DE1122142B - Device for program control of a keyboard - Google Patents

Description

Device for program control of a keyboard The invention relates to Devices for controlling a keyboard from a recording medium. One such a device can be selected between an input device that controls the recording medium, z. B. punched tape, punch card, magnetic tape, etc., contains, and controlled facilities are used as they are for operating the keyboards of typewriters, typesetting machines etc. are needed.

It is known from a record carrier by photoelectric Scanning generated pulses in connection with a counter for controlling machine tools to use.

In order to achieve high transmission speed and the transmission to be able to adapt to the special conditions that arise when for the Pressing the individual keys different times are required, is according to the invention, the counter with one arranged in the form of a cross switch panel Actuating device connected to the buttons. The counter brings the keys through Counting the coordinates of the cross switch field for addressing. In the cross control panel are z. B. windings or solenoids arranged in horizontal and vertical rows. The counter selects the horizontal and vertical rows, in which is the magnet coil of the desired key. The counting process can go through two multi-digit counting tubes or by counting chains, whereby for a counting tube or counting chain is provided for each point and one between the two Possibility of transmission, e.g. B. a ten-digit cross switch field and a ten-digit transfer option, consists.

According to the invention is also a device for delaying the Forwarding of the jerky perforated tape provided, depending on the defines the time of the forwarding of the key that has been activated. The length of the delay time can optionally be set.

Since the setting process takes a long time with setting machines, if two identical letters are to be set one after the other, according to the invention Means for comparing data from the punched tape sensed in immediate succession be provided when two consecutively sensed data coincide turn on a delay device.

In one embodiment of the invention, a pulse generator, e.g. B. a pulse wheel is provided which has a flip-flop chain in the manner of a binary counter advances, the number of impulses passed on by the data of the punched tape is controlled.

The device for comparing the data of successive sensations The punched tape can contain two flip-flop registers, their settings with each other be compared.

The invention will be explained in detail in connection with the drawings described. In the drawings Fig.l is the block diagram of a control circuit between a punched tape sensing device and a cross switch panel, FIG. 2 shows the basic circuit diagram a selection device, in which the selection of the cross switch field by gas discharge tubes 3 is a timing diagram showing the sequence of operations with a device Fig. 4 shows another type of signal recording and FIG. 5 shows a device similar to that of FIG. 1, but with a comparison circuit contains.

In connection with FIG. 1, the sensing of a perforated strip is first discussed and controlling a hundredfold contact field. Such an arrangement can be placed either above or below the keyboard to operate the keys be, or it can be installed in place of the normal keyboard will.

The device contains a motor 1 by which the shaft 2 is driven. This shaft 2 is connected to the toothed wheel 4 by a magnetic coupling 3. The magnetic clutch 3 is controlled by the electronic discharge device 40, which will be described further below. The toothed wheel 4 causes a gradual movement of the wheel 5 with its shaft 6 and of the wheel 7 with its shaft B.

The sensing device 9 with the sensing elements 10/1 to 10/7 is arranged above the belt 11 . The band 11 is provided with code combinations arranged transversely to the direction of movement. The belt 11 has transport holes 12 in which the transport wheel 13 engages and thus causes a step-by-step movement of the belt with the step-by-step movement of the wheel 7. The code elements are represented by punched holes 14 within the corresponding transverse rows, and it is possible to select a hundred keys with the available combinations.

The wheel 15 carries pulse generating means 16/1 to 16 / n on its circumference. These pulse generating means can e.g. B. be formed in that along the circumference in a non-magnetic material permanent magnets are arranged, which are sensed by the magnetic head 17 during a relative movement between this magnetic head and the circumference of the wheel 15.

The pulses generated by the sensed signals are fed to the monostable flip-flop 19 via line 18. This supplies pulses to the seven-digit counting chain 20 with the counting positions 21/1 to 21/7. This counting chain can be a flip-flop chain of known type and z. B. can be constructed from cold cathode thyratrons, magnetic core chains or similar components. Each of the counting stages 21/1 to 21/7 is connected to the corresponding sensing element 10/1 to 10/7 via the capacitors 22/1 to 22/7 .

The sensing elements cause the interruption points to be closed when information is present on the perforated strip. The sensing elements can be designed as contact brushes or can also be operated indirectly, e.g. B. by plungers that engage through the perforation holes 14 of the tape.

The time sequence of the pulses generated by the counting positions 27/1 to 27/7 in FIG. 1 is shown in FIG. The pulse shown in row 16/1 is generated by counting point 27/1 during a sensing period, the pulses in row 16/2 by counting point 27/2. in row 16/4 through counting point 27/3 etc.

The pulses supplied by the monostable flip-flop 19 are fed to the counting chain at the lowest level 21/7 . Within the same time during which the flip-flop counter stage of the sixty-four switched 21/7, 21/6 counting stage is thirty-two times and counting stage 21/5 sixteen times switched etc. Finally, stage 21/1 is switched once during this time. The pulse frequency of the pulses supplied by the monostable flip-flop is such that all counting stages 21/1 to 21/7 can tip over during the pause between two pulses at the input of the counting stage 21/7. The input pulses of each of the counting stages 21/1 to 21/7 are fed to the sensing elements 10/1 to 10/7 via the corresponding capacitors 22/1 to 22/7, so that there are pulse sequences according to FIG. 3, that is, within the element 10/7 sixty-four pulses, element 10/6 thirty-two pulses, element 10/5 sixteen pulses, element 10/4 eight pulses, element 10/3 four pulses, element 10 / 2 two pulses and element 10/1 only one pulse. The pulses marked by a line in FIG. 3 are arranged in such a way that the pulses of the row 16/32 lie between the pulses of the row 16/64. The pulses of the row 16/16 are offset by 16/32 , etc. compared to those of the two rows 16/64, so that a maximum of five or six pulses from the other rows are inserted into a space between the pulse row 16/64. Since these pulses all arrive at different times, a pulse sequence is produced on the line 23 which is fed to the monostable flip-flop 26 via the capacitor 25, depending on whether the corresponding code element was perforated or not. The pulse groups in some of the binary values of the code channels in each sense cycle represent the count of the code combinations sensed.

The monostable flip-flop 26 operates the counter 27 (z. B. a Dekatron) in such a way that each pulse switches the glow discharge from one point to the next, so that the counting stage 27 is operated according to the number of pulses within the aforementioned pulse group . If z. B. in the first code channel and in the third code channel a hole is punched, then the counting stage 27 within a sensing period five pulses, that is the sum of 1 + 4, supplied. The counter tube 27 is operated in a known manner, so that switching from one cathode to the next takes place when a pulse from the monostable flip-flop 26 is supplied. The glow discharge between the anode and one of the cathodes is therefore switched from cathode to cathode depending on the supply of pulses.

There is a connection from the last cathode of the counting tube 27 to the transfer device 30, which connects the counting stage 27 to a further counting stage 31. It is essential that other counters can be used instead of a decatron, e.g. B. Discharge tubes of different types, which are connected together in an arrangement according to Fig.2.

The transfer device 30 receives a pulse after every tenth pulse supplied to the counter tube 27, since only the tenth cathode is connected to this transfer device. In the drawing, only eight stages of the counter tube 27 are shown for the sake of simplicity. These transmission pulses actuate the counter 31, which - like the counter tube 27 - contains a large number of cathodes and a common anode. The circuit of each stage of the counting stage 31 contains a corresponding relay coil 34/1 to 34 / n, through which the relay contacts 35/1 to 35 / n are operated in such a way that the contact is closed, the associated counting stage in the counter conductive and all other contacts 35 are open. These contacts 3511 to 35 / n operate switching paths through the horizontal rows 37/1 to 37 / n of the key magnets 39/1 to 39 / m of the keyboard device. In these horizontal rows 37/1 to 37 / n the windings are arranged in such a way that each magnet 391 to 39 / m has a winding which is connected to a common positive pole by the corresponding contact 35/1 to 35 / n, and a winding controlled by counter tube 27.

Each of the n stages of the counter tube 27 has an output line leading to the keyboard which is connected to the corresponding line in the vertical rows 38/1 to 38 / n. These double windings result in a crosswise control of the keyboard magnets. Each of these magnets is actuated as a function of the closing of one of the contacts 35 in the corresponding horizontal row and the ignition of a discharge stage in the counter tube 27 , ie only one of the magnets mentioned is excited as a function of the position of both counting stages 27 and 31. In Fig. 1 contact 35/5 is drawn closed. The connections can be effected by amplifying trodes or similar elements.

The magnetic coupling 3 is controlled by the start-stop device 40 . This start-stop device contains the gas discharge tubes 41 and 42. The gas discharge tube 41 is ignited by a start signal which is supplied via the capacitor 43 from the line 49 to the grid. The gas discharge tube 42 is ignited by a stop signal which is supplied via capacitor 44 from the line 50 labeled “Stop” to its grid. In the discharge circuit of the gas discharge tube 41 , the cathode resistor 47 and the winding of the magnetic coupling 3 are switched on, so that this magnetic coupling is excited when the gas discharge tube 41 is ignited by a start signal.

The belt 11 is moved step-by-step under the sensing devices 10/1 to 10/7 by the wheel 8 until a signal occurs in a certain row which stops the movement of the belt. This stopping is achieved in that, in addition to a magnet coil for actuating a button, a relay coil is also arranged within the magnet arrangement 39/1 to 39 / m (not shown in the drawing). By energizing this relay, contacts are closed, one of which causes the corresponding key magnet to be energized and a second closes a circuit to the input line 50. This causes a pulse which is fed to the gas discharge tube 42 via the capacitor 44. The ignition of this gas discharge tube 42 causes the capacitor 45 to be charged, so that the gas discharge tube 41 is extinguished since the positive pole 46 has a higher potential than the anode of the gas discharge tube 41.

The gas discharge tube 42 goes out automatically after the capacitor 45 has been charged. Such a stop signal is provided by the keyboard when the signal combinations are sensed in which the normal step-by-step transport of the tape must be interrupted in order to obtain the delay time necessary before the next key is pressed. Some of these buttons can trigger different functions that require different delay times of, for example, one, two, five, ten or up to twenty normal switching steps of the tape. These delays are controlled by a delay device which includes the capacitor 57, the gas discharge tube 55 and the resistor 54 provided with multiple taps. This delay device is required in all those cases in which automatic switching is required after a certain previous delay period.

If, however, a device is provided which does not require automatic restart of the step-by-step movement process after a previous specific delay period, but instead requires a contact to take effect, then this contact will send a pulse to input line 49 labeled "Start" after the previous operation has been completed delivered. This is followed by a step-by-step further movement and sensing of the tape, as described above.

Such a start pulse can e.g. B. generated when the elevator of a line typesetting machine is operated. The movement of the elevator can be initiated by closing a contact of an appropriately selected relay in the cross field 39/1 to 39 / m, whereby the corresponding key is pressed and the switching of the belt is interrupted at the same time. After the elevator has reached its upper position, a signal is triggered, which reaches the input line 49 and there sets the starting mechanism into action.

However, other parts of such a machine may require delay times to perform other operations. These are brought about by closing the contact 52 which, depending on the position of the selection switch 53, establishes a connection with a specific one of the taps of the resistor 54 . There is thus a connection from the positive pole through the closed contact 52 and via the corresponding tap of the resistor 54 to the capacitor 57. The time constant of this circuit depends on which of the taps of the resistor 54 was connected. After the capacitor 57 has reached a certain state of charge, the gas discharge tube 55 is ignited, so that the position of the selection switch 53 determines the delay time. This gas discharge tube 55 is biased in a certain way, so that the capacitor 51 receives a pulse as a function of the delay time determined by the state of charge of the capacitor 57. This pulse can be fed to the capacitor 43 via the closed contact 48 and ignite the gas discharge tube 41 , so that the starting process is initiated. The contact 48 must remain closed in order to achieve continuous operation.

Fig. 2 shows the selection device for the various relay coils in the cross switch panel arrangement 39/1 to 39 / m. Two sets of gas discharge tubes 58/1 to 58/10 and 59/1 to 59/10 are used. These gas discharge tubes can either be connected together to form counting chains corresponding to the counting stages 27 and 31 in FIG. 1, or they can be controlled accordingly by such counting stages. The ignition of the gas discharge tubes 58/1 to 58/10 is switched to one of the control grids 60/1 to 60/10 by a pulse and the ignition of the gas discharge tubes 59/1 to 59/10 by a pulse to one of the control grids 63/1 to 63 / 10 causes. The second grid of these gas discharge tubes is biased negatively. The gas discharge tubes 58/1 to 58/10 are connected between the plus potential of, for example, 250 volts and ground potential, while the gas discharge tubes 59/1 to 59/10 are connected between ground potential and a negative potential of, for example, minus 250 volts. A relatively high-resistance cathode resistor is connected in the cathode circuit of each of the gas discharge tubes 58/1 to 58/10. These cathode resistors are denoted by 58a11 to 58a / 10 and are only provided in order to create the possibility of ignition for the gas discharge tubes 58/1 to 58/10 . Correspondingly, in the anode circuit of each of the gas discharge tubes 59/1 to 59/10 a high-ohmic resistor 59 a / 1 to 59 a / 10 is switched on in order to ignite each of these gas discharge tubes as a function of the supply of a pulse to the corresponding control grid 63/1 to 63/10 to allow.

Within the interconnections of the two rows of gas discharge tubes, the coils 39/1 to 100 are provided, which, according to FIG. 1, represent coils for actuating corresponding keys and also relay coils whose actuation requires a subsequent delay time, as described earlier. Furthermore, diodes 62/1 to 100 are provided, which are each switched into the mentioned connections between one of the gas discharge tubes 58/1 to 58/10 and one of the gas discharge tubes 59/1 to 59/10 .

The gas discharge tubes 58/1 to 58/10 can effect the vertical selection corresponding to the vertical rows in the device shown in FIG. 1, and the gas discharge tubes 59/1 to 59/10 can effect the horizontal selection corresponding to this device. There is only one switching path between one of the gas discharge tubes 58/1 to 58/10 and one of the gas discharge tubes 59/1 to 59/10, namely that which leads through the corresponding one of the coils 39/1 to 100 . For example, when the gas discharge tubes 58/1 and 59/1 are ignited, there is a switching path from the positive pole via the gas discharge tube 58/1, from there through the diode 62/1 and the winding 39a1 to the gas discharge tube 59/1 and from there to the negative pole. If only tubes 58/1 and 59/1 are ignited, only coil 39/1 is energized.

If, however, the gas discharge tubes 58/2 and 59/1 were ignited instead of the gas discharge tubes 58/1 and 59/1, then there would be a connection from the positive pole through the gas discharge tube 58/2, diode 62/2, coil 39/2 and from there via the gas discharge tube 59/1 to the negative pole. If gas discharge tubes 58/3 and 59/1 were ignited instead, a current would flow from the positive pole through the ignited gas discharge tube 58/3, diode 62/3, coil 39/3 and gas discharge tube 59/1 to the negative pole. It is essential that by energizing only two of these gas discharge tubes in each set, each of the coils 39/1 to 100 can be selected. If the mentioned gas discharge tubes 58/1 to 58/10 and 59/1 to 59/10 are controlled by counting tubes that only carry a weak current in their various counting positions, e.g. B. cold cathode counting tubes, then switching means are provided which only allow the ignition of one of the gas discharge tubes 58/1 to 58/10 or 59/1 to 59/10 after the counting tubes their final counting position after sensing a transverse row depending on the different Holes in the individual code channels. Figure 4 shows another way of delivering pulses to the various sensing elements. The impulses to the various elements are generated one after the other in this device. This arrangement can also be viewed as a timing diagram for the supply of pulses in a device according to FIG. The sensing elements are shown on the right in Fig. 4 and labeled 65/1 to 65/7 and 10/1 to 10/7. The generation of these pulse trains is shown in Fig. 4 by control by a rotating recording medium, which is shown as a development and a signal 64/1 in path 63/1, two signals 64/2 in path δ3 / 2, four signals 64/4 in lane 63/4, eight signals 64 / S in lane 63/8, sixteen signals 64/16 in lane 63/16, thirty-two signals 64/32 in lane 63/32 and sixty-four signals 64/64 in lane 63/64 . Since the signals in each lane are arranged between those in the preceding and those in the following lane, first the sixty-four signals 64/64 are passed through the magnetic head 65/7, followed by the thirty-two signals 64/32 from lane 63 during one revolution of the recording body / 32 sensed by the magnetic head 65/6 and so on, so that after the two signals 64/2 have been sensed by the magnetic head 65/2, the last signal 64/1 from path 63/1 is sensed by the magnetic head 65/1.

Fig. 5 will now be described. In this device, a pulse generator in the form of a drum 99 with magnetic heads 65/1 to 65/7 as shown in FIG. 4 is used. It contains a motor 1 with the shaft 2 and the magnetic coupling 3, via which the stepping mechanism 8 is driven, furthermore the sensing device 9 with the sensing elements 10I1 to 10/7, the belt 11 with the punched holes 14 and the drive device 13 for this belt 11, which is driven by the stepping mechanism 8 via the shaft 7. In this device, the contacts 79/1 to 79/7 are actuated indirectly by the sensing elements 10/1 to 10/7, ie they are switched by plungers that reach through the perforation holes 14, or the sensing elements 10a1 to 10/7 are designed as contact brushes which actuate relays, and these in turn switch contacts 79/1 to 79/7 . The switching of the contacts 79/1 to 79/7 takes place as in Fig. 1 transverse row by transverse row of the punched holes 14, but the device shown in Fig. 5 allows a delay between the individual sensing steps as an essential difference compared to the device in Fig. 1 . Such a delay is necessary, for example, when two identical combinations of strip 11 are sensed one after the other, since the setting process takes a long time in this case. This delay is achieved in that the previously sensed combination is stored in the flip-flops 81/1 to 81/7 and the setting of the contacts 79/1 to 79/7 made after the sensing of the following combination with the setting of this flip-flops. Flops 81/1 through 81/7 is compared. The flip-flops 81/1 to 81/7 are designed so that when one of these flip-flops switches, a positive pulse occurs on the output lines 80/1 to 80/7. The comparison of the two combinations is done in the following way: After the contacts 79/1 to 79/7 have been set by the sensing elements 10/1 to 10/7, a positive pulse is triggered in the monostable flip-flop 84, which via the individual Contacts 79/1 to 79/7 are fed to the input lines 82/1 to 82/7 or 83/1 to 83/7 according to the position of the contacts 79/1 to 79/7 , whereby the flip-flops 81/1 to 81/7 can be brought into the corresponding switching positions. The pulse supplied by the monostable flip-flop 84 also reaches the grid of the gas discharge tube 86 via the line 85 and ignites it. As a result, the delay device 87 already described in connection with FIG. 1 is activated. At the same time, the pulse supplied by the line 85 is passed on to the line 50 labeled “Stop” (see FIG. 1), thereby interrupting the advance of the strip 11. (The resistor 88 connected in parallel with the capacitor 57 in the delay device 87 serves only to create the ignition possibility for the gas discharge tube 86. However, it is so high that the time constant of the capacitor 57 and the resistor 54 is still large enough to result in sufficient delay times .) If the supply of the pulses to lines 82/1 to 82/7 or 83/1 to 83/7 resulted in a switchover of one or more of the flip-flops 81/1 to 81/7, then the corresponding lines 80 occur / 1 to 80/7 positive pulses which are fed to the grid of the gas discharge tube 90 via line 89. This ignites it. As a result of the short circuit of the gas discharge tube 86 and the resistor 54 caused by this, the capacitor 57 is charged very quickly, so that there is practically no delay time. The pulse occurring on the line 89 is, however, also simultaneously fed via the diode 91 to the line 49 (FIG. 1) labeled "Start" and sets the transport device for the advance of the strip 11 into operation again. Since the two pulses follow one another at such short intervals, an interruption of the advance of belt 11 is practically ineffective. This pulse also reaches the line 92 via the diode 91 and is fed from there to the controllable gate 93 in order to open it. The gate 93 is in the transmission path from the magnetic heads 65/1 to 65/7 (Fig. 4) to the line 94, which leads to the counting stage 27 (Fig. 1). The lines 95/1 to 95/7 lead from the magnetic heads 65/1 to 65/7 to the inputs of the gate stages 96/1 to 96/7 controlled by the flip-flops 81/1 to 81/7. These gate stages are coupled to the flip-flops 81/1 to 81/7 in such a way that when the contact 79/1 to 79/7 corresponding to one of these flip-flops has been switched through a perforation 14 , the corresponding gate stage 96 / 1 to 96/7 is open and thus allows pulses from the corresponding magnetic head 65/1 to 65/7 to pass to the common output line 97. From there, these pulses are fed to the controllable gate 98 via the opened gate 93. At the beginning of one revolution of the recording body 99, a positive pulse is fed to this gate via the line 100, which pulse opens it. As a result, the pulses fed from line 97 via controllable gate 93 to controllable gate 98 reach line 94 and can be fed from there to counting stage 27. The number of these pulses corresponds to the decimal count of the binary combination recorded in one of the transverse rows of the tape 11. Thus, they can be used to make a selection among the magnetic coils 39/1 to 39 / m in the manner described in FIG. 1. At the end of one revolution of the recording body 99, a pulse is fed to the controllable gates 93 and 98 via the line 101 , which closes them again, so that only the pulses generated during one revolution from the magnetic heads 65/1 to 65/7 are sent to the line 94 can get.

If the contacts 79/1 to 79/7 are set in the same way when sensing the next transverse row as when sensing the previous transverse row, then pulses are fed from the monostable flip-flop 84 to the corresponding input lines 82/1 to 82/7 or 83/1 to 83/7 no switching of the flip-flops 81/1 to 81/7, so that no pulse occurs on the line 89. In this case, only the pulse occurs on the line 85 and, by igniting the gas discharge tube 86 , sets the delay device 87 into action in the manner described. At the same time, as already mentioned, this pulse arrives at the line 50 labeled “Stop” and blocks the advance of the tape 11. After the capacitor 57 is charged in the delay device 87 , the gas discharge tube 55 ignites, whereby a pulse occurs on the line 103 . This impulse arrives at the line 49 labeled “Start” and thus gives the signal for the beginning of a new sensing process. At the same time, however, this pulse from the line 103 also reaches the line 92 and thus gives the possibility of receiving pulses from the magnetic heads 65/1 to 65/7 according to the setting of the flip-flops 81/1 to 81/7 and thus the controllable gate stages 96/1 to 96/7 to be delivered to line 94.

Claims (6)

PATENT CLAIMS: 1. A device for program control of a keyboard in which the control pulses taken from a recording medium feed a counter, characterized in that the counter is connected to an actuating device arranged in the form of a cross-switch field and the keys by counting the coordinates of the cross-switch field for Appeals. 2. Device according to claim 1, characterized in that a device intended to delay the indexing of the jerky perforated tape is the time of the depending on the key that is activated Defines forwarding. 3. Device according to claim 1 and 2, characterized in that that a device for the optional setting of the delay time is provided is. 4. Device according to claim 1 to 3, characterized in that a pulse generator it is provided, which advances a flip-flop chain like a binary counter, the number of transmitted pulses controlled by the data of the punched tape will. 5. Device according to claim 1 to 4, characterized in that means for Provision is made for comparison of data from the perforated tape which are sensed in immediate succession are that if they match sensed by two in a row Data switch on a delay device. 6. Device according to claim 1 to 5, characterized in that the means for comparing the data of successive Samples of the perforated tape contains two flip-flop registers, their settings be compared with each other. Publications considered: German patent specification No. 890 420; VDI magazine, 1956, No. 9, p. 366.