the multiplier key 0, is at positive potential; however, when the key 0 is operated, the potential of the terminal Y becomes negative.

The pulse generator PG contains a ten-cathode counter tube which is controlled by a 4 kHz blocking oscillator, the anode of which is connected to a terminal oscillator. Normally, the pulse generator PG oscillates continuously after the calculating machine has been switched on. However, the pulse generator can be shut down when a control signal is supplied from the output side of a gate SGl Still setting or a setting Still gate SG. 2 Each of these gates is an AND stage, and it can be seen that the input signals for the shutdown gate SGl are supplied by the terminal TO, tll and by a terminal ST3 , which in turn will be described below. The input signals for the shutdown gate SG 2 are supplied by a terminal M, by the terminal MR and by a terminal ST 3. Assuming now that the terminals M and ST3 are energized, the pulse generator is stopped when a positive potential is applied to the terminal MR . As explained above, the terminal MR is connected to a specific output terminal of the control counter CC by the actuation of a multiplier key. Accordingly, the pulse generator is stopped when the clock TR has run through a number of work cycles corresponding to the ordinal number of the actuated multiplier key.

The control counter CC can be a ring counter of the same design as the clock generators TR and TK . It is switched forward by means of input pulses which originate from an OR gate CGI. The two input signals of the OR gate CGI are supplied by the output terminals of the two AND gates CG 2 and CG 3. It can be seen that the input signals of the AND gate CG 2 through the

509 759/474

Terminals Γ12 and M are supplied and that the input signals of the AND gate CG 3 are supplied from the terminals CGO, TO, DG and ST3. During the multiplication process, the terminal M is energized and accordingly the control counter is incremented each time the clock TR passes through T12 .

It has already been mentioned that each row of keys can be connected to each of the counters, since the clocks TR and TK do not have to work synchronously. However, errors would be carried into any calculation in which a row of keys is associated with a counter of a higher order than that of the row of keys. A bistable stage BA is provided in order to avoid such an assignment. This bistable stage has two output terminals A and ~ Ä. Usually the output terminal A is positive and the other output terminal is negative. However, the bistable stage can be set or activated by means of an output pulse of the clock generator TK , which in turn occurs at the end of the period ill. When the stage is activated, output terminal ~ Ä is energized and output terminal A becomes negative. The stage is reset by means of an input signal from the clock TR , which in turn occurs at the end of the period TO . It can be seen that the terminal A supplies one of the input signals of the gate KG1 , so that no key can influence the output signal of the bistable stage KC after the end of the period t11 . Therefore, under normal circumstances, no pulses can be transmitted or passed on from the keys after the period ill has elapsed.

If the machine is used for division, another bistable stage BC is required. This latter stage takes effect only when the calculating machine is used for division purposes and has the task of determining whether the divisor is added to the dividend or subtracted from the dividend. This bistable stage has two output terminals, one of which is labeled C + and the other with C-. In the reset state, the output terminal C- is positive, and in the set state, the output terminal C + is positive. The bistable stage is activated or set every time the control counter CC is switched forward, and is reset by the back front of the next ΓΟ pulse from the output side of the gate TG 3.

The calculating machine described here is suitable for performing additions, subtractions, Multiplications and Divisions. The various functions are selected with the help of toggle switches. These switches are not shown in the drawing, but can have positive potentials to the terminals specified in the following table.

Addition M +

Subtraction MS

Multiplication M +

Division D +

When the calculating machine is on hold, the pulse generator PG runs and delivers its normal ten pulses during each working cycle. However, these pulses are initially not effective because the clock generator TR is on its terminal TO and accordingly none of the gates IRG to 12 RG are open. The clock TR remains in its position TO by virtue of a negative voltage supplied to its start-up contact ST 2. Further negative potentials are fed in via a start-up contact ST1 . This start-up contact STl has the task of holding the control counter CC in its position Cl , and a third start-up contact ST 3, which is also supplied with a negative potential

ίο has the task of closing the gates 5Gl, SG2, CG 3, TGS and TG 6 .

When the calculator is first turned on and warmed up, it is in a Stand-by position in which every counter in the register is zero. After adding a number to the Register has been entered, the machine waits in a second standby position in which the mentioned number remains in the register. There is therefore a possibility that the machine will last for a long time

so must remain in readiness for periods of time any of the tubes associated with a particular digit in a meter is carrying power.

The clock generator TR has an output terminal TO which, when the machine is in the ready position, is held at positive potential, and since this clock generator is a ring counter which returns to a zero position or ready position, a cold cathode trigger tube that corresponds to the output terminal TO , be live during every standby time. Although the pulse generator PG oscillates normally in the standby state and the pulses dP9 are fed to the input side of the clock generator TR , this clock generator is not switched forward until an activation signal occurs at the terminal ST 2 , which in turn is supplied by a starter switch that is activated when a key is pressed is closed.

From the foregoing it should be apparent that the registers Ii? to 12R and the clock TR must be in their standby state for a long time, since each of these stages contains a cold cathode tube which carries current in the standby state.

According to the invention, a circuit T 0 'is therefore provided which contains a cold cathode tube which is connected to the stage TO of the clock generator TR and represents a bistable stage and is switched by the pulses dP 9 . If the output signal of terminal Γ0 remains positive for a considerably longer period than would be the case during normal use of the machine, the circuit Γ0 'is made operational by the next pulse dP9 and, after it has been ignited, the tube is connected to terminal TO turned off. However, the next terminal is Γ0 supplied pulse DP9 the tube re-ignited, and the tube in the circuit TO 'will be deleted, has passed again to the above-mentioned further period of time. A delay gate prevents the circuit Γ0 'from being influenced by the output terminal TO until the oscillator which controls the pulse generator PG has adjusted to its correct frequency after it has started to run. The input signal OSC supplied by the oscillator is used for this purpose. The output terminal of TO 'is excited as long as the tube in TO' carries current, and this output signal is amplified by an amplifier AMP , from which a positive output

output signal is supplied to all output terminals Π to T12 of the clock TR , furthermore a positive output signal RP is obtained and finally a negative output signal TX is obtained.

Thus, one of the desired advantages is achieved, since the tube in the part TO of the clock TR no longer has to carry current continuously in the standby state. The service life of the clock generator TR is therefore considerably extended.

When the output signals Tl to Γ12 of the clock TR have become positive due to the passage of current through the tube in the circuit TO ' , the register gates IRG to 12RG are opened simultaneously, so that all pulses which occur on the common line H are allowed through. Since the calculating machine is in the standby state, no normal pulses occur on the line H , but according to the invention, recirculation pulses are fed to this line via the AND gate GIl. The AND gate GIl has two input terminals, of which the input terminal - Gu receives pulses from the oscillator which drives the pulse generator PG and from which the input terminal RP is fed by the amplifier AMP. The input signal at the terminal - GD is a negative pulse, which comes from the output terminal OSC of the pulse generator PG and is primarily used for pulse shaping and supports the closure of gates Gl to G 9 at the end of each pulse. This pulse course is shown in the form fed to the gate GIl, since the parts of this pulse course running in the negative direction keep positive output signals from the gate G10 away from the line H. As a result, the positive pulses at RP are chopped up by the curve -GD in the AND gate GIl into exactly ten pulses, which arrive at the OR gate GlO and therefore also occur on the line H. Since all gates 11? G to 12RG are open, the ten pulses are simultaneously fed to each counter in the register, and in the standby state each counter will therefore periodically run through a full operating cycle with a recirculation frequency which is established by the bistable stage formed by the tubes Γ0 and TO ' , is determined. If, as assumed, the oscillator runs at a frequency of 4 kHz, each pulse train of ten pulses has a duration of about 2.5 milliseconds, but the ratio of pulse duration to pulse pause is the bistable stage, which is formed by TO and TO ' so large that the recirculation period is between 15 and 35 milliseconds. This dimensioning of the ratio of pulse duration to pulse pause has the double advantage of reducing the probability of a delay between the reception of an input signal and the advancement of the clock TR and of reducing the background glow as a result of the passage of pulses passing through the register. On the other hand, the time interval between the recirculation pulses cannot be extended indefinitely, since the advantages of the recirculation are to a certain extent proportional to the recirculation frequency.

Certain additional precautionary measures must be taken to prevent the machine from starting up unintentionally. For example, if all counters Ii? until 12 R are initially zero, an output on line C will be generated by each counter when the tenth pulse is received and the voltage pulse on line C will therefore be much larger than normal and could cause carry memory CS to fail. A limiter stage L is therefore provided in the input line C of the carry memory CS . However, if an economical limiter stage, for example a

ίο Zener diode is used, the pulse is broadened and there is a risk that it overlaps the pulse PO used for resetting. The carry memory could therefore not be properly reset, with the result that a traceable pulse PO is fed to the gate G 9 and finally reaches the register stages when the calculating machine immediately begins a calculation process. In order to suppress a noticeable pulse of this type, the output signal TX of the amplifier AMP is fed to the gate G 9 in the sense of a locking of this gate. When the machine performs an arithmetic operation, there is no output signal from the amplifier and the output signal at the terminal TX becomes positive, so that normal carry pulses are transmitted via the gate G 9 to the OR gate GlO. On the other hand, during the recirculation and in the standby state, all carry pulses from CS are blocked by the gate G9 , since the output voltage on the line TX is then negative. This lead slowly goes positive at the completion of 0 and the rise is slow enough to prevent the application of a P0 carry pulse during period Π immediately following recirculation.

It is possible that the increase in potential at the output terminal Γ12 of the clock generator TR by means of the amplifier AMP during the recirculation results in an incorrect operation of the gate CG 2 and an undesired advancement of the control counter CC . Such an incorrect mode of operation of the gate CG 2 can be prevented by adding a further input signal to this gate, that is to say by adding a further input signal from the start-up contacts ST3. Since this input signal is not available in the standby state, gate CG 2 is locked against actuation by a signal from terminal Γ12. If desired, an additional safeguard can be created by supplying a signal P 9 to the gate G12, since this gate is always locked outside the intervals in which a pulse P 9 is received.

There is a possibility that a machine is in an inoperable state, namely if TO and ill are both positive, and the pulses P 9 would then be suppressed by the AND-not gate TG1. This latter gate controls the clock TR and therefore the control of TO 'by the pulses P9 would cease and the recirculation would not be able to take place. The AND-not gate TG1 is therefore removed, and the AND gate TG2 and the pulses P 9 feed the clock TR directly

and the auxiliary circuit TO '. In order to prevent actuation of the machine in the above-mentioned inoperative or so-called clogged state, a simple modification to the

Start-up gate SGl taken in that its one input signal ST 3 is replaced by the input signal ST 2 , so that this start-up gate SGl works immediately when the signals at TO, ill and ST2 are all present. So when the operator of the machine begins to initiate a computation process, this shutdown gate comes into action immediately and the oscillator is shut down. If, on the other hand, an attempt is made to start a so-called clogged calculating machine whose registers are currently receiving a series of recirculation pulses, there will be no signal at the TO input terminal of SGl and the recirculation cycle will run before the oscillator is shut down. So the registers cannot be prevented from completing the recirculation cycle.

2 is a partial circuit diagram of the clock generator TR with its additional switching elements and illustrates a method by which the desired output signal can be generated while the passage of current in the tube VTO of the stage TO of the clock generator TR is interrupted. During the standby state, FTO is initially current- permeable , since the resistors R1 and R2 set the trigger voltage so that the first pulse dP9, which passes through the coupling capacitor C1, ignites the tube. The pulse dP9 is fed to the normal reset line or feedback line RS . The ignition of the tube FTO raises its cathode potential and blocks a diode Dl which, together with a resistor R 3, lies between the cathode and the triggering electrode of a tube FTO '.

When the oscillator has just started up, the delay gate DG takes effect in the following manner. The oscillator output voltage of the pulse generator PG is fed to the input terminal OSC via the coupling capacitor C 2, and is rectified by the diodes D 2 and D 3 in such a way that the potential at the capacitor C 3 is raised to a value which is sufficient to reverse the bias of a diode D 4. This diode D 4 connects the delay gate DG to the tripping resistor R3 of the tube FTO '. One occupancy of a capacitor C 3 is kept at -20 V, and this capacitor discharges through a resistor R 4 lying parallel to it if the oscillator should be switched off for any reason. The trigger electrode of the tube FTO 'is raised to the vicinity of the ignition potential by means of a capacitor C 4. The capacitor C 4 charges through the resistor R 5 from the +75 V line, but when either the diode Dl or the diode DA is unlocked, a relatively large current flows through the resistor RS to increase the tripping potential of FTO ' lower and prevent the ignition of this tube by a pulse dP9. Such a pulse can be supplied via the diode D 5 and a coupling capacitor C 5. The ignition of the tube FTO 'is thus delayed by a pulse dP9 on its triggering electrode by means of the delay gate DG until the diode DA is blocked. The delay time is dimensioned so that the oscillator has enough time to settle to a constant frequency. It can be seen that the voltage appearing on the capacitor C 4 and that the input pulse dP9 for the circuit TO 'both emanate from the -20 V line. For this purpose, the resistor R 6 is located between the cathode of the diode DS and the −20 V line.

As soon as the oscillator has settled to a constant frequency and the tube FTO has been ignited by a pulse dP 9 via the capacitor C1, the diodes D 1 and DA

ίο biased in the opposite sense, and the capacitor C 4 can be charged via the resistor R 5 in KreiseTO '. Depending on the time constants of R 5 and CA , sooner or later one of the pulses dP 9 will ignite the tube and thus cause the tube FTO to be extinguished. As soon as the tube FTO 'ignites, its cathode potential is raised and current flows through the diode D 6, the resistors, R2, R1 and R8 to the -125 V line. This increases the triggering potential of the tube FTO close to the point of ignition, so that the next pulse dP9 ignites this tube and the cycle is repeated.

A positive output pulse is sent from the cathode of the tube FTO 'to the amplifier AMP and the delay circuit 9, the capacitor C 6 serving to ensure that the tube FTO' is extinguished when the tube FTO becomes conductive. The amplifier AMP consists of three npn transistors TR1, TR2 and TR 3, which as

three-stage amplifier with each emitter connected to the -20 V line. The base bias of the transistor TRl is determined by the bias resistor R 10, which is connected to the -130-V line, while the bias of the transistors TR 2 and Ti? 3 is defined by the potentiometers, which are formed from the resistors 11, R12 and R13 or Λ14 and are also connected to the - 130 V line. The collectors of the transistors TR1 and TR 3 are connected via the resistors R15 and R16 to the +15 volt line, while the collector of the transistor TR 2 via the resistor R 17 H-180 V line is located on a. A positive pulse is therefore fed to the base electrode of the transistor TR1 , which results in an amplified voltage pulse via RIS. This latter pulse becomes the base electrode of the transistor Ti? Supplied via Rll 2, so that a further gain occurs at the resistor R 17th The pulses amplified by the first two stages are given directly to the output line RP and via the resistors R 21, R 22 ... .R 32 to the terminals T1 to T12.

The output signal TX is taken after the third stage of the amplifier by coupling the voltage drop to R 17 via a diode D 7 and a resistor R 13. In this way, a further amplified pulse is obtained from the resistor R 16. It can be seen that between the collector of the transistor TR 3 and the emitter of this transistor there is a parallel resistor C 7. The output pulse TX is therefore broadened and delayed, and the pulse deformed in this way overlaps the pulse PO for the purpose set out above. The third amplification stage thus isolates the output pulse TX from the output signal on the line RP via the transistor TR 3. It can also be seen that

the transistors TRl and Ti? 3 are protected against possible damage by backward-running pulses which could be fed to the base electrode by means of diodes D 8 and D 9. These two diodes are reverse biased, ie locked, for a positive input pulse. Since the output signal TX is negative when the tube VTO ' carries current and is positive at all other times, this signal can be fed to the gate TG 4 like the input signal ΓΙ to T 12 to xo , provided that it is ensured that TX while TO becomes negative. For this purpose, the pulse Γ0 is fed to the common terminal of i? 13 and Dl via a diode D 12. The diodes D1 and D 12 therefore together form an OR gate. A diode D 13 is connected between i? 13 and the +15 V line in order to limit the potential at the connection terminal of Dl and .R13.

From the above description of the operation of the tubes VTO ' and VTO it should be apparent that the output signal RP of the amplifier AMP consists of a positive pulse which begins at the end of one pulse P 9 and ends at the end of the next pulse. The as time interval between the pulses is determined by the time constants of R 5 and C 4 in the trip circuit of the tube VTO ' . It should also be evident that all terminals Π to Γ12 are made positive for the duration of the positive pulse at terminal RP . The desired conditions for the standby state have thus been achieved, and the register circles Ii? up to 12 R are used as well as the clock TR .

It is important, however, that the normal operation of the clock TR and the registers or counters are not affected by the recirculation during the standby state. As soon as a key is pressed to introduce a number of digits, a gradually increasing positive potential of the terminal ST1 of the timer TR supplied and also fed via a diode D10 to capacitor C 5, but not transferred through this capacitor. the diodes D 5 and dLo thus practice composed of a gating action which DP9 5 has the transfer of the pulses to the capacitor C the result. the stresses are so adjusted that 5Γ 2 no pulse dP 9 'can cause the diode DS ignition of the tube VTO very shortly after the supply of the input signal. thus, shortly after the delivery of ST 2, if not already during the duration of this Input signal, the tube VTO current-permeable, and there is no risk that the tube VTO ' begins to carry current again until a ll digits have been entered in the register. The delay circuit from .R19 and C 8 offers a safeguard against the fact that VTO is deleted when VTl becomes conductive .

However, the input signal ST2 has an influence on the ignition voltage of the tube VTl, since this input signal of the ignition electrode via a resistor /? 20 is fed, but its effect is delayed because the voltage fed to the trigger electrode increases slowly.

Therefore, if the positive signal ST 2 is supplied when the tube VTO is current-permeable, the pulses dP 9 on the triggering electrode of VTO 'are quickly locked, and shortly after the locking of the control voltage for VTO' , the input signal ST 2 becomes the potential at the Have raised the ignition electrode of VTl enough to cause the next pulse dP 9 on the common input line to ignite the tube VTl via the capacitor C 9. The tubes VTO and VT1 can therefore not fire at the same time when the signal ST 2 is present and the next pulse dP9 arrives.

After the tube VT1 has been ignited, the further switching of the clock generator TR will take place in the normal manner, as is the case in the above-mentioned, already proposed desktop calculating machine.

From the embodiment described it should be apparent that an electronic calculating machine can be converted with little effort so that a pulse recirculation in the standby state takes place in at least one clock and in each register. As already detailed has been explained, the recirculation pulses not only increase the service life and the reliability of the register increases, but also the life and reliability of the Clock in which the recirculation pulses are generated.

Claims (8)

Patent claims: 1. Calculating machine with a plurality of counters operated by pulses and containing cold cathode tubes (Ii? To 12i?), Characterized by means (TO ', AMP, GU) which, in the standby state of the machine, supply pulse trains to the counters, the number of Pulses in each pulse train is dimensioned so that each counter is incremented by a complete duty cycle. 2. Calculating machine according to claim 1, characterized in that each counter is a ring counter containing a plurality of cold cathode trigger tubes. 3. Calculating machine according to claim 1, characterized in that each counter by a Cold cathode tube is formed. 4. Calculating machine according to one of the preceding claims with a further ring counter (TR), the first stage (Γ0) is assigned to the standby state of the machine, and which has a plurality of second stages (Tl to T12), which when performing a calculation process Be effective in sequence, characterized in that a third stage (Γ0 ') coupled with the mentioned first stage (Γ0) and alternately effective with this first stage when the machine is in a standby position, and that one of the pulse series counters is supplied every time the third stage of the further ring counter becomes effective. 5. Calculating machine according to claim 4, characterized in that the further ring counter (TR) is a clock which opens a plurality of gates (li? G to 12RG), one of which is assigned to each counter, in sequence for predetermined time periods that an input terminal of each of these gates to a ··. - aaj «509 759/47 + common pulse input line (H) is connected that the pulse series are generated by a pulse generator (PG), from one output terminal of which a voltage curve (-GD) is taken and fed to the common pulse input line in such a way that the potential on the common pulse input line is periodically with one of the repetition frequency of the pulse generator the same speed is lowered and that all gates are opened and an input signal is fed to the common pulse input line when the third stage of the further ring counter is operating. 6. Calculating machine according to one of the preceding claims, characterized by means (ST 2) for blocking the supply of the pulse trains when an input signal is received at one of the counters, and characterized by means (D 5, D10 and C 5) which ensure that each counter has completed its duty cycle before the supply of the pulses is blocked. 7. Calculating machine according to claim 4, characterized in that each stage of said further ring counter contains a cold cathode trigger tube and that the mentioned first and third stages are coupled to one another in such a way that a bistable trigger stage is created. 8. Calculating machine according to one of the preceding claims, characterized in that the pulse series are taken from an oscillator and that means (£> G) are provided to take off a slowly increasing voltage from the output side (OSC) of this oscillator, with which the feed the wave trains is locked until the oscillator has run for a predetermined time. For this purpose 2 sheets of drawings 509759/474 12.65 © Bundesdruckerei Berlin