DE1054746B - Device for generating and storing electrical signals - Google Patents

Description

GERMAN

The invention relates to a device for generating and storing electrical signals, preferably pulses or groups of pulses, for use in electronic computing and data processing Machines with the aid of sensing means and pulse generating means moved relative to one another.

It is known, by sensing localized changes in the magnetic structure of a magnetizable Surface to generate pulses by means of a magnetic head. But if you want a relatively high one Achieve pulse train, then it is necessary either with a very high relative speed between Sensing means and the pulse recording to work, or the pulse generating means in very close succession to arrange. The latter, however, is not always possible, since it is necessary to achieve high pulse heights Place of recordings on magnetizable layers or for the generation of sync pulses Often permanent magnets are arranged in rotating, magnetically neutral bodies. With consideration for the mechanical strength of this body and the spatial expansion of the permanent magnet flakes must be such an arrangement a minimum distance must be maintained, resulting in a limited maximum pulse frequency at a given relative speed between the sensing means and the magnetic flakes Has. In addition, if the arrangement is too close, the magnetic fields of the individual permanent magnets overlap.

The known drum stores usually contain a single signal head opposite a signal path for recording and sensing the impulses. Sometimes separate recording and Sensing heads used. If now in the train z. B. ten marks are housed, then arise ten pulses when passing these ten marks at the output of one sensing head.

It has also been proposed to use several, e.g. B. provide ten heads. if If there is a marking in this lane, then this marking is generated at the outputs of the ten Heads one pulse each during one revolution, i. H. so a total of ten pulses per revolution.

A much higher number of pulses per revolution can be achieved if according to the invention several signal heads lying in a row in the direction of movement of a track are mutually below each other have the same distances, according to the vernier principle, from the distances of the pulse generating Means vary within the associated lane.

If z. B. ten markings are present in the track and arranged on the circumference of the track eleven heads then it is possible to generate one hundred and ten consecutive pulses per revolution

Facility
for generation and storage
of electrical signals

Applicant:

Dr. Gerhard Dirks,
Frankfurt / M., Mörfeider Landstr. 44

Claimed priority:
Great Britain 8 March 1956

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

produce. The same number of marks would be made in the track as there were heads on the circumference are present, then the impulses on the heads would not be generated one after the other, but simultaneously will; so you would not achieve the desired effect.

It should be noted that the vernier principle has a different effect in this context than in the usual application, e.g. B. with a calliper. While the known measuring devices Reading accuracy is to be increased, the invention is a dynamic process, namely the migration of the pulse-generating means past the signal heads, or vice versa.

The principle of the invention can be used in many ways in electronic computing and data processing Use machines; neither is it due to the magnetic generation and recording of the impulses bound, but can e.g. B. can also be used with capacitive generation of pulses.

Capacitive means can, for example, be applied in such a way that one half of the coatings of a number of capacitors are arranged with a uniform pitch "i" on a stationary insulating body in a circular path. The second half of the capacitor plates is then attached to a rotating insulation body with a division that differs by the amount + At from the original. The two bodies are arranged so that the smallest possible air gap exists between them. During one revolution, two capacitor plates will face each other after one rotation around At and, since they are determined with one)? 789/242

th voltage are biased, due to the sudden increase in capacity, a detachable on the supply lines Generate momentum. In order to obtain strong electric fields, between the individual fins, which represent the capacitor linings, further can be arranged. These will either connected to ground or biased with an appropriate voltage.

As can be seen from this illustration, a pulse occurs after each rotation around At , although the sensing means - in this case the fixed capacitor plates - by the amount t and the pulse-generating means ■ - ■ the rotating capacitor plates - by t + At from each other are away.

The arrangement is preferably made so that the spacing of the successive signal heads in the direction of movement of the track in relation to the spacing of the pulse generating means is dimensioned within the track so that all pulse-generating means of the track are assigned to all of the track Signal heads pass in a period of time in which a single pulse-generating Means moved from one signal head to the next.

The invention is described below in connection with exemplary embodiments in which Data is to be entered into a memory through a keyboard. As a transmission link between the keyboard and the memory a pulse generator is used according to the invention is trained.

There are different depending on the arrangement of the signal heads and the switching elements connected to them Executions possible.

In a preferred embodiment, a storage drum is connected to the rotating body and provided on its circumference with a series of signal fields for receiving the pulse groups. The number and the distance of the signal fields can be the number and the distance of the pulse generating Means correspond. But it can also be on the circumference of the storage drum or several fields can be provided for the execution of control functions.

To select the signal fields on the memory, a stepping mechanism can be provided that includes a series of magnetic heads is connected to a pulse generator located on the rotating body scan. In another version, the signal fields can also be selected using a counter tube done, which is connected to a magnetic head, which is located on the rotating body Pulse generator scans, the counter tube counts the scanned pulses and causes the The next pulse group is stored in a new signal field in the memory.

It is advisable to provide facilities that automatically operate when a key on the keyboard is pressed carry out a further switching of the selection device for the signal fields. It is also possible within the series of pulse-generating means to arrange one or more devices, the pulses opposite property, e.g. B. polarity, on the sensing means.

The invention is not limited to the exemplary embodiments described, but can also be used in other devices that rely on the generation of pulses in rapid succession arrives with the help of circumferential facilities.

On the basis of the drawings there are now three

Application examples of the invention shown. It shows

1 shows the block diagram of an input device, FIG. 2 shows the schematic arrangement of the sensing and impulse-generating means,

3 shows the block diagram of a further input device,

4 shows the associated schematic representation of the sensing and pulse-generating means,

ίο Figure 5 is a block diagram of a third input device according to the invention.

Fig. 6 shows the associated schematic representation of the sensing and pulse generating means.

The device according to FIG. 1 contains a magnetic drum store, the jacket of which is shown as a development 1 . 1 also contains a pulse generator 2. This consists of a rotating body, the development of which 3 and the corresponding sensing elements 4/1 to 4/11 and 5/1 to 5/10 are shown. Both drum storage 1 and the rotating part 3 of the pulse generator 2 are attached to the common shaft 3 a , which is driven by motor 3 b . The device serves to display digits which are keyed into the keyboard 6 in the form of magnetic recordings on the drum memory 1 . The drum memory 1 is divided into individual sectors 7/1 to 7/11, each of which is assigned to one digit of the numbers to be recorded. The count values of the individual digits of this number are represented by the pulse groups 8/1 to 8/11 . The individual pulses that are recorded within the pulse groups 8/1 to 8 / n are induced in the magnetic heads 5/1 to 5/10 , while the selection of one of the sectors 7/1 to 7/11 depends on the position of the Switching arms 9 and 10 of a rotary selector takes place.

The number of pulses within one of the pulse groups 8/1 to 8 / n is determined by which of the keys 11/1 to 11/0 of the keyboard 6 is pressed. The individual pulses are generated in that the magnetic structural changes 12/1 to 12/11 applied to the lateral surface 3 move in the direction of arrow 13 relative to the magnetic heads 5/1 to 5/10. These magnetic structural changes are represented either by recording on a magnetizable layer or by permanent magnets in a magnetically neutral body. According to the statements made earlier, magnetic head 5/1 is first influenced by recording 12/1 , then magnetic head 5/2 by recording 12/2 , etc., until at the end of a movement by the amount i - At magnetic head 5/10 by the Record 12/10 is affected. As can be seen from Fig. 1, the magnetic heads 5/1 to 5/10 are spaced from one another by the amount t. The individual records 12/1 to 12/11 , on the other hand, are only at a distance of t - At from one another, that is, after each further movement of the rotating body 3 by the amount A t , one of the magnetic heads 5/1 to 5/10 is passed through one of the Recordings 12/1 to 12/11 influenced and thus induced an impulse in it. After each movement phase by the amount t , a pulse is induced in one of the magnetic heads 4/1 to 4/11 by the recording 14. Record 14 is shifted by the amount A t / 2 compared to record 12/1. The pulses induced in the magnetic heads 4/1 to 4/11 are used to select one of the sectors 7/1 to 7/11 . Each of the sectors 7/1 to 7/11

extends along the circumference on the drum storage unit over the amount t - At. In the present embodiment, At = tili.

The arrangement of the sensing means and the memory sectors is shown schematically in FIG. The individual circular paths on which the aforementioned elements are arranged are drawn as concentric rings in this figure. In circular ring 15 , the magnetic heads 5/1 to 5/10 are shown by the markings 5/1 to 5/10 , while the associated magnetizations on circular path 16 are shown by the markings 12/1 to 12/11 . The sensing heads 4/1 to 4/11 and the magnetization 14 are shown by the marking 14 on the circular paths 17 and 18 . In circular path 19 , the division of the outer surface of the drum storage device 1 by the circular ring sectors 7/1 to 7/11 is shown. Furthermore, a magnetic head 20 is provided, by means of which the recording of the pulses on the drum memory 1 takes place. As can be seen from the figure, each of the sectors 7/1 to 7/11 extends over the same angle as the distance between two of the magnetic heads 4/1 to 4/11 and the magnetization 12/1 to 12 / 11 corresponds.

If a number entered in keyboard 6 is to be recorded on drum memory 1 , then the first digit of this number is represented by pulses in sector 7/1 , the second digit by pulses in sector 7/2 , etc. The individual sectors are selected in Depending on the position of the two switching arms 9 and 10 (Fig. 1). With the first digit keyed into the keyboard 6 , these switching arms are in the initial position shown, so that the two magnetic heads 4/1 and 4/2 are effective.

The recording 14 is sensed by the magnetic head 4/1 during each revolution of the rotating body 3, and a pulse is thereby sent via line 21, the switching arm 9 and line 22 to the input of the amplifier 23 . After amplification in the amplifier, the pulse passes through line 24 to the input of the controllable gate 25. This controllable gate 25 is opened by pulses which are supplied to line 26, that is, it is switched so that pulses supplied on line 24 the gate can pass, and it is closed by pulses that are fed to line 27 , ie blocked for pulses on line 24. The pulses on line 27 are generated in magnetic head 4/2 during each revolution by recording 14. Of this magnetic head, they pass via line 28, the switching arm 10 and line 29 to the input of the amplifier 30. In this they are amplified and passed via line 27 to the controllable gate 25 is supplied. At the same time they reach the controllable gates 33 and 34 via the lines 31 and 32 , which are also closed as a result. Since there is initially no pulse on line 26 , pulses from line 24 cannot pass controllable gate 25. This gate is opened when one of the keys 11/1 to 11/0 of the keyboard 6 is depressed . This is done by switching over the corresponding contact 35/1 to 35/0 when one of these keys is depressed. In the rest position, all contacts 35/1 to 35/0 are in the illustrated switching position "a". In this case, they are connected in series and connect the capacitor 36 to the input line 37 of the working magnet 38 of the rotary selector. In the rest position of the contacts 35/1 to 35/0 there is accordingly a series connection of positive pole 39 via capacitor 36, line

device 40, the series connection of the contacts 35/1 to 35/0, the working magnet 38 to the negative pole 41. Since a DC voltage is applied to the terminals 39 and 41 , the working magnet 38 is initially not excited. When one of the buttons 11/1 to 11/0 is pressed, the associated contact 35/1 to 35/0 is switched from switch position “a” to switch position “b” . As a result, capacitor 36 via line 40, the corresponding one of the contacts 35/1 to

ίο 35/0 and resistor 42 discharged. As a result of this discharge process, a negative pulse occurs on line 26 , which opens the controllable gate 25. This makes it possible for the impulse induced in the magnetic head 4/1 to pass the controllable gate 25 after one of the keys 11/1 to 11/0 has been depressed.

Simultaneously with switching over one of the contacts 35/1 to 35/0 , the associated one of the contacts 43/1 to 43/0 is closed. By closing one of these contacts, the number of pulses recorded on the Trommeiao memory 1 in the corresponding sector is determined. B. the button 11/6 contact 43/6 is closed and thereby causes a recording of six pulses in the corresponding sector 7/1 to 7/11.

When the button 11/0 is pressed, however, no expensive function is triggered by the contact 43/0 , so that no recording takes place on the drum memory 1. The impulses are selected when one of the contacts 43/1 to 43/9 closes one of the magnetic heads 5/1 to 5/9 via the closed contact 43/1 to 43/9 and line 44 to the input of the amplifier 45 is connected. This makes it possible to feed the pulse generated in the corresponding magnetic head by one of the recordings 12/1 to 12/11 from amplifier 45 via line 46 to the controllable gate 34 . If the output of this pulse by the amplifier 45 during the period in which the corresponding one of the sectors is 1.7 to 11.7 in the up-drawing position with respect to the magnetic head 20, then the controllable gate 34 is opened and the current supplied on line 46 pulse can be picked up on line 47. The controllable gate 34 is opened by the pulse generated in the magnetic head 4/1 by the recording 14 , which can pass the controllable gate 25 after pressing one of the buttons 11/1 to 11/0 and is fed to the controllable gate 34 via line 48 . This is opened by the pulse occurring on line 48 , so that pulses from line 46 can reach line 47 . The pulse induced in one of the magnetic heads 5/1 to 5/9 is fed from line 47 to the controllable gate 33 , whereby the gate is opened. As a result, all of the pulses generated in the magnetic heads 5/2 to 5/10 , which reach line 50 via diodes 49/2 to 49/10 and are amplified in amplifier 51 , pass through controllable gate 33 and become the recording amplifier via line 52 53 supplied. After they have been amplified in this, they are recorded by the recording head 20 in the corresponding one of the sectors 7/1 to 7/10 . In the illustrated switching position of the switching arms 9 to 10 , the recording takes place, for example, in the sector 7/1 . As already stated above, a pulse is induced in the magnetic heads 5/1 to 5/10 after each rotation by the amount Δt of the recording medium 3. If the button 11/6 is now pressed, for example, then six pulses must be recorded on the drum memory 1. The moving part of the

taktes 43/6 is connected to the magnetic head 5/4 via line 54/6 . A pulse is then generated in this magnetic head 5/4 when the recording 12/4 moves past it. This pulse now reaches the controllable gate 33 via the closed contact 43/6 in the manner described and thus establishes a switching connection from the line 50 to the recording amplifier 53 . After a pulse has been induced in the magnetic head 5/4 , after each rotation by the amount Δ t in the magnetic heads 5/5 to 5/10 , a pulse is generated by the recordings 12/5 to 12/10. These six pulses in total reach line 50 via diodes 49/5 to 49/10 and are fed from there to recording amplifier 53 . After the recording 12/10 has induced a pulse in the magnetic head 5/10 , the recording 14 becomes effective on the magnetic head 4/2 , and a pulse thus reaches the amplifier 30 via the line 28, the switching arm 10 and the line 29.

From the output line 55 of the amplifier 30 , this pulse is fed to the control lines 27, 31 and 32 of the controllable gates 25, 33 and 34 , whereby these are closed. In this way, the transmission path from line 50 to recording amplifier 53 is first interrupted and further recording of the pulses induced in magnetic heads 5/2 to 5/10 is avoided. By closing the controllable gate 34 , a second sensing of a pulse from the magnetic heads 5/1 to 5/9 via the closed buttons 11/1 to 11/0 is avoided, so that a double recording of a digit that has only been keyed in once is not possible. By closing the controllable gate 25 , a renewed opening of the controllable gate 34 by the impulse induced in the magnetic head 4/1 by the recording 14 is made impossible. After the pulses have now been recorded on one of the sectors 7/1 to 7/11, in the present case on sector 7/1, the pressed button 11/1 to 11/0 returns to its starting position. This also switches the associated contact 35/1 to 35/0 back to its starting position "a". This has the effect that now a circuit from positive pole 39 via capacitor 36, the switch position "a" of all contacts 35/1 to 35/0 and line 37 to the working magnet 38 of the rotary selector and from there to negative pole 41 is closed. Since before when one of the keys 11/1 to 11/0 was depressed, capacitor 36 was discharged via resistor 42 , this capacitor is now charged. The charging current flowing in the process excites the working magnet 38 and thereby switches the two switching arms 9 and 10 one step further in the direction of the arrow 56. This has the effect that when one of the keys 11/1 to 11/0 is pressed down the start pulse, which was previously induced in magnetic head 4/1 , is now induced in magnetic head 4/2 and thus the second digit entered is recorded in the sector 7/2 takes place on the drum storage 1 in the manner described above. After all digits of a number have been keyed in, the two switching arms 9 and 10 are switched back to the starting position shown by a return device, not shown. From the drum memory 1 , the recorded values can be entered into any other electronic device for further processing.

Fig. 3 shows a further arrangement for entering digits via a keyboard in a drum

Storage. In this device, too, the pulses representing the individual counted values are generated by an arrangement of sensing means and pulse generating means according to the invention. However, the device differs from that shown in FIG. 1 by a different selection of the storage locations on the drum store. In this embodiment, too, the circumference of the drum store is divided into individual sectors 62/1 to 62/11

ίο divided. However, only sectors 62/1 to 62/10 are used as storage locations for the number to be recorded. During the time in which sector 62/11 is in the sensing position, control functions or the like can be carried out. The apparatus includes for entering the digits keyboard 56 and a pulse-generating elements, the rotating bodies 57 and 58. These are secured together with the drum memory 59 on the shaft 60 which is driven by motor 61st The selection of the individual

ao nen sectors 62/1 to 62/10 is carried out by the ten-digit counter 63 in this case. As can be seen from Fig. 4, the sectors 62/1 to 62/11 extend over an angle which is the distance between two of the Records 64/1 to 64/11 on the rotating body 57 corresponds. The records 64/1 to 64/11 are sensed by the magnetic heads 65/1 to 65/10. Furthermore, a magnetic head 6 is provided, in which pulses are induced which are used for the counting device 63 to continue counting. The rotating body 58 carries a single record 67 which marks the beginning of a revolution and which is sensed by the magnetic head 68. The spatial arrangement of the individual recordings and the sensing elements is shown in greater detail in FIG. In this figure, too, according to FIG. 2, the individual circular paths on which the sensing elements or the recordings are attached, and the surface of the drum store 59, are represented by concentric circular rings. The individual magnetic heads 65/1 to 65/10 are shown on circular ring 69 by the markings 65/1 to 65/10 . The markings 64/1 to 64/11 , which correspond to the recordings 64/1 to 64/11 on the rotating body 57 , are shown on the circular ring 70 . The circular ring 71 only contains the marking 66, which corresponds to the magnetic head 66 in FIG. 3. The circular ring 72 shows the markings 68, which correspond to the magnetic head 68 , while the circular ring 73 shows the marking 67 , which corresponds to the recording 67 on the rotating body 58.

The circular ring 74 shows the division of the drum store 59 into individual sectors 62/1 to 62/11 . One of these sectors is selected when one of the keys 75/1 to 75/0 is pressed down in the following way: When one of the above-mentioned keys is pressed , the corresponding one of the contacts 76/1 to 76/0 is closed, causing a pulse from the positive pole 77 to pass through it Contact and control line 78 reaches the controllable gate 79. This is opened so that the pulse induced by the recording 67 in the magnetic head 68 , which has been amplified in the amplifier 80 , can reach the control line 81 of the controllable gate 82 , whereby this is also opened. Thus, a switching path is created from magnetic head 6 via amplifiers 83 and 136 to input line 84 of ten-digit counter stage 63. As a result, the pulses induced by recordings 64/1 to 64/11 in magnetic head 66 reach this counter stage 63 and count them in each case

1

by one counting point. After ten pulses have been fed into counting stage 63, a pulse occurs on output line 85, which is fed to controllable gate 87 via controllable gate 85 a and control line 86. This is opened, and there is now a switching connection from one of the magnetic heads 65/1 to 65/9 via one of the lines 88/1 to 88/9, the contact closed by pressing one of the buttons 75/1 to 75/0 contacts 89/1 to 89/9 and the common line 90 through the amplifier 91 and the opened controllable gate 87 to the input line 92 of the controllable gate is 93. α the controllable gate 85 by the previously generated by the recording pulse 67 which via the control line 85 b reaches the controllable gate 85 a, open. The controllable gate 85 a is closed by the pulse occurring on line 86 , which is fed to this via line 86 a. If, for example, the button 75/5 has now been depressed, then five pulses must be recorded on the first sector 62/1 of the rotating memory 59.

These five pulses are part of the recordings 64/1 to 64/11 in the magnetic heads 65/2 to 65/10 induced pulses. These reach the input line via diodes 94/2 to 94/10 95 of the amplifier 96 and from there via the controllable gate 93 to the recording amplifier 97. After if they have been amplified in this, they are recorded on the drum memory 59 by magnetic head 98. Since the controllable gate 93 is closed in the idle state, pulses from the magnetic heads 65/2 to 65/10 only get to the recording amplifier 97 when, via line 90, the Amplifier 91 and the controllable gate 87 are fed a pulse to the controllable gate 93 and this with it opened. Since the supply of such a pulse depends on which of the buttons 75/1 to 75/0 was depressed, it thereby becomes the number of pulses supplied to the recorder amplifier 97 certainly. In the example described, the one generated in magnetic head 65/5 by recording 64/5 Pulse fed through contact 75/5 of the control line 92 of the controllable gate 93 and this thereby opened. At the same time, this pulse came from control line 92 to control line 87ir of the controllable Gate 87, which in turn closed it. Thus, the first impulse caused by the recording 64/6 in the magnetic head 65/6 generated the controllable gate 93 via the diode 94/6 and amplifier 96 and fed from there to the record amplifier 97. In the same way, get through the Recordings 64/7 to 64/10 in the magnetic heads 65/7 to 65/10 induced pulses to the recorder amplifier 97. It can be seen from Fig. 4 that after recording 64/10 the magnetic head 65/10 has happened, the recording 64/11 is sensed by magnetic head 66. The impulse induced thereby is amplified by amplifier 83 and fed to controllable gate 93 via line 99. This will this is closed and thus a further pulse output to the recording amplifier 97 is avoided. Before the recording 67 was sensed for the second time by magnetic head 68 and that in amplifier 80 was amplified The pulse is fed to the control line 81 of the controllable gate 82 via the open controllable gate 79. This was closed so that the counter stage 63 only during one revolution eleven pulses induced in magnetic head 66 were applied. When the controllable gate 82 is closed

746

a pulse is generated on line 100, which is fed to the controllable gate 79 and this thereby closes. Thus, the further pulses induced by recording 67 in magnetic head 68 cannot get more to the control line 81 of the controllable gate 82, so that this during a key press is only opened and closed once.

In the example just described, an output pulse was generated on output line 85 of counting stage 93 after ten pulses fed into input line 84. However, since a total of eleven pulses were fed to the counting stage 63 during this recording period, when one of the keys 75/1 to 75/0 is pressed the second time, the starting position of the counting stage 63 is the count "I". Accordingly, an output pulse occurs on output line 85 after nine pulses fed into input line 84. This means that the second digit is recorded in the sector 62/2. Since the counting capacity of the counter 63 is ten, but eleven pulses are fed to input line 84 during each recording period, the number of pulses to be fed in until an output pulse is output on output line 85 after each digit has been recorded is reduced by one. That is, at the tenth digit, the pulse on line 85 occurs after the first one applied to line 84. Since a total of eleven pulses are supplied to line 84 during each collection period, thus occur in recording the tenth digit in two pulses to line 85, of which only one is effective because the first already the controllable gate 85 has closed a.

FIG. 5 shows the block diagram of a further input device according to the invention. This contains the keyboard 136 with the keys 137/1 to 137/0. A rotating disk 138 with the magnetic structural changes 139/1 to 139/10 and 140 is also provided in this device as a pulse-generating means. This is attached to the shaft 142 together with the rotating disk 141, the magnetizable outer surface of which represents a drum storage device, and is driven by the motor 143. The magnetization 140 is such that it generates negative pulses in the sensing heads 144/1 to 144/11, while the magnetization I39 / I to 139/10 generates positive pulses in the sensing heads 144/1 to 144/11. The negative pulses are used to select one of the sectors 145/1 to 145/11, into which the outer surface of the rotating disk 141 is divided. The positive pulses which are generated in the sensing heads 144/1 to 144/11 are used to represent the individual digits to be recorded. One of the sectors 145/1 to 145/11 is selected as follows: When one of the buttons 137/1 to 137/0 is pressed, the associated contacts 146/1 to 146/0 are switched from switch position "a" to switch position "6" «Switched. These contacts 146/1 to 146/0 are connected in series in the idle state and thus close a circuit from the positive pole 147 via the capacitor 148 and the winding of the working magnet 149 of a rotary selector to the negative pole 150. Since a DC voltage is applied to the terminals 147 and 150 ″, in the idle state there is no excitation of this working magnet 149. If one of these contacts is switched from switch position “a” to switch position “b” , then capacitor 148 discharges through resistor 151. As a result, a negative pulse occurs on line 152, which the controllable gate

809 739/242

153 is fed. This is opened, so that now negative pulses which feel in the Ab 144/1 to 144/11 are generated via the diodes 154/1 to 154/11, the contact arm 155 of the Rotary selector, amplifier 156 and the controllable gate 153 on control line 157 of the controllable gate 158 can get. This opens it, so that now the positive impulses, which in the sensing heads 144/1 to 144/11 are generated via the diodes 159/1 to 159/11 and the common line 160 and amplifier 161 can reach line 159 via controllable gate 158.

In the starting position of the switching arm 155 shown, the negative generated in the sensing head 144/1 arrives Pulse via diode 154/1 to the input of amplifier 156. As can be seen from FIG Moment when a negative pulse is generated in sensor head 144/1 by recording 140, the sector 145/1 in the recording position opposite magnetic head 162.

In Fig. 6 are again the individual circular paths on which the sensing elements or the pulse-generating Magnetic structural changes are arranged, represented by circular rings. In circular ring 163, the sensing heads 144/1 to 144/11 are represented by corresponding markings 144/1 to 144/11. On the circular ring 164, the magnetizations 139/1 to are through the markings 139/1 to 139/10 139/10, while the magnetic structural change 140 is represented by the marking 140 is. Furthermore, the individual sectors 145/1 to 145/11 of the drum store 141 are in the circular ring 165 shown. Marking 162 on circular ring 166 identifies the position of the recording head 162.

If the switching arm 155 is now switched one position further, the magnetic head 144/2 becomes effective, that is, the negative impulse induced by the magnetic structural change 140 in the magnetic head 144/2 reaches the controllable gate 158 via the amplifier 156 and the controllable gate 153 6 again shows that at the moment this pulse is generated, sector 145/2 is in the recording position opposite magnetic head 162. Switching arm 155 is indexed one place after each digit has been recorded, so that the individual digits are recorded one after the other in sectors 145/1 to 145/11. The determination of how many pulses are to be recorded in each of the sectors 145/1 to 145/11 is made by selecting one of the buttons 137/1 to 137/0. If one of these buttons is pressed, the associated contacts 163/1 to 163/0 are switched from its switch position “a” to switch position “b” . If one of the buttons 137/1 to 137/9 is pressed, this switching of the corresponding contact 163/1 to 163/9 causes a negative pulse from negative pole 164 via capacitor 165 and the corresponding one of contacts 163/1 to 163/9 of the associated lines 166/1 to 166/9. Each of these lines leads to one of the cathodes of the counting tube contained in counting stage 167. As a result of this negative pulse thus delivered to the corresponding cathode, the glow discharge which exists within this counting tube migrates to this selected cathode, so that the counting stage 167 is preset. The counting stage 167 corresponds to that shown in FIG. 10, with the exception that in this embodiment all cathodes are connected to ground via cathode resistors. The connection between contacts 163/1 to 163/9 is complementary, ie contact 163/1 is connected to cathode 129/9 via line 166/1, while contact 166/9 to cathode 129/1 via line 166/9 connected is. This complementary presetting determines the number of recorded pulses according to the count of the associated key 137/1 to 137/0. When the button 163/0 is depressed, the controllable gate 168 of the positive pole 169 is switched to switch position "&" of this contact and

ίο A positive pulse is supplied to control line 170, which closes it. Contact 163/0 closes somewhat delayed compared to contact 146/0, so that the positive impulse occurring on line 152, which arrives at controllable gate 168 via line 171, first opens this and then that by closing contact 163/0 via line 170 supplied pulse this in turn closes. By closing this controllable gate 168 it is avoided that when the button 137/0 is pressed, pulses are recorded in the corresponding sector. If, for example, button 137/6 is now depressed, a positive pulse is initially generated on line 152, as already described, which opens the two controllable gates 153 and 168. At the same time, a negative pulse is sent to the counter stage 167 via line 166/6 and sets it to the count value "4". When the body 138 rotates in the direction of the arrow 172, a negative pulse is now generated by the magnetization 140 in the magnetic head 144/1, which via diode 154/1, the switching arm 155, amplifier 156 and the open controllable gate 153 on control line 157 of the controllable gate 158 got. This closes it. At the same time, this pulse reaches the controllable gate 153 via control line 137 and closes it again, so that a second sensing of a negative pulse generated by the magnetization 140 is not possible. By opening the controllable gate 158, the positive impulses generated by the recordings 139/1 to 139/10 in the magnetic heads 144/1 to 144/11 reach the input of the amplifier 161 and via the corresponding diodes 159/1 to 159/11, after they have been amplified in this, via the controllable gate 158 to the line 159. From there they are fed to the input line 175 of the counting stage 167 via the amplifier 174. At the same time they reach the input line 177 of the recording amplifier 178 via line 176 and the open controllable gate 168. After they have been amplified in this, they are recorded by the recording head 162 in sector 145/1 of the drum memory 141. The pulses fed to input line 175 continue to count counting stage 167, starting at counting position "4". After six pulses have been fed in, the counting stage 167 has reached its maximum counting capacity "10", and a positive pulse thus occurs on output line 179, which is fed to the controllable gate 158. This closes it and prevents any further pulse feed to the counting stage 167. At the same time, the pulse supply to the recording amplifier 178 is also blocked, so that only these six pulses were recorded in sector 145/1. After this process is finished, the depressed button 137/6 goes back to its rest position, and a circuit is now closed from positive pole 157 via capacitor 148, the series connection of contacts 146/1 to 146/0 and the winding of the working magnet 149 of the Rotary selector to the negative pole 140. This charges capacitor 148 and the working magnet 149 through the charging

Claims (10)

current excited. By this excitation, contact arm 155 is indexed one position. Magnetic head 144/2 is now connected to the input of amplifier 156 via diode 154/2. If the second digit of a number to be recorded is keyed in by pressing S one of keys 137/1 to 137/0, the process just described is repeated, with the exception that the negative pulse induced in magnetic head 144/2 switches the controllable gate 158 in contrast to the previous recording phase, where the pulse generated in magnetic head 144/1 has opened this controllable gate. This ensures that the pulses which represent the second digit are recorded in the sector 145/2 on the drum memory 141. The following digits are recorded in the same way. After all the digits have been recorded, the contact arm 155 of the rotary selector is switched back to its starting position by a reverse circuit (not shown). The symbols recorded on the drum memory 141 can be input into other electronic computing or other devices in any desired manner. After the entry has been made, the memory 141 can be erased and a new number can thus be recorded by the device shown. Patent claims: 1. Device for generating and storing electrical signals, preferably pulses or pulse groups, for use in electronic computing and data processing machines with the aid of sensing means moved relative to one another and pulse generating means, several of which in a row one behind the other in the direction of movement while maintaining constant Minimum distances are arranged, characterized in that several in the direction of movement Signal heads lying in a row on a track are equidistant from one another, according to the vernier principle of the distances of the pulse-generating means within deviate from the associated track. 2. Device according to claim 1, characterized in that the distance between the successive Signal heads in the direction of movement of the track in relation to the spacing of the pulse generating ones Means within the track is dimensioned so that all pulse-generating means of the Track past all signal heads assigned to the track in a period of time in which a moving a single pulse generating means from one signal head to the next. 3. Device according to claim 1, characterized in that the capacitive design of the Set up the signal heads each with an assignment and the pulse-generating means each with a different assignment a capacitor included. 4. Device according to claims 1 to 3, characterized in that when using the per se known magnetic pulse generation, the pulse generating means as ferromagnetic strips or records on part of a rotating storage drum and the signal heads are designed as lying on the circumference of the track magnetic heads. 5. Device according to claims 1 to 4, characterized in that the number and the distance of the signal fields on the storage drum equal to the number and the distance of the pulse generating Means is. 6. Device according to claims 1 to 5, characterized in that on the circumference of the Storage drum also provided one or more fields for performing control functions are. 7. Device according to claims 1 to 6, characterized in that a selection device z. B. is provided in the form of a keyboard which, when actuated, for. B. when depressing one key causes a corresponding group of pulses to be sent from the signal heads to the signal fields of the memory is released. 8. Device according to claims 1 to 7, characterized in that for the selection of the signal field a stepping mechanism is provided on the memory, which is connected to a number of magnetic heads is connected, the number of which is equal to the number of pulse generating means in the track and which scan a pulse generator located on the rotating drum. 9. Device according to claims 1 to 8, characterized in that for the selection of the Signal fields on the memory a counter tube is provided, which is connected to a magnetic head that scans the pulse generator located on the rotating drum, and that the counter tube the sampled pulses counts and causes the next pulse group on a new one Signal field of the memory is recorded. 10. Device according to claims 1 to 9, characterized in that within the series of pulse-generating means one or more devices are arranged, the pulses opposite Property, e.g. B. polarity, generate in the signal heads. Considered publications:
German Patent No. 900026;
U.S. Patent Nos. 2,540,654, 2,721,990. For this purpose 2 sheets of drawings © 809 '789/242 3.59