DE1070675B - - Google Patents

Description

GERMAN

kl. 21 al

INTERNAT. KT ,. H 03 k

PATENT OFFICE

D 26844 VIII a / 21a ¹

REGISTRATION DATE: NOVEMBER 16, 1957

NOTICE
LOGIN
AND ISSUE OF THE
EDITORIAL: DECEMBER 10, 1959

In many cases, modern communications technology uses transmission systems that operate according to the start-stop procedure work ', whereby - depending on the purpose - 5, 6, 7 or even more steps extensive Alphabets are used. The distribution and control devices of the available for this purpose Transmission devices are usually powered by electric motors through mechanical clutches and are fixed in their working speed. They are therefore sufficient - ■ especially in radio operation - often not meeting the requirements, e.g. because it is desirable here, the message transmission speed to be able to adapt to the transmission conditions prevailing on the radio path.

It is true that telegraph systems have also become known in which, while maintaining rotating Distribution and scanning devices a variation of the telegraph speed and an adaptation to it respective transmission conditions is possible (synchro telegraph); ' set such orders but due to the rotating distribution and scanning devices always a perfect synchronization between the sending-side distributor and the receiving-side sampler. voraus, the complicated synchronization devices conditional.

The device according to the invention completely dispenses with the use of mechanical working distribution and scanning devices, it therefore allows an adaptation of the telegraph speed to the existing transmission conditions without complex synchronization devices. Since the If the distribution circuit does not contain any mechanical switching elements, the message transmission speed is only limited by the performance of the devices that mark the message, some of which are higher than those of the mechanical ones Distributor.

They are already in themselves. Facilities for converting and evaluating character combinations known, which work with a fir tree-like branching of relay contacts, also known as a relay pyramid referred to as. Such arrangements are very prone to failure due to their large number of contacts and laborious. It is therefore already an evaluation device based on the crossbar principle known, in which the switching contacts are replaced by appropriately biased diodes. One Such an arrangement is also used as a diode or selector matrix due to its column and line structure designated. With such a selector matrix, the number of electronic changeover switches (diode pairs) increases not analogous to the relay pyramid with the position of the code step within the step combinations but it will be evaluated for each of the facility

a binary code composed of η code steps

Applicant:

Dr. phil. habil. Oskar Vierling, Ebermannstadt, Pretzfeider Str. 23

Dr. phil. habil. Oskar Vierling, Ebermannstadt, Rudolf Röseler and Otto Schulz, Darmstadt,

have been named as inventors

2 " possible step combinations a number of diodes corresponding to the number of steps η , that is," times 2 " diodes are used. The diodes assigned to a step are connected to the potential of a bistable multivibrator, on which the associated code step acts according to its polarity. The multiple connection of the diodes takes place in such a way that at. 2 "- 1. of the 2" possible current paths, the voltage is diverted through shunts, so that a voltage only remains in one current path. This non-derived voltage is used as an evaluation criterion. Such an evaluation principle is necessary. however, a high expenditure on electronic switching elements, namely η 2 " diodes and a very large operating current over 2" -1 shunt circuits.

The invention also relates to a device for evaluating a binary code composed of η code steps and therefore 2 ″ step combinations with the aid of an electronic selection device that takes on the task of the known relay pyramid, in which the η code steps of a combination each control a bistable multivibrator according to their polarity The characteristic feature of the invention is that the selection of the flip-flop associated with the respective step is effected by an M-stage ring counter which is advanced in time with the received step sequence, which counts each step only on the flip-flop assigned to it according to its position within the step combination In contrast to the selector matrix described above, each of the η bistable switching stages furthermore actuates a number of 2 ⁿ - 1, each consisting of one diode, which increases with the position of the code step within the step combinations in a geometric progression. or pair of transistors existing electronic Um ^

909 688/291

switches that are connected to each other to form a branching chain circuit, so that the respective position of the η flip-flops and thus the switch only forms one of the 2 "possible circuits; for the evaluation elements arranged at the 2" ends of the chain circuit.

In an evaluation circuit constructed according to the teaching of the invention, only one of the 2 "possible circuits is switched through to the output, a pressure magnet or the like can then be excited directly via the selected output Expenditure on electronic switching elements and operating current. For the evaluation of a 0-digit code, a selector matrix η · 2 "- 6 · 2 ⁶ = 384 diodes is required, the device according to the invention, however, requires 2 (2" -1), = 2 (26-1 ) = 126 diodes; in the selector matrix, currents flow in • 162 of 384 diodes, in contrast to the evaluation circuit according to the invention in 63 of 126 diodes to convert code steps present as perforations of a perforated strip into a temporal pulse sequence (serial form) However, the evaluation device according to the invention in the selection of the trigger stage belonging to a specific step of the incoming step sequence. In addition, in the case of the invention, the ring counter is incremented at the rate of the received sequence of steps, while in the previously known arrangement the incremental pulses are not received but are generated separately. .; .. · ,.

The invention is explained in more detail below using two exemplary embodiments:

Fig. 1 shows, partly in a block diagram, an embodiment in which the electronic switches are formed by appropriately biased diode pairs;

FIG. 2 shows the ring counter designed with switching transistors, which is intended to work together with the switching stages shown in FIG. 3 and electronic switches consisting of transistors. For the sake of simplicity, the device shown evaluates only three-digit pulse groups, ie codes consisting of three steps and therefore eight combinations. According to FIG. 1, the incoming three-step combination arrives at the pulse reverser designated by 1. In this the received impulses z. B. transformed by differentiation into those of the same polarity. ■ These individual impulses now reverse the ring counter levels 2, 3 and 4 one after the other. These are designed in a manner known per se. The code steps are, however, also sent to flip-flops 5, 6 and 7 at the same time with their correct sign. In the idle state, these bistable multivibrators, which preferably each consist of a switching transistor operating in the bistable multivibrator with two possible operating points, are insensitive to incoming code steps. They only become sensitive when they are supplied with an auxiliary voltage from the associated ring counter stage. Depending on the polarity of the incoming code steps, the flip-flops 5, 6 and 7 are either left in their state or switched over one after the other. The current switching status of these stages is a true representation of the step combination that has arrived. B. causes levels 5 and 7 to assume one switching state, level 6 the other. As is well known, this switching state is retained by bistable circuits and embodied by voltages occurring on individual components. From level 5 ίο could after arrival, the drawn sequence of steps z. B. a positive voltage, from stage 6 a negative, from stage 7 in turn a positive voltage against any fixed potential of the circuit. These voltages are used to open or block diodes. In the example, diode 9 is opened by the positive voltage from stage 5, while diode 10 is blocked. Correspondingly, several diodes are opened and blocked using steps 6 and 7. As can easily be seen, steps 5, 6. and 7 exactly one path is switched from the generator 8 to the outputs 11, ie voltage is present at only one of the outputs when the generator 8 is switched on. In the example given, the ^a 5 generator 8 is only supplied with operating voltage in pulses. This pulse is derived from the last stage of the counting chain, stage 4, via a delay element 12. This ensures that the path from the generator 8 to the output 11 is only used when the three flip-flops 5, 6 and 7 are in the correct state. From output 11, the alternating current pulse is fed to the printing magnet of an electric typewriter, the actuating magnet of a remote setting machine or the like, by means of which the type lever is actuated.

This arrangement is obviously suitable for an easy control of the received character to enable: Are z. B. instead of the one needed to control normal electric typewriters six-digit step sequences used seven-digit, so the seventh step in itself As is known, check the previous six steps and only open a diode if the character was sent and received correctly. Otherwise feedback to the sender is possible, which asks them to repeat the wrongly sent character. This control device fits easily into the arrangement shown. It is also possible through proportionately minor expansion of the device to evaluate step combinations of different step numbers, where one z. B. Frequently transmitted characters are short, small pulse groups that are rarely transmitted Allocates characters to particularly long impulse groups. All that is required is several of the To provide steps 12 and to control them, among other things, by the register (the chain circuit). Because with multi-part step groups, the register is the most extensive part of the entire facility it makes sense to use it in the transmitter as well. By a Hiifs pulse generator, which quickly combines all state variations of levels 5, 6 and 7, and through a device that shuts down the generator at the appropriate moment can evidently be switched through from generator 8 to a line selected by pressing a typewriter key reach. The switching state of the flip-flops 5, 6 and 7 can then be scanned and in the form of positive ones and negative impulses are transmitted.

5 6

For the delivery of pulse combinations you can use the resistor R 2 to set the clock frequency ^; while the fir tree-shaped derailleur is electri- cal. The impulses of the clock are directly exploited ironic switch in that one in or differentiated via an "alternating current path 2" branches of the chain circuit, z. B. via Cl - DZ to the base of the control stages T3 to TO letter keys, applied current is conducted via the electrical 5. The tax levels T5 to TO are the same. The ironic switch acts back on the η flip-flops, T5 to T0 in each case a resistor ¹ leads to the diodes D2 which are located in the line path to be transmitted due to their switching position. Save the on TS fol characters. The arrangement according to FIG. 1 assumes that there is also a change in the message content in the form of pulses from the collector TO to the emitter of the preliminary stage, which is separated from one another by time segments are all are, or that the message content in one of these transistors, except for T 3, is in the blocked state. The form is converted For the evaluation 15 outputs: The voltage is reduced via R5 , such a code is the one shown in FIGS only the inputs 1 and 3. The diode Dl of the transistor Tl is flat for the sake of simplicity if one of them has a changed bias voltage and is to be assumed for a three-digit code, the incoming impulses are blocked. However, the transistor T2 is preceded by a start-up step. However, its working voltage is openly fed to the emitter, and it is clearly possible to use this arrangement to generate pulses. Since T3 is in the flow state, an evaluation of the normal five-digit code or a negative current impulse from Tl is ineffective. The pulses coming from the higher-digit codes to be used when the number of clock generators T2 is passed to those of the flip-flops and electronic switches ent- control stages T3 to TO. The tax level T3 is increased accordingly. 25 is in the conductive state and is controlled by the first; FIG. 2 shows an off pulse with switching transistors in the blocking state; as a result, the guided ring counter, which works as follows: the following stage T4 in the conductive state is controlled by the start-up step of the incoming characters. If T4 is switched off, the step combination in the ring counter switches the pre-stage switching from T 5 to the diode D 2 into the flow, whereby the clock-generating stage is controlled to 30 state, and the first path is free. One starts working. This controls the line input with its impulses the coming code step finds the following control stages, which in the rhythm determined by the now a free path and goes through D2 and Cl to the clock-generating stage over the first flip-flop stage. The clock continues to work, diode gates are assigned to the incoming character step and the assigned path is released one after the other via T6 to TO. The whole of the coded paths are released and the blocking step following the previously opened combination or the last path blocked again. Once the desired number of code steps has been reached, the distributor switching arrangement switches from code steps over the line to the starting position again. so the last stage TO switches the preliminary stage Tl into the Fig. 2 shows the ring counter with preliminary stage, the blocking state back. This sets the voltage clocking stage and the control stages. The control 40 feed for T2 is switched off, T2 stops, pulses levels T6, T7, etc. to TO are not shown because they are to be delivered; Due to the positive switching shock at Kolsie in the structure and in the effect of the control stage lektor of Tl, T3 will again correspond to the flow state T5. In the example, the control stages are controlled. The arrangement is ready for a new step transistors with a negative resistance series. In the series of S expensive levels, T4 showed the line; Naturally, other half-task, the time interval between the control pulse, teaching elements can also be used if the loading and the subsequent character pulses bridge the two different working positions. Otherwise it could happen that T2 is fulfilled after. It would also be possible for each control stage to immediately emit pulses to the jump from T1 to combine with the gate diode D 2 if, for example, a diode gate D2 is already open before the starting four-layer diode is used. 50 impulses come to an end.

In the figures, the same DC-based designations made by switching transistors are selected for the components that are subject to the same operating conditions in a switching example in FIG. 3. In all emitter circuits (T17 to T22) controlled chain circuit is shown, the resistor R 2, in the base circuits the resistor For the sake of clarity, it is assumed that there was a RZ and in the collector circuits the resistor 55 consisting of 2 ^{3 combinations.} 7? 5. From the entrance of each stage the path goes through the. It is only a matter of the principle of one of the coupling capacitors C 1 to the base. The diodes Dl- like structure, the number of stages can be arbitrarily and D2 get through the resistors Rl and 7? 4 can be expanded. In Fig. 3 for the sake of clarity, there are certain bias voltages. The voltages are not shown with 0-1-2-3, the higher number 60, the downshift can also mean the higher potential, for example, by means of a. short interruption of a voltage supply line er-Tl is the transistor of the preliminary stage. Follow this at the collector, whereby it is already sufficient as an interruption, the voltage supply for the emitter and a high-blocking diode must be switched into the circuit from Tl. Base of the clock transistor T2 connected. The downshift can also be triggered by the mechanical connection. There is also an alternating current connection between the movement of the expander, see collector T1 and base T3. In FIG. 3, T17 to T22 transistors represent an alternating current connection exists between the emitter with a negative resistance characteristic. Im Tl and collector TO. In the emitter circuit are the resistors R2, in the base-In the emitter circuit of the clock transistor T2 Hegt circuit R 3 and in the collector circuit R 5. The condensers via the resistor R2 also have a capacitor Γ2. 7o capacitors Cl are coupling capacitors for input

control of the plus and minus pulses. The transistors Γ17 / Γ18, T19] T20 \ indT21 / T22 form the switching points belonging to a stage for the respectively connected PNP transistors.

The transistors Γ23 to T 26 are PNP transistors with a base resistance R 6. In the collector circuits from T29 to T 36 are for signal. registration of the relays Ra.

In the case of the transistors T 23 to Γ36, the base is connected in alternating order to the collector of a switching stage that responds to negative pulses and to the collector of a switching stage that responds to positive pulses. In addition to the output stage, the collector of each transistor is connected to the emitter of the following two transistors.

: The working process is as follows: The first pulse coming from the ring counter reaches the emitter of T 17 via the capacitors C 1 and at the same time to the base νοηΠδ; both transistors are in the blocking state. The transistors Γ23 to T 36 are also blocked in the rest position due to the high positive voltage at the collector of the blocked switching transistor. If the pulse is positive, it cannot trigger a reversal at the emitter of Γ17, on the other hand it switches T 18 from the blocked state to the flow state. If Γ18 has become conductive, the voltage at the collector is reduced via R 5 , and the bias voltage at the base of transistor T24 changes. The transistor T24 has now become conductive 30 ^: but no current can flow yet because the following blocked transistors form a high resistance in the collector circuit of T24. .; The first code step switched part of the direct current path to low resistance. If the second code step comes from the ring counter, and is it e.g. B. negative, then T19 is controlled from the blocking state to the flow state. If the collector voltage at T 19 is reduced as a result, the bias voltage at T25 and 7'27 is reduced and both transistors become conductive. Since T23 is blocked, the positive voltage cannot reach the emitter of T25, and T 25 remains unaffected in terms of current. The positive voltage at the emitter of T 24 is applied to the emitter of T 27 and Γ 28 via the open transistor T 24 ; T28 is blocked and blocks the path to transistors Τ35 / Γ36. The positive voltage is applied to the emitters of T 33 and T 34 via Γ24 to T27.

If the third comes, e.g. B. positive code step, T 22 is switched. By switching over T 22, the base voltages at Γ30 / Γ32 / Τ34 and T36 are reduced. The transistors T30 / T32 and 'T 36 remain blocked, but T34 is opened. The direct current path via Γ24 to Γ27 and T34 is closed and a character is registered.

The direct current path shown in FIG. 3 can also be developed as an alternating current path by, for example, as in the embodiment of FIG gives a pressure pulse via the derailleur.

For ■ switching off the evaluation organs, the locking step of the z. B. developed for spring writer operation Code combination can be used.

Claims (16)

Patent claims: 1. Device for evaluating a binary code composed of η code steps and therefore 2 "step combinations with the help of an electronic selection device that takes over the task of the known relay pyramid, in which the η code steps of a combination each control a bistable trigger stage according to their polarity, characterized in that the selection of the flip-flop assigned to the respective step is effected by an rc-stage ring counter (2, 3, 4) which is incremented in time with the received step sequence and which allows each step to act only on the flip-flop assigned to it according to its position within the step combination, and that Each of the η ^{bistable switching stages actuates a number of (2 n-} 1) electronic changeover switches consisting of a pair of diodes or transistors, which expand with the position of the code step within the step combination in a geometric progression, and which form a fir tree-shaped branching chain circuit are connected, so that by the respective position of the η flip-flops and ¹ thus the switch only one of the 2 "possible circuits for the evaluation elements arranged at the 2" ends of the chain circuit is formed. 2. Device according to claim 1, characterized in that the switching pulses of the Ring counter from the code steps. z. B. be derived by differentiation. 3. Device according to claim 1, characterized in that the switching pulses of the Ring counter by a delayed start by the start-up step of a combination of characters Clock will be delivered. 4. Device according to claim 1 and 2, characterized in that the character steps are fed to the parallel inputs of all η flip-flops and each switched-on stage of the ring counter supplies the associated flip-flop an auxiliary voltage that makes this flip-flop sensitive to the character step controlling it . 5. Device according to claim 1 and 2, characterized in that the character steps are separately supplied to their associated bistable η flip-flops by an opening voltage generated by the respectively switched-on stage of the ring counter via a gate diode. 6. Device according to claim 1, 2 and 4, characterized in that the η trigger stages each consist of a switching transistor operating in the bistable trigger circuit, so that only two operating points are possible. 7. Device according to claim 1, 3 and 5, characterized in that the flip-flops from each two switching transistors working in the bistable multivibrator with a common input and separate outputs, the one transistor at the emitter electrode, the other is controlled at the base electrode, so that for each flip-flop two of the Polarity-dependent working positions and a rest position are possible. 8. Device according to claim 1, characterized in that the 2 ⁿ evaluation elements are represented at the ends of the chain circuit by the printing magnets of an electric typewriter, each letter being assigned its own printing magnet. 9. Device according to claim 1, characterized in that the 2 "evaluation organs through the actuating magnets of a remote setting machine are shown, each letter being assigned an actuating magnet. 10. Device according to claim 1, 2 and 4, characterized in that the pulse for actuation the evaluation unit is output from a special generator, which is fed via a delay element from the last ring counter stage is triggered. 11. Device according to claim 1, 3, 5, 7 and following, characterized in that the locking step a code combination developed for spring-writing operation to switch off the Evaluation organs is used. 12. Device according to claim 1 and following, characterized in that the mechanical movement of the evaluation unit triggers the downshift. 13. The device according to claim 1, characterized in that in a combination consisting of η +1 code steps, the last code step, the previous η steps, z. B. on the number of degrees of the separating current or character current steps, controlled and only opens a diode when the character has been put together correctly, and triggers a feedback to the transmitter to repeat the incorrect character in the event of errors. 14. Device according to claim 1, characterized in that the walking speed is the Transmission conditions is adapted. 15. Device according to claim 1, characterized in that different for characters Frequency the number of code steps is chosen differently. 16. A device according to claim 1, characterized in that the fir-tree-shaped chain circuit of electronic switches for the delivery of pulse combinations is used in that a current applied to the 2 "branches of the chain circuit, e.g. via letter keys, is applied to the electronic switch via the η flip-flops, which store the character to be sent through their switching position. Considered publications:
Funk-Technik, 1957, No. 21, pp. 724 to 726;
Elektronik, 1957, No. 5, pp. 127 to 130. 1 sheet of drawings © 909 688/291 12.