DE1171181B - Method and device for controlling a pulse combination - Google Patents

Description

Method and device for checking a pulse combination Es is sometimes necessary to control in electronic data processing technology, whether a combination of impulses contains a special statement within several impulse combinations occurs or not. It can be a combination of impulses that is stored in encoded form represents both digits and letters or characters and the occurs as the result of a calculation or as a memory value. So it is z. B. to Control of various booking operations common, the corresponding calculation processes, like additions or subtractions, after their termination with opposite signs to repeat. The result of this control calculation must be zero. Meets this not to, then there is a booking or calculation error. Well-known booking engines carry out this so-called zero check in such a way that the result of the Test calculation is stored in a test memory, its digits after Completed calculation is sensed in an additional tap pass and with zero be compared. If the comparison is negative, the machine will fail prevented a commando from continuing to work. Through this separate memory tap and comparison process requires an additional time that is longer than the duration of the Booking process extended.

The object of the invention is to carry out such control operations without substantial To carry out additional expenditure of time and with simple and cheap means. After this Method according to the invention this is achieved in that during the transfer of impulse combinations between two functional units of the machine when they occur the combination to be controlled by the coincidence of the associated individual pulses a switching means, e.g. B. a magnetic core is operated, its switching state according to When the value transfer has ended, it serves as a statement about the occurrence of this combination.

The circuit arrangement according to the invention for performing this Method consists essentially in that from one to the value transfer between two functional units of the machine, the number of lines to be controlled determines the number of lines Pulse combination assigned to lead through a magnetic core, which only occurs at the same time Occurrence of pulses on these lines is remagnetized, and that an output winding of the magnetic core connected to a device for evaluating the test result is. A particularly advantageous arrangement is obtained in such a way that those involved in a transmission of the pulse combination to be checked Lines are led through a first magnetic core, which only occurs when there is coincidence the impulses on these lines are remagnetized during transmission the pulse combination to be controlled by a line that is not involved further magnetic core are guided through each on one of these lines occurring pulse is remagnetized that the first magnetic core an interrogation winding which has its magnetization reversal in the same direction as the transmission lines causes and also with one with the reading winding of the first magnetic core an amplifier connected winding leads through the second magnetic core, wherein magnetization reversal only in the case of coincidence of pulses on both windings of the second core takes place, and that the second core has an output winding, in which an output pulse is generated by an interrogation pulse after the transmission has ended that reports a deviation in the pulse combination to be checked.

With such an embodiment it is possible to use all transmission lines, both the impulse-carrying when the impulse combination to be checked is transmitted as well as the rest of the currentless during this time, on their impulse-free state to control.

Further details of the invention are evident from the subclaims. The invention is based on an exemplary embodiment in conjunction with drawings explained. It shows F i g. 1 is a block diagram of part of a machine, in on which the control device according to the invention is arranged, and FIG. 2 a circuit diagram such a control device, which is the: Kntrölle-, the numerical value zero serves. An arithmetic unit 1 is with its output lines 2 with a Zero control device 3 connected, its output to the value input of a memory 4 leads. The output of the memory 4 is connected to the input of the via a line 5 Arithmetic unit 1 coupled, which also outputs values to be calculated via a line 6 received from an input unit, not shown. A value set-off via the Arithmetic unit is done by decimal place. Is intended to test various machine functions If a control calculation is carried out, the value in memory 4 becomes of an equally large value that is entered via the input unit and line 6 into the Arithmetic unit 1 arrives, deducted. The result of this operation must be zero. Step If results deviating from zero are found, this must be reported to the machine. The following Machine operations are interrupted in this case. The control device 3 therefore checks the result appearing at the output of the arithmetic unit 1 while this arrives in the memory 4 for a decade. At the end of the test calculation this will be The result of the zero check is reported to an evaluation device 8 via a line 7.

The zero control device 3 is shown in FIG. 2 shown in detail. The output line 2 from FIG. 1 consists of four transmission lines 9-1, 9-2, 9-3, 9-6, which are assigned to the code elements with the value meaning one, two, three, six. Each digit value is characterized by a corresponding pulse combination that occurs simultaneously on these lines.

For example, the number four is represented by a pulse on lines 9-3 and 9-1 , while the number eight is represented by pulses on lines 9-6 and 9-2 . Assuming that the subtraction result appears at the output of the arithmetic unit 1 as a nine's complement, the value zero corresponds to the number combination nine on lines 9, ie one pulse each on lines 9-6 and 9-3. The task of the zero control device is now to check whether the code elements three and six are actually present coincidentally in each decade and whether no pulse occurs on the other two lines 9-1, 9-2.

The lines 9-6, 9-3 lead through a magnetic core K1, which has a rectangular hysteresis curve in a known manner and can thus assume two stable magnetization states. The current intensity of the pulses occurring on the lines 9 is such that one pulse on a line is not sufficient to re-magnetize the magnetic core K 1. For this purpose, pulses occurring simultaneously on lines 9-6, 9-3 are required. The lines 9-1, 9-2 lead through a second magnetic core K1. However, they each have two turns, so that a single pulse on one of these lines is sufficient to re-magnetize core K2. The lines 9-1, 9-2, 9-3, 9-6 are connected on the one hand to the output of the arithmetic unit 1 and on the other hand to the input of the memory 4 . They therefore act as pure value transmission lines that do not have any branches. If the memory 4 is designed as a magnetic core memory in a known manner, the lines 9 can be connected directly to its input windings.

The core K1 has a winding. 10 on which clock pulses of the opposite polarity than those of the value pulses on lines 9 occur. These bring the magnetic core into an initial state of magnetization. An interrogation winding 11 leads with two turns through the core K1 and is connected in series with a winding 11a of the core K2. Pulses of the same polarity as those of the pulses on lines 9 appear on it. A read winding 12 of the magnetic core K 1 is connected to the input of a monostable multivibrator 13 acting as an amplifier and pulse shaper, to the output of which a further winding 14 of the core K2 is connected. The windings 11 a and 14 of this core each have one turn, so that they are only effective when pulses occur coincidentally. The interrogation pulse on winding 11 or 11a must therefore be timed so that it overlaps with the output signal of the monostable multivibrator. The core K2 also has an interrogation winding 15 and a reading winding 16 .

The mode of operation of the arrangement is as follows: With a clock pulse at the clock time P1, the ferrite core K1 is written via the winding 10 at the beginning of each decimal place to be transmitted. At clock time P2, the value pulses appear on lines 9-1, 9-2, 9-3, 9-6. If the result is zero, then coincident pulses occur on lines 9-3 and 9-6 which cause a change in the remanence state of core K 1. The reading pulse generated on winding 12 is amplified and shaped in monostable flip-flop 13 and offered to core K2 as half the magnetic reversal current on winding 14. Since no further pulse occurs coincident with the aforementioned pulse on the windings of this core, its remanence state does not change. In the event that no coincident pulses occur on lines 9-3, 9-6 , core K 1 retains its information stored via winding 10 at cycle time P1, which, however, it delivers to core K2 at cycle time P3. This happens because the pulse occurring at cycle time P 3 on winding 11, 11 a, coincides with the output signal of the monostable multivibrator 13 on winding 14, which occurs as a result of the read pulse induced in winding 12 when the core K1 is reversed of the core K 2 causes. The core K 2 can also be written by a pulse on line 9-1 or 9-2 or by coincident pulses on these two lines. As soon as the number core K2 to be transmitted into the memory 4 is written into the memory 4, this is an indicator that this number deviates from zero. Otherwise, if the core K2 has not changed its magnetization state during the transmission of the number, the transmitted value pulse combinations agree with zero. After all the decades have been set off at the cycle time P4, the core K2 is interrogated by a pulse on the interrogation winding 15 and transmits its information content via the reading line 16, which is connected to the line 7 in FIG. 1 is identical to the evaluation device 8 for further processing.

In a simplified form of the circuit according to FIG. 2 can do that of the reading winding 12 when the core K1 is magnetized reversed, the signal already generated reach the evaluation device 8 as the output signal of the zero control device. Here, the occurrence of an output signal shows the positive one course the zero control, namely the presence of a zero. The ad relates however, each time only applies to a single pulse combination. Besides, there is none Check whether not to the pulses corresponding to the digit zero the lines 9-3, 9-6 additionally on the lines 9-1, 9-2 any missing pulses appear.

The circuit arrangement according to the invention does not need to be based on Limit control of the digit value to zero. In the same way she can also to control any other impulse combinations that z. B. digits or Represent characters, be adapted.

Claims (12)

Claims: 1. Method for controlling a combination of pulses, which is used to represent numbers, letters or symbols and which consists of two consists of any number of code elements, especially for electronic calculating machines, characterized in that during the transmission of the pulse combinations to be controlled the pulse combination to be controlled between two functional units of the machine a bistable switching element (magnetic core K1, K2) is fed, which by coincidence the associated single impulse is actuated and its switching status after the end of the Transfer of value as a statement about the occurrence or non-occurrence of those to be controlled Pulse combination is used. 2. The method according to claim 1, characterized in that a switching state indicating a deviation from the pulse combination to be monitored of the bistable switching means to another bistable after each pulse combination Switching means is transferred, the switching state of which at the end of a transfer operation a deviation of the pulse combination to be checked for a plurality of transmitted Indicates pulse combinations. 3. The method according to claim 2, characterized in that that when a combination of impulses is transmitted, not to be controlled Impulse combination associated impulses the further bistable switching means individually or operate in combination. 4. The method according to any one of claims 1 to 3, characterized characterized in that the control is performed during a transmission of result values an arithmetic unit takes place in a memory. 5. Circuit arrangement for implementation of the method according to one of claims 1 to 4, characterized in that of one intended to transfer values between two functional units (1, 4) of the machine Number of lines (9) assigned to the pulse combination to be checked through a magnetic core (K 1), which only occurs when pulses occur at the same time is remagnetized on these lines, and that an output winding (12) of the Magnetic core connected to a device (8) for evaluating the test result is. 6. Circuit arrangement according to claim 5, characterized in that the .bei a transmission of the lines involved to be controlled pulse combination (9-3, 9-6) are guided through a first magnetic core (K1), which only occurs in the event of coincidence the impulses on these lines are remagnetized while the transmission the pulse combination to be checked not involved lines (9-1, 9-2) are passed through a further magnetic core (K2), which by each on one The pulse occurring on these lines is reversed that the first magnetic core has an interrogation winding (11) which reverses its magnetism in the same direction as effected by the transmission lines (9) and also with one with the reading winding (12) of the magnetic core (K1) via an amplifier (13) connected winding (14) leads through the second magnetic core, with only in the case of coincidence of pulses A reversal of magnetization of the second core takes place on both windings, and that the second core has an output winding (16) in which when the transfer is complete an output signal can be generated by an interrogation pulse, which indicates a deviation reports from the pulse combination to be controlled. 7. Circuit arrangement according to one of claims 5 and 6, characterized in that the transmission lines (9-1, 9-2) leading through the second core (K2) and the interrogation winding (11) for remagnetization of the first magnetic core (K1) each have two Have turns. B. Circuit arrangement according to one of Claims 5 to 7, characterized in that that the amplifier (13) is designed as a monostable multivibrator and that the Interrogation pulse on winding (11) timed with the output signal of the amplifier overlaps. 9. Circuit arrangement according to one of claims 5 to 8, characterized in that the magnetic cores (K1, K2) have reset windings (10, 15), of which the one assigned to the first magnetic core (K1) receives a reset pulse prior to transmission of each pulse combination, while the second magnetic core (K2) is reset only at the end of a transfer operation. 10. Circuit arrangement according to one of the Claims 5 to 9, characterized in that the pulse combination to be controlled represents the digit zero. 11. Circuit arrangement according to one of claims 5 to 10, characterized in that the digit zero by value pulses to two out of four Transmission lines (9-1, 9-2, 9-3, 9-6) shown in complementary form as nine will. 12. Circuit arrangement according to one of claims 5 to 12, characterized in that that the transmission lines (9) on the one hand to the output of an arithmetic unit (1) and on the other hand connected to input windings of a magnetic core memory (4) are. Documents considered: German Patent No. 1076 406.