DE1119565B - Electronic circuit arrangement for storing decadal pulses - Google Patents

Description

Electronic circuit arrangement for storing decadic Pulses The invention relates to an electronic circuit arrangement for Storage of decadic impulse series in binary encrypted form for a specific one Class [e.g. B. (2) or (3)]. There are already electronic circuit arrangements for the inclusion of decadic series of current impulses become known, in which as storage elements stable multivibrators are used. During a save process, each rush current a certain combination of storage elements, d. H. activated flip-flops, assigned. To find the appropriate combinations while recording a series of impulses to change, the memory elements are coupled to one another in such a way that with the appropriate combination can be formed for each incoming pulse. These Couplings can be capacitive, galvanic or electronic. These rigid couplings between the storage elements allow only certain possibilities for the formation of combinations too. The reason for this is that the combination elements only in a certain order forwards or backwards with each other can be connected. This results in the encrypted recorded Current impulse series an irregular combination formation ;: d. that is, for example one, two or three combination elements can be effective. Such an irregular Combination formation means for the evaluation of stored series of current impulses a disadvantage, as the tapping elements cannot be designed uniformly.

The function of acting as storage elements is already known switchable switching elements, for example electronic flip-flops for Preparation of the switching state of gate circuits to be used: Also with the subject matter of the invention has made use of this measure. This provides an arrangement which for the storage of decadic series of current impulses a coding to a specific one Class allowed [e.g. B. (2), (3) etc.]. The fact that for every impulse one Impulse series is actuated the same number of combination elements also has with regard to the monitoring of such storage devices the notable one Advantage that if the respective actuated combination elements are exceeded or fallen below a fault in the storage process becomes apparent immediately. The inventive The arrangement is therefore designed so that the switchable switching elements with them each assigned gate circuits are arranged in a chain connection in such a way that that when applying pulses that reach all gates at the same time, only those gates are opened that can be switched by the switches assigned to them Switching elements are put in the preparatory state, and that the open Gate circuits to the switchable switching elements assigned to them each have a switching pulse give.

The invention is illustrated with the aid of exemplary embodiments the drawings explained in more detail. 1 shows a schematic flip-flop circuit with two stable time slots, Fig. 2 shows the flip-flop circuit in detail as it does is needed for this invention, Fig. 3 is a schematic representation of an electronic Coincidence gate, FIG. 4 shows the details of a coincidence gate, FIG. 5 shows a circuit arrangement for pulse storage, FIG. 6 is a basic circuit diagram for combining several Storage devices as shown individually in FIG.

In the pulse storage circuit of FIG. 5, flip-flops and electronic gates with coincidence pulses used according to the known designs.

In Fig. 1, a flip-flop which contains the two elements 0 and 1 is shown schematically. Each of the two elements 0 and 1 can assume two stable positions, which are defined as "ignited" and "extinguished". The elements 0 and 1 form the flip-flop circuit as shown in FIG. These elements are connected to one another in such a way that when one of the elements is in one of the two possible positions, the other element assumes the other position. In this way, the flip-flop can assume two stable positions. Switching from one position to the other takes place under the influence of a control pulse which is applied to a suitable point in the circuit. Such flip-flops can have multiple outputs, as is known from the prior art. In the circuit under consideration here, each of the elements contains an input and an output. Thus, element 0 has an input E0 and an output SO and, analogously, element 1 has an input E 1 and an output S 1. Furthermore, an output S'l of element 1 is shown with a dashed line, but this is in the example under consideration Output connected to the same point in the circuit as output S1.

As can be seen from FIG. 2, an exemplary embodiment of a known type is shown here. The toggle switch uses the two gas-filled tubes GO and G l. The input and output terminals are named the same as in Fig. 1. The cathode of the tube G0 is connected in parallel to ground via the resistors R10 and R20 to the capacitor C10. The point between the resistors RIO and R20 is connected to the ignition electrode of the tube G 1 via the resistor R 1. The anodes of the gas-filled tubes G 0 and G 1 are connected to an anode battery HT with a high positive voltage via the common resistor R 31. The control pulses are applied to the ignition electrode of the gas tube G 0 at the terminal E 0 via the capacitor C 20. The switching elements R 11, R 21, R 2, C 11, C 21 perform the same switching functions via the terminals E 1 and S 1 for the tube G 1 as already described for the tube GO.

The functions of the circuit in FIG. 2 develop in such a way that at the beginning the tube G 0 is ignited and the tube G1 is accordingly extinguished. If a positive control pulse is now applied to the terminal E 1, the tube G l is ignited, which extinguishes the tube GO through the common resistor R31 and the capacitor C 10. This then results in a voltage increase at the output terminal S1 and a voltage drop at the output terminal SO. If a positive control pulse is applied to terminal E0, the toggle switch is returned to its starting position.

3 shows schematically an electronic power gate, which becomes effective in the case of coincidence pulses. It contains three input terminals C 1, C 2, C 3 and an output terminal O 1. The index 3 in a circle indicates that a coincidence of three predetermined potentials is necessary, which at the terminals C 1, C 2 and C 3 must be applied to produce an output signal at terminal O 1. The direction of the arrows shows the difference between the input and output terminals.

4 shows an embodiment of coincidence gates which use switching means that are dependent on the current direction, such as selenium or germanium rectifiers Re 1, Re 2, Re3. The rectifiers are arranged in such a way that the same electrode is always connected to the common point 2. This common point is connected to the output terminal O 1 and also to the positive terminal of the battery via a resistor R 4. It can be easily seen that when one of the terminals C 1, C 2 or C 3 has a negative potential with respect to the battery potential, the potential of the point 2 and that of the output terminal O 1 become more negative than the battery voltage. The resistor R 4 provided has a suitable value with respect to the rectifiers. The output terminal O 1 is brought to a potential close to the battery voltage only when the terminals C 1, C 2 and C 3 carry positive potentials which are equal to the voltage of the battery terminal.

It is a special embodiment of a flip-flop circuit and also an embodiment for a coincidence circuit with electronic gates has been described. Arrangements for electronic coincidence circuits can of course also be used used with vacuum tubes or flip-flops with vacuum tubes or transistors will.

FIG. 5 shows a basic diagram of a counting chain in the form of a ring, which allows the storage of ten pulses, each with 2 of 5 storage elements. For this reason, five flip-flops A, B, C, D and E are used, which are designed according to the circuit arrangements shown in Fig.l and 2 respectively. Each toggle switch is an electronic gate A 3, B 3.. . E 3 assigned, each gate circuit corresponding to the arrangements shown in Fig. 3 and 4, respectively. The input and output terminals of the individual switching elements are indicated by arrows. The pulses are applied to terminal F1 as positive pulses. The latter are applied simultaneously to all electronic gates with the aid of the capacitor C 4 and the resistor R 5. Each electronic gate (e.g. C3) receives a control potential from the lower element of the previous flip-flop (in this case B 1) and additionally a control potential from the upper element of the next but one flip-flop (in this case from E0). In addition, each element of the flip-flop (C1 for the example shown) controls the triggering of the upper element of the preceding flip-flop (B0). The firing of the lower elements of the flip-flops is caused by the electronic gates assigned to them. It is also shown in dashed lines a circuit for the reset to the zero position, which will be explained in detail later.

The mode of operation of the circuit in FIG. 5 will now be described. The coding used here is as follows: Type of coding to be saved in the Digit memory circuit 0 1 1 0 0 0 1 1 0 1 0 0 2 0 1 1 0 0 3 0 1 0 1 0 4 0 0 1 1 0 5 0 0 1 0 1 6 0 0 0 1 1 7 1 0 0 1 0 8 1 0 0 0 1 9 0 1 0 0 1 In the storage system used, a 0 means a switch position in which the respective element 0 in the flip-flops is ignited and element 1 is extinguished. The number 1, on the other hand, means the reverse stable position for the flip-flop circuit. It is assumed that the circuit is in position 0 at the beginning, ie that the elements A 1, B 1, C 0, D 0 and E 0 are conductive and the other elements are deleted.

From the assumed switching state it follows that the electronic gate B 3 receives positive control potentials at its control terminals b 3.1 and 2 b 3.2, which are applied by the ignited elements A 1 and D 0. In the same way, the electronic gate C 3 receives control potentials from the elements B1 and E0 at its input terminals c3.1 and 2c3.2, the latter also being ignited. When a control pulse is applied to terminal F 1, it is fed to all electronic gates A 3, B 3, C 3, D 3 and E 3 at the same time. However, only the electronic gates B 3 and C 3 each generate an output pulse. The output pulse from gate B 3 is sent as an ignition pulse to element B 1, which is, however, already ignited, so that no switching change is achieved with it. The output pulse at the terminal C 3 is applied to the element C 1 and thus causes a switchover of the flip-flop C. The element C 1 becomes conductive and applies a positive control potential to the terminal d3.1 of the electronic gate D 3 and also to the element B 0 of the flip-flop B, causing this flip-flop to switch. After completion of these switching processes, the elements A 1, B 0, C 1, D 0 and E 0 are ignited. As a result, only the electronic gate B 3 receives positive control potentials from the ignited elements A 1 and D 0 at its input terminals b 3.1 and 2 b 3.2. If a second control pulse is now applied to terminal F 1, the output pulse of the electronic gate B 3 causes a switchover of element B, which in turn results in a switchover of element A. How the circuit works when additional control pulses are applied to terminal F 1 can be derived from the explanations given for the first two pulses. It can be seen that when nine pulses are applied to input terminals F 1 , elements A 0; B 1, CO, D 0 and E 1 are ignited. The electronic gate A 3 then receives positive control potentials from the elements E 1 and CO at its control terminals a3.1 and a3.2. When a tenth control pulse is applied to terminal F1, the electronic gate A 3 is used to switch over the stable positions of element A, which in turn results in the ignition of element E 0. The counting circuit has then returned to its rest position and thus identifies the number 0. The zero switching is carried out with the line CA, and a high voltage is applied to the line CR in order to feed the flip-flop. When the key RS is actuated, the high voltage HT is switched off, which causes all ignited elements to be extinguished and the capacitor C 5 to discharge. As soon as the key RS is brought to its rest position, the increased voltage is reapplied to the flip-flops and a positive control pulse via the capacitor C 5 and the decoupling rectifiers Ra, Rb, Rc, Rd, and Re to the switching elements A 1, B l, CO, DO, E 0 placed, which then ignite. The circuit arrangement is thus brought into its rest position.

Fig. 6 illustrates a device which allows addition of digits. When the circuit arrangement shown in Fig. 5 has counted ten pulses, it returns to the zero position and a pulse must then be transmitted to the following counter, e.g. B. the counter for tens. An electronic gate P 1 is therefore used for this purpose, which gives an output pulse corresponding to the supply of predetermined potentials to the four input terminals G1, G2, G3 and G 4, for example. Such an electronic gate can be designed like the circuit shown in FIG. The four input terminals of the electronic gate P 1 can, for. B. be connected to the output terminals of the switching elements A 1, B 1, C 0, D 0 , so that when all these switching elements are triggered, ie after receiving ten pulses, a pulse appears at the output terminal 41 of the gate P 1, which is passed through the amplifier device AM . This pulse can be applied to the terminal F 1 of the counter for tens, in the manner as described for the circuit in FIG. It will be understood that any number of counting circuits can be added in the same manner. In the same way, it is possible to arrange ring counting lungs in a chain arrangement which contain any number of switching elements in order to receive pulses with 2 of m storage elements, where m can be any number.

Claims (12)

PATENT CLAIMS: 1. Electronic circuit arrangement for storing decadic series of pulses in binary encrypted form with irregular combinations and combinations for a certain class [z. B. (2)], to prepare at the reversible switching elements, such as electronic flip-flops with two stable positions gate circuits in dependence on its switching state, characterized in that the reversible switching elements (eg. As shown in FIG. 1 and 2) associated with them in each case Gate circuits (z. B. According to Fig. 3 and 4) are arranged in a chain circuit (Fig. 5) that when impulses are applied that reach all gate circuits at the same time, only those gate circuits are opened that are assigned to them by the switchable switching elements in the preparatory state are shifted, and that the open gate circuits each give a switching pulse to the switchable switching elements assigned to them. 2. Circuit arrangement according to claim 1, characterized characterized in that the switching elements have three inputs and two outputs (Fig. 1, 2 and 5). 3. Circuit arrangement according to claim 2, characterized in that that the switching devices are arranged in chain circuits in such a way that in each case one output of a downstream switching device to the input of a upstream switching device acts. 4. Circuit arrangement according to claim 2, characterized in that the other two Outputs respectively a changeover device act on two different gate circuits, the others Switching devices are assigned. 5. Circuit arrangement according to claim 1, characterized characterized in that each gate circuit has three inputs and one output. 6th Circuit arrangement according to Claim 5, characterized in that two inputs a gate circuit with two different outputs from this gate circuit directly associated switching devices are connected. 7. Circuit arrangement according to claim 5, characterized in that the respective third inputs of all Gate circuits are connected in parallel and with the input for receiving the to storing pulses are connected. B. Circuit arrangement according to Claim 5, characterized characterized in that the output of a gate circuit with an input of the these gates each associated switching device is connected. 9. Circuit arrangement according to claim 1, characterized in that the switching devices with them assigned gate circuits are arranged in a ring circuit. 10. Circuit arrangement according to claim 1, characterized in that a switching means (button RS in Fig. 5) is provided to put the derailleur in the rest position. 11. Circuit arrangement according to claim 10, characterized in that a switching means is provided (button RS in Fig. 5) to bring the storage device into an initial position. 12. Circuit arrangement according to the preceding claims for the addition of pulse series, characterized in that after full storage of a counting chain via a gate circuit (P1 in Fig. 6) which is opened by the actuated switching devices characterizing the end position of a counting circuit and an output pulse to a further binary Counting chain (e.g. tens counting chain). References considered: U.S. Patent Nos. 2,436,963, 2,538,122, 2,558,936, 2,566,918, 2,566,933, 2,577,075,2591008; German interpretative document No. 1011179.