DE1071382B - Control device for calling memories - Google Patents

Description

The invention relates to control devices for calling memories that are dependent on a movable Carriages or sledges in different columns or locations on a recording medium be effective. There should therefore be storage locations based on the relative position of the carriage or sled the recording medium can be called or queried.

It is known that for input and for writing out in calculating or booking machines, telex or to use typewriters. There were switches on the typewriter's car provided in the manner of a control rail to the advancement of the carriage up to certain predetermined.: Bodies to reach. '' ''

According to the invention, the control device is a counting device and a device for generating of pulses assigned depending on the carriage movement for each of the carriage reachable point and / or column actuates the counting device, which the selection associated Storage car or storage fields causes.

This arrangement has the advantage that. no special control rail needs to be used, in that the counting device contains only one counter which is continuously operated in places. In other In cases, a very light control rail is sufficient, which only controls the respective columns. The Counting device included two counters, one of which is given by the transition to the other Impulse is actuated, while the other is activated by the Im- ■ pulse is operated. Through these measures, the actual control rail of. of the respective type of the program completely or largely relieved. The ones required to change the program multiple control devices can separate from the machine z. B. housed in the typewriter table where there is sufficient space.

The outputs of the counters can be assigned a cross-switch field in which the ones to be selected Storage tracks and storage fields are optionally switchable.

• In the case of a multi-part structure of a counting level the outputs of the individual links can be connected to a switching matrix, which output lines in the number of possible combinations of the states of excitation of the counting members, of which one is made effective depending on the respective state of excitement.

It is recommended that a selector switch, which is dependent on the position of the trolley, has a setting device the scanning head to the associated control device for calling memories

Applicant:

Dr. Gerhard Dirks, Frankfurt / M., Mörf eider Lands tr. 44

Claimed priority: Great Britain 9 March 1956

Dr. Gerhard Dirids, Frankfurt / M., has been named as the inventor

Track sets and that a second selection switch determines which type of storage 'in the relevant track is selected. The selection switch for selecting a sector of the storage path can be a comparison. or coincidence circuit affecting the connection between the discharge device and the Writer only enables when the generated by the relevant sector of a 'synchronizing track Impulse coincides with an impulse of the selector switch.

A plurality of rows of pulse-generating means are preferably arranged on the writing carriage, which cause a selection of a storage location when interacting with corresponding control means. The memory can be operated with the same access speed as the printing speed or with a higher access speed, so that for each print column on the described Sheet that is brought into the printing position, the relevant sector of the memory selected and read can be. The sensed signals then actuate or become the pressure devices issued further storage with or without changing the sequence. A number of sectors can be can also be shifted against each other by one sector; when transmitting signals to or from another memory a shifting device is made operative to shift the signals e.g. B. on a to bring another storage web or another recording medium, whereby the sensing and / or recording is shifted by as many sectors as there are memory lanes in the input are. ... .

Further details of the invention can be found in the following description of exemplary embodiments emerged. '., "...,

909 689/302

The following description includes Figures 1 to 7. It shows

Fig. 1 shows the block diagram of a device accordingly the invention, . . . ,

2 shows the schematic representation of a contact arrangement,

3 shows the principle of a counting stage used in FIG. 1,

4 shows the principle of the cross switch panels used in FIG. 1,

FIGS. 5 a and 5 b are schematic representations of a displacement device according to FIG. 1,

6 shows the principle of a comparison device according to FIG. 1, <

FIG. 7 shows the principle of the control stage of the writing device according to FIG. 1.

Fig. 1 first shows a device for sensing signals from a drum memory 1 and inputting them into a write-out device. In this device, selection means are provided in accordance with the invention, which make it possible to select the storage location on the drum storage unit 1 as a function of the position of the writing carriage of the writing device. The means for selecting a storage location on the drum 1 contain a hundred-digit counting stage 1, which is further counted by pulses generated by the contact arrangement 3. This contact arrangement 3 is actuated as a function of the movement of the writing carriage. It is shown in more detail in FIG. The contact arrangement consists of the two fixed contacts 4 and 5 and the resilient contact 6. The three contact parts 4, 5 and 6 are attached to the writing carriage 7 of the writing device in an insulated manner. The resilient contact 6 is connected to the positive pole 9 via line 8, and the two fixed contacts are connected to the two pulse converters 12 and 13 via lines 10 and 11. The resilient contact 6 carries at its lower end a bearing surface 14 which rests on the sliding surface 15 connected to the stationary part of the writing-out device. By appropriately shaping the upper part 6 a of the resilient contact 6, a preload is achieved which presses the bearing surface 14 against the sliding surface 15, so that a frictional resistance in the direction of movement 16 arises between the two. The writing carriage 7 moves one step in the writing direction 17 after each type written out. However, it can also be moved in the direction of arrow 18 against this writing direction. The movement steps in the two directions 17 and 18 take place relatively quickly, so that the resilient contact 6 damped by the frictional resistance between the support surface 14 and the sliding surface 15 cannot immediately follow this movement, but is deflected laterally. This creates a conductive connection between this resilient contact 6 and one of the fixed contacts 4 or 5, depending on whether the writing carriage was moved in the direction of arrow 17 or 18. The friction between the contact surface 14 and the sliding surface 15 is adjusted so that the resilient contact 6 just briefly comes into contact with one of the stationary contacts 4 or 5. Due to the restoring force of the resilient contact 6, after the writing carriage 7 has come to a standstill, the latter arrives again approximately in the rest position shown after a delay. This contact arrangement makes it possible, depending on the direction of movement of the writing carriage 7, to generate a positive pulse either on line 10 or on line 11. Both the pulses appearing on line 10 and on line 11 are fed to the counter tube 19 of the counting stage 2. The pulses appearing on line 11 continue to count this counter tube in the positive direction, while the pulses appearing on line 10 continue to count the counter tube 19 in the negative direction. First, the pulses from lines 10 and 11 are each fed to one of the pulse converters 12 and 13, respectively. These are formed by monostable flip-flops, which are tilted by the pulses formed by the contact arrangement 3 and thereby emit pulses whose shape is adapted to the requirements of the counter tube. From these pulse converters 12 and 13, the now positive pulses are fed to the two amplifiers 22 and 23 via lines 20 and 21. 'After they have been amplified by this, they reach the input lines 24 and 25 of the counter tube 19 as negative pulses. This counter tube 19, together with a second counter tube 25 and a cross switch panel 26, forms the counting stage 2 with a maximum counting capacity of "100" pulses. This counting stage is shown in more detail in FIG. The output lines 27/1 to 27/100 of the counting stage 2 lead to the selection device 28. This is shown in more detail in FIG the output lines 27/1 to 27/100 have a positive voltage. This positive voltage is fed to the output lines 31/1 to 31 / n and 32/1 to 32 / m as a function of the connections made in the two cross switch panels 29 and 30. The output lines 32/1 to 32 / n lead to the adjusting device 33, by means of which the push rod 34 can be moved in the direction of arrow 35, depending on which of the lines 32/1 to 32 / m- has a positive voltage. A sensing head 35 is mounted on the push rod 34, which can be brought into sensing position by the axial displacement of this rod 34 on various storage tracks 36/1 to 36 / w of the drum storage unit 1. The drum storage device 1 is fastened on the shaft 37 and is driven by a motor 38. It is subdivided into the individual memory tracks 36/1 to 36 / w · and the two signal tracks 39 and 40. The setting device 33 makes a selection among the memory tracks 36/1 to 36 / w, while the setting device 41 selects which the lines 31/1 to 31 / n lead, a selection takes place among the individual sectors into which each of these memory paths 36/1 to 36 / n is divided. The extent of these sectors corresponds to the distance between two of the magnetic structural changes 42/1 to 42 / w. Signal path 40. In signal path 39, only a magnetic structural change 43 is applied, which marks the beginning of a revolution of the drum storage device 1. The magnetic structural changes 42/1 to 42 / n are sensed by the magnetic head 44 and the resulting pulses are fed to the counter tube 45 of the selection device 41. These pulses continue to count the counter tube 45 from one counting position to the other and thereby generate a positive voltage on the lines 46/1 to 46 / n in accordance with the counting position of the counter tubes 45. The lines 46/1 to 46 / w- connect the counter tube 45 to the comparison device 47. The lines 31/1 to 31 / n are also connected to this comparison device

fed. In it, the voltage state of one of the lines 31/1 is in each case with that of the corresponding of lines 46/1 compared. If there is a positive voltage on both of the corresponding lines, then a positive voltage arises on output line 48, which the controllable amplifier 49 opens, d. H. switches so that pulses sensed by magnetic head 35 and passed through amplifier 50 were amplified, this controllable amplifier 49 can pass and via amplifier 51 of the counter tube 52 can be supplied. These pulses sensed by magnetic head 35 correspond recorded on the corresponding sector in the selected one of the memory lanes 36/1 to 36 / w Information. The counter tube 52 is set to a specific count position by these pulses set and "thus caused a positive voltage state on one of the lines 53/1 to 53/10. This positive voltage on one of the lines

Selector 33 to provide enough time to move the magnetic head 35 to the selected one Storage lanes 36/1 to 36 / w to move. This selection device 33 is actuated in the following way: By pulses which are fed to the two lines 20 and 21, is counting level 2 is set to a certain value. This counting stage is shown in principle in FIG. she contains the two ten-digit counter tubes 19 and 25.

The counting tube 19 is for counting the ones and the Counter tube 25 provided for counting the tens. Both are glow discharge counting tubes; i.e., through negative pulses is a glow discharge, which between anode 65 and one of the cathodes 66/1 to

ig 66/0 consists of one of these cathodes to the next forwarded. The pulses arrive from the two lines 20 and 21 via the two capacitors 67 and 68 to the two auxiliary electrode systems 69 and 70. These two auxiliary electrode systems

gen 53/1 to 53/10 is the corresponding one in the ao systems are through a T-link, which is made up of the

Control unit 54 of the writing device contains two resistors 71 and 72 and capacitor 73

Gas discharge tubes ignited and thereby. one is formed connected to each other.

Magnet energized, which the corresponding type of the over diode 74 and the voltage divider, which from

Tendering device operated. the two resistors 75 and 76 are formed,

The pulses from magnetic head 44 arrive via 25 the auxiliary electrode system 69 with a positive one

Amplifier 55 through the controllable gate 56 and amplifier 57 into the counter tube 45. The controllable gate 56 represents a bistable flip-flop in connection with a controllable triode. The flip-flop is toggled

Tension biased. Will now be on the input line 21 negative impulses are supplied, then these first reach the auxiliary electrode system 69 and, delayed by the T-link, to the auxiliary

by impulses which are applied to the lines 57 or 58 30 electrode system 70. This supplies the glow will. A charge then arrives at line 57 from cathode 66/1 in the direction of cathode 66/2

"'' etc. are forwarded, however, on line 20

negative pulses are supplied, then these first reach the auxiliary electrode system 70, and, through the

switched on. The cathodes 66/1 to 66/0 are connected to earth via cathode resistors 77/1 to 77/0. If there is a glow discharge between

77/0 a current which causes a positive voltage drop across this resistor. This positive Voltage drop issued by the associated line

Pulse when through magnetic head 59 the magnetic
Structural change is sensed and the result
The generated pulse is fed to the line 57 via the amplifier 60 and the controllable gate 61. The 35 T element is also delayed, at auxiliary electrode system 69. The controllable gate 61 is a bistable flip-flop in which the glow discharge is in reverse rich connection with a triode, whose grid bias voltage is determined by the switch position of the bistable
Flip-flops is affected. If a positive pulse is generated on one of the lines 20 or 21, one of these cathodes is seen and the anode 65 flows through the corresponding one of the diodes 62 via the corresponding cathode resistor 77/1 to or 63 to the control line 64 of the controllable
Gate 61. As a result, the flip-flop contained there is switched over in such a way that pulses, which are fed from amplifier 60 to the controlled triode, 45 § ^en 78/1 to 78/0 are amplified against a positive voltage, that is, the magnetic structure those whose associated cathode no glow change 43 can be sensed, and the charge thereby exists, since this is sent via the corresponding generated pulse to line 57. This turns resistors 77/1 to 77/0 with ground potential verdas the bistable flip-flop of the controllable Tores 56 are so bound. If the glow discharge is switched to the cathode so that the associated triode is opened 50 66/0, the positive voltage is generated, ie pulses from magnetic head 44 can jump to resistor 77/0, a positive pulse, counter 45. The counting capacity of the counter which, via the two capacitors 79 and 80 of the stage 45, corresponds to the number of magnetic inputs of the two controllable amplifiers 81 and structural changes 42/1 to 42 / m. Since at the beginning of a 82 are fed. These amplifiers are controlled by one of these 55 for each sector on the drum memory 1
magnetic structural changes 42/1 to 42 / w — 1
attached and also at the end of the last
Sector the magnetic structural change 42 / w stands,
the counting capacity of the counter tube 45 is 1 larger
than the number of sectors on the memory lanes 60
36/1 to 36 / m. Through the through the magnetic
Structural change 42 / m generated pulse, counter 45 is switched back to its starting position
and thereby generates a positive pulse on line 65, which tilts the bistable flip-flop of the controllable 65 further negative pulse back to its starting position via capacitor 68 to gate 56 and guides it, then the glow discharge migrates from the counter 9 to the cathode 66/0, and a head 44 generates pulses for the counter 45 transmission pulse. This prevents it from reaching the condenser. The opening of the triode contained in the controllable gate 61 80 and the open amplifier on the output line is somewhat delayed, in order to connect the 70 86 and from there via the capacitor 87 to the auxiliary electrode.

through the bistable flip-flop 83. This in turn is triggered by pulses which are sent to the cathodes 66/9 and 66/1 occur and are fed to the grids via lines 85 and 85, switched. If a positive pulse occurs on line 84 - this is the case when the glow discharge occurs Cathode 66/9 is switched - then the bistable flip-flop 83 switches over so that amplifier 82 opens is, d. H. Impulse amplified and amplifier impulse blocks. Now the counter tube 19 is a

electrode system 88 of the counter tube 25. As a result, the glow discharge existing there is in a positive direction forwarded.

The glow discharge circuit of the counter tube 25 corresponds to that of the counter tube 19.

If a positive pulse occurs on line 85 of the counter tube 19, then the bistable flip-flop 83 is switched over so that amplifier 81 amplifies pulses and amplifier 82 blocks pulses. If the counter tube 19 is now switched on in the negative direction, xo that is, the glow discharge migrates from cathode 66/1 directly to cathode 66/0, then the transfer pulse generated at cathode 66/0 is amplified by amplifier 81 and via capacitor 89 to auxiliary electrode system 90 of the counter tube 25 supplied. As a result, this counter tube is indexed in the negative direction. A positive voltage also occurs on the output lines 91/1 to 91/0 of the counter tube 25 when there is a glow discharge on the associated cathode. Lines 91/1 to 91/0 are routed to cross switch panel 26 in the same way as lines 78/1 to 78/0. At the respective crossing points of the lines 78/1 to 78/0 and 91/1 to 91 / O ₁ , these are connected by two resistors 92/1 to 92/100 and 93/1 to 93/100. The corresponding lines 27/1 to 27/100 are connected to the connection point of these two resistors. If two crossing lines 78/1 to 78/0 and 91/1 to 91/0 are positively biased, then the output line 27/1 assigned to the crossing point is also positively biased with the same voltage. If, on the other hand, only one of these crossing lines is positive and the other has ground potential, then the output line 27/1 to 27/100 assigned to the crossing point is at half the positive potential. If both of the crossing lines are at ground potential, then the corresponding output line 27/1 to 27/100 also carries ground potential.

The voltage states of the lines 27/1 to 27/100 are now via the two shown in FIG Transfer cross switch panels 29 and 30 to lines 31/1 to 31 / «and 32/1 to 32 / m. How out Fig. 4 can be seen, each of the lines 27/1 to 27/100 is via a diode 94/1 to 94/100 in the cross switch panel 29 introduced and continue via one of the diodes 95/1 to 95/100 in the cross switch panel 30. Soll If a writing-out process takes place at a certain position of the writing carriage, then this is the one Place the corresponding horizontal line 96/1 to 96/100 at the corresponding intersection with the Line of lines 31/1 to 31 / »connected, -which is assigned to the sector in which the advertised Information is recorded.

The horizontal line 97/1 to 97/100 assigned to the live input line 27/1 to 27/100 in the cross switch panel 30 is in this case connected at the intersection with one of the vertical lines 32/1 to 32 / m, which. corresponds to the memory path 36/1 to 36 / ", in which the information that is to be written out at this point is recorded, ie on the line of the vertical lines 31/1 to 31 /", which corresponds to the sector to be selected, and on that of the vertical lines 32/1 to 32 / «, which corresponds to the memory path to be selected, there is a positive voltage. The positive voltage prevailing on the corresponding lines 32/1 to 32 / «is fed to the setting device 33, which is shown in principle in FIGS. 5 a and 5 b. This adjustment device 33 contains the motor 98 which drives the shaft 99. This shaft 99 is cranked, and the push rod 34 is articulated to the crank arm thus created via the connecting rod 100. At its front end, the shaft 99 carries a rotary body 101 which establishes a galvanic connection between the brush 102 and the brushes 103/1 to 103 / n . An insulating piece 104 and 105 is inserted into the body 101 at two points on the circumference, so that in each case one of the brushes 103/1 to 103 / m has no connection with the brush 102. As can be seen from FIG. 5 b, the brushes 103/1 to 103 / n are arranged in a semicircle on the end face of the body 101. Each of these brushes 103/1 to 103M is connected to one of the lines 32/1 to 32 / «. The brush 102 is connected to the grid 107 of the triode 108 via resistor 106. This grid is biased negatively via grid bleeder resistor 109 to such an extent that the anode current through triode 108 is blocked if no positive voltage is supplied via resistor 106. In this case the relay 110, which is switched into the anode line of the triode 108, is not energized, and the two contacts 111 and 112 of this relay are in the rest position shown. The normally closed contact 111 closes a circuit from the positive pole 113 through a brake winding of the motor 98 to the negative pole 114, ie when the relay 110 is not energized, the motor 98 is braked. If a positive voltage now occurs on one of the lines 32/1 to 32 / «, then this is passed via the associated brush 103/1 to 103 / w via the body 101 and brush 102 and resistor 106 to the grid 107 the grid bias is raised to such an extent that a strong anode current flows, which energizes the relay 110. By energizing this relay 110, normally closed contact 111 is opened and thereby the braking effect is canceled and normally open contact 112 is closed, whereby the motor circuit is closed and shaft 99 is thus driven. Shaft 99 now rotates until one of the insulating pieces 104 or 105 is opposite the brush 103/1 to 103 / w, to which the positive voltage is applied. This interrupts the circuit to the grid 107, so that the negative bias voltage supplied via the grid bleeder resistor 109 becomes effective again; that is, the relay 110 drops out, the motor circuit is interrupted and the brake circuit is closed again, so that the shaft 99 remains in this position. As a result of the rotation of the shaft 99, the push rod 34, which is linked via the connecting rod 100, has been displaced in the direction of arrow 34a so far that the magnetic head 35 is located opposite the memory path of the memory paths 36/1 to 36 / «, which is connected to the corresponding line 32/1 to 32 / n is assigned. The movement of the push rod 34 was initiated by the presence of a positive voltage on one of the lines 32/1 to 32 / «and thus by the supply of a pulse to the counter tube 19 via one of the lines 24 or 25. of the diodes 62 and 63 are supplied to the control line 64 of the controllable gate 61. This is delayed so long that pulses from the magnetic head 59 via the amplifier 60 can only pass the controllable gate 61 when the push rod 34 has returned to its rest position; that is, the selection of the sectors only takes place when the magnetic head 35 has been brought into the sensing position on one of the storage tracks 36/1 to 36 / «. At the beginning of one revolution of the drum store 1, the magnetic structure is now through the magnetic head 59

Change 43 sensed, so that a pulse arises, which is amplified in the amplifier 60 and through the controllable gate 61 arrives at the control line 57 of the controllable gate 56. This pulse switches at the same time also the bistable flip-flop of the controllable gate 61 back to its starting position, so that the magnetic Change of state 43 can only be filled once. After the controllable gate 56 is opened pulses, which are sensed by magnetic head 44 'on signal path 40 and by amplifier 55 were amplified, fed to the amplifier 57 via this controllable gate and from there into the counter tube 45 are fed in. These pulses cause counter tube 45, the circuit of which is one of the counter tubes 19 and 25 in FIG. 3 correspond, starting with "0", each counting further by one counting position. Through this a positive voltage arises at one of the output lines 46/1 to 46 / tt.

The lines 46/1 to 46 / »lead to the comparison device 47, which is shown in Fig. 6 in principle. This facility will also be the lines 31/1 to 31 / m fed. The lines 31/1 and 46/1 or 31/2 and 46/2 etc. are through two each equal resistances 115/1 to 115 / »or 116/1 to 116 /» are connected to one another. From the junction A resistor 117/1 to 117 / n leads these resistor pairs to control line 48. As already described, one of the lines 31/1 to 31 / »via the cross switch panel 29 is a positive voltage granted. Are on two corresponding lines 31/1 to 31 / »and 46/1 to 46 /» positive Tensions, then also prevail at the connection point of the two corresponding resistors 115/1 to 115 / m and 116/1 bns 116 / »the same positive Voltage which is issued on control line 48 via the associated resistor 117/1 to 117 / » will. As a result, the grid bias of the controllable amplifier 49 is increased so much that pulses, which by magnetic head 45 'from "the selected sector on the corresponding one of the memory lanes 36/1 to 36 / m are sensed, can be fed from amplifier 50 to amplifier 51. Lies on-two different lines 31/1 to 31 / »and 46/1 to 46 / »a positive voltage, then the voltage on control line 48 is only half as large as the voltage applied to the respective input lines 31 and 46 and is therefore not sufficient to to increase the grid voltage of the controllable amplifier 49 so that pulses can be amplified. Even if only one line 31/1 to 31 / »or one of the lines 46/1 to 46 /» has a positive voltage is applied; the grid bias of controllable amplifier 49 is not increased enough to generate pulses to let it happen. Since the existence of a positive voltage on one of the lines 46/1 to 46 / « corresponds to the sensing of a certain sector of the storage lanes 36/1 to 36 / », can be done by assigning a positive voltage to one of the lines 31/1 to 31 / ». You have made a selection from these sectors will. .

After the drum memory 1 has performed one revolution, the last one becomes magnetic Structural change 42 / »the counter tube 45 switched to its starting position, whereby on line 65 a positive pulse occurs. This positive pulse reaches the control line 58 of the controllable gate 56, whereby the bistable flip-flop is switched back to its starting position and thus no pulses, which are induced in the magnetic head 44 can pass this controllable gate; i.e., counter tube 45 is counted through to its full counting capacity only once during a sensing process.

The pulses amplified by the controllable amplifier 49 are now fed to the amplifier 51 and, after they have been amplified there, the counter tube 52. Also the circuit of this counter tube corresponds to one of the counting tubes 19 or 25 except that only those of the input line 24 or 25 is provided on which the supplied

ίο The counter tube continues to count pulses in a positive direction.

The individual cathodes of the counter tube 52 are connected to lines 53/1 to 53/10. These lines lead to the control stage 54, which is shown in principle in FIG. It contains a number of gas discharge tubes 118/1 to 118 / m, one of which is assigned to the type of writing device to be selected. The control magnet 119/1 to 119/1 of the associated type is switched on in the anode circuit of each of these gas discharge tubes. These control magnets are connected to the positive pole 122 via the common line 120 and capacitor 121. The cathodes of the gas discharge tubes 118/1 to 118 / »are connected to ground. The grids of these gas discharge tubes are _{biased negatively by the resistors 123/1 to 123 / »L to} such an extent that they do not ignite. At the same time, these grids are connected to lines 53/1 to 53 / »via resistors 124/1 to 124 / m. If a positive voltage occurs on one of these lines

voltage, then this increases the grid voltage of the associated gas discharge tube 118/1 bis 118 / »so far that the ignition curve is exceeded. By igniting one of these gas discharge tubes 118/1 to 118 / »capacitor 121 is charged and the associated control magnet 119/1 to 119 /» excited by the charging current. When the charging current subsides, the corresponding gas discharge tube is activated 118/1 to 118 / »deleted. By energizing the corresponding control magnet 119/1 to 119 / »becomes the writing of the type assigned to this control magnet causes and at the same time the carriage 7 by one movement step in the direction of the arrow 17 switched on and thus again a pulse on line 11 is generated. This impulse leads a new one A tender process, which proceeds in the same way as just described.

From the above description it can be seen that the counting stage 2 when moving the writing carriage negative pulses are fed to the writing-out device, which convert this counting stage into positive Count on direction. Even if the carriage is moved against the direction of writing with each movement step of the counting stage 2 negative pulses are supplied, which, however, in negative Count direction, d. i.e., after both a forward movement and a backward movement of the writing carriage, the storage location to be selected is clearly determined by the setting of counting level 2.

Instead of the control magnets 119/1 to 119 / w in Fig. 7, relays in the anode lines of the corresponding discharge tubes are switched on, further control functions by their excitation to be triggered; d. that is, the information recorded on the drum memory 1 may be a Represent control command, which by the device shown depending on the position of the writing carriage of a tendering facility is selected and the information content of which is is assigned to the correct relay by energizing it

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the control function is triggered. So it is possible to train the drum memory 1 both as an information and as a program memory.

In the example described, the selection of a storage location was made using selection elements, which contain multi-part counting tubes. According to the basic principle corresponding to the invention, namely that the selection of a storage location is brought about by initially using a first selection switch a group of storage locations is selected from a memory, e.g. B. a memory web a drum memory, and that by a second selection switch within this group a specific one Storage location, e.g. B. selected a sector on one of these storage lanes of the drum store such a selection device can also be constructed in such a way that, for example, on the Writing carriage of the writing means several rows of pulse generating means are arranged, which cause a selection of a storage location when interacting with corresponding control means. These pulse-generating means can, for example, be permanent magnets, which during a movement step the writing carriage in sensing means associated with them, d. H. Magnetic heads, induce pulses. The pulse generating means are expediently arranged so that each position of the Writing carriage corresponds to a certain code combination. Should these pulse-generating means, for example cause the selection of a storage location on a drum storage, which in 30 storage lanes and each of these memory lanes is divided into twelve sectors, then for each write position of the writing carriage two code combinations, for example in dual code, are provided. In the case of the ■ A first combination of a 5-digit dual code would have to be provided for the capacity of the drum memory mentioned which causes the selection of one of the memory lanes and a second 4-digit dual code combination, which makes a selection among the individual sectors of this memory. The through the Pulse-generating means generated pulses can be fed to flip-flop chains, their switching states in cooperation with appropriate control means, first a selection from the individual Storage lanes and then make a selection among the individual sectors of these storage lanes. The control by code combinations can, however, also be carried out in such a way that the counting capacity the code is determined by the number of possible writing positions of the writing carriage; d. h., at For example, 100 writing positions on the writing carriage would have to be provided with a 7-digit dual code. The pulses generated here would also be fed to a plurality of flip-flops. Through appropriate Switching means can be achieved that with a certain combination setting of the flip-flop chain a certain output line is live, so that at a certain position of the carriage only one of these output lines, which this position of the carriage is assigned, is live. These output lines would, for example, be the lines 27/1 to 27/100 in Fig. 1 correspond. The positive voltage condition present on one of these lines can be used in the same or a similar way as described in FIG. 1 to select a storage location can be used on a memory.

In the examples described, the selection of a memory lane on the memory corresponds to Selection of a column group on the writing material to be labeled and each of the sectors of these Path of a column within this column group. In connection with the device which is shown in FIG is shown, such a selection can also be made that the resistor pairs 92/1 and 93/1 to 92/100 and 93/100, whose assigned position of the writing carriage is a column within the same column group corresponds to a common one

ίο is assigned to lines 27/1 to 27/100. Through this it is possible to make a selection through the voltage state of these lines 27 via a cross switch field to meet under the existing storage lanes. Since on each of the lines 27/1 to 27 / n in this A positive voltage is then present when the carriage is within an arrangement This voltage can be over a distribution device can be distributed to any number of lines. By a second counting stage, which pulses are supplied from lines 25 and 26, depending on whether one of these lines 27/1 to 27 / n carries a positive voltage or not, can within these output lines such a distribution device, which in the mode of operation of the output lines 31/1 to 31 / n of the cross switch field 29 in FIG. 1 correspond, in conjunction with a comparison device, accordingly that used in Fig. 1, a selection among the individual sectors of the previously determined Storage path take place. That is, the first selection device in connection with counting stage 2 adjusts Main program, and the second selection devices in the form of benefit devices - for each of the lines 27/1 to 27 / w is such a distribution device provided - represent the subroutines assigned to the main program.

Claims (12)

PATENT CLAIMS: 1. Control device for calling memories that are dependent on a movable carriage or slide takes effect in different columns or locations of a recording medium, characterized in that the control device has a counting device and a device for generating of pulses assigned depending on the carriage movement for each dated Car reached position and / or column actuates the counting device, which the selection associated Causes storage tracks or storage fields. 2. Control device according to claim 1, characterized in that the counting device has two Contains counters, one of which is given by the transition from one column to another Impulse is actuated while the other is given by those given within such a column per digit Impulse is operated. 3. Control device according to claim 1, characterized in that the counting device has only one Contains counter that is continuously operated in places. 4. Control device according to claims 1 to 3, characterized in that a switching device is provided, which the operation of the counter according to the direction of movement of the Trolley or carriage switches. 5. Control device according to claims 1 to 4, characterized in that the outputs of the Counter is assigned a cross switch field (29, 30) in which the memory tracks to be selected and Memory fields are optionally set to be switchable; 6. Control device according to claims 1 to 5, characterized in that with multi-link Construction of a counting stage (2) the outputs of the individual elements are placed on a switching matrix (26) are what output lines in the number of possible combinations of excitation states the counting members, one of which depending on the respective state of excitation is made effective. 7. Control device according to claims 1 to 6, characterized in that one of the position the carriage-dependent selector switch (30) via an adjusting device (33) the scanning head (35) sets on the associated track and that a second selection switch (29) determines which storage location is selected in the relevant lane. 8. Control device according to claims 1 to 7, characterized in that in each case the selection a memory lane on the memory of the selection of a column group on which the readable writing carrying record carrier and each sector of the web corresponds to a column within the group. 9. Control device according to claims 1 to 8, characterized in that the selection switch (29) a comparison or coincidence circuit (47) to select a sector of the storage path affects the connection between the sensing device and the writer only enables when the relevant sector a synchronizing track generated pulse coincides with a pulse of the selector switch. 10. Control device according to claims 1 to 9, characterized in that on the writing carriage several rows of pulse generating means are arranged, which when interacting with corresponding control means cause a selection of a storage location. 11. Control device according to claim 10, characterized in that each position of the Writing carriage corresponds to a certain code combination. 12. Control device according to claim 10, characterized in that the by the pulse generating Means generated pulses are supplied to flip-flop chains, the switching states of which in Interaction with appropriate tax means initially a selection from the individual Storage tracks and then a selection among the individual sectors. Considered publications: German patent specifications No. 559 364, 615 859,
027, 952 572; U.S. Patents Nos. 2,364,758, 2,551,093,
425; "Computing Systems", Max Planck Institute for Physics, Göttingen, 1953, pp. 60 to> 68; "Automatic Digital Calculators," Butterworths
Scientific Public, London, 1953, pp. 120 and 121; "The Design of Switching Circuits", D. van Nostvand Comp., Princeton, 1951, pp. 194 to 199; "Computer Development at the National Bureau of Standards Washington D. C", Circular 551, January 25. 1955, p.114; "Electronic Rundschau", 1955, No. 10, pp. 344 to 348; "Electronics", 1952, May issue, pp. 116 to 120; “Proc. Inst, of El. Closely. (Part II), Vol. 99, 1952, No. 68, pp. 94 to 106. For this purpose 2 sheets of drawings © 909 689/302 12.59